Mercurial > octave
view liboctave/util/oct-cmplx.h @ 22323:bac0d6f07a3e
maint: Update copyright notices for 2016.
| author | John W. Eaton <jwe@octave.org> |
|---|---|
| date | Wed, 17 Aug 2016 01:05:19 -0400 |
| parents | e43d83253e28 |
| children | 4caa7b28d183 |
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/* Copyright (C) 1995-2016 John W. Eaton Copyright (C) 2009 VZLU Prague, a.s. 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/>. */ #if ! defined (octave_oct_cmplx_h) #define octave_oct_cmplx_h 1 #include "octave-config.h" #include <complex> typedef std::complex<double> Complex; typedef std::complex<float> FloatComplex; // For complex-complex and complex-real comparisons, we use the following // ordering: compare absolute values first; if they match, compare phase angles. // This is partially inconsistent with M*b, which compares complex numbers only // by their real parts; OTOH, it uses the same definition for max/min and sort. // The abs/arg comparison is definitely more useful (the other one is emulated // rather trivially), so let's be consistent and use that all over. // The standard C library function arg() returns [-pi,pi], which creates a // non-unique representation for numbers along the negative real axis branch // cut. Change this to principal value (-pi,pi] by mapping -pi to pi. #define DEF_COMPLEXR_COMP(OP, OPS) \ template <typename T> \ inline bool operator OP (const std::complex<T>& a, const std::complex<T>& b) \ { \ OCTAVE_FLOAT_TRUNCATE const T ax = std::abs (a); \ OCTAVE_FLOAT_TRUNCATE const T bx = std::abs (b); \ if (ax == bx) \ { \ OCTAVE_FLOAT_TRUNCATE const T ay = std::arg (a); \ OCTAVE_FLOAT_TRUNCATE const T by = std::arg (b); \ if (ay == static_cast<T> (-M_PI)) \ { \ if (by != static_cast<T> (-M_PI)) \ return static_cast<T> (M_PI) OP by; \ } \ else if (by == static_cast<T> (-M_PI)) \ { \ return ay OP static_cast<T> (M_PI); \ } \ return ay OP by; \ } \ else \ return ax OPS bx; \ } \ template <typename T> \ inline bool operator OP (const std::complex<T>& a, T b) \ { \ OCTAVE_FLOAT_TRUNCATE const T ax = std::abs (a); \ OCTAVE_FLOAT_TRUNCATE const T bx = std::abs (b); \ if (ax == bx) \ { \ OCTAVE_FLOAT_TRUNCATE const T ay = std::arg (a); \ if (ay == static_cast<T> (-M_PI)) \ return static_cast<T> (M_PI) OP 0; \ return ay OP 0; \ } \ else \ return ax OPS bx; \ } \ template <typename T> \ inline bool operator OP (T a, const std::complex<T>& b) \ { \ OCTAVE_FLOAT_TRUNCATE const T ax = std::abs (a); \ OCTAVE_FLOAT_TRUNCATE const T bx = std::abs (b); \ if (ax == bx) \ { \ OCTAVE_FLOAT_TRUNCATE const T by = std::arg (b); \ if (by == static_cast<T> (-M_PI)) \ return 0 OP static_cast<T> (M_PI); \ return 0 OP by; \ } \ else \ return ax OPS bx; \ } DEF_COMPLEXR_COMP (>, >) DEF_COMPLEXR_COMP (<, <) DEF_COMPLEXR_COMP (<=, <) DEF_COMPLEXR_COMP (>=, >) #endif