/******************************************************************** * gnc-rational-rounding.hpp - Template functions for rounding * * Copyright 2017 John Ralls * * 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 2 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, contact: * * * * Free Software Foundation Voice: +1-617-542-5942 * * 51 Franklin Street, Fifth Floor Fax: +1-617-542-2652 * * Boston, MA 02110-1301, USA gnu@gnu.org * * * *******************************************************************/ #ifndef __GNC_RATIONAL_ROUNDING_HPP__ #define __GNC_RATIONAL_ROUNDING_HPP__ #include "gnc-numeric.h" #include "gnc-int128.hpp" template inline bool quotient_is_positive(T dividend, T divisor) { return (dividend > 0 && divisor > 0) || (dividend < 0 && divisor < 0); } enum class RoundType { floor = GNC_HOW_RND_FLOOR, ceiling = GNC_HOW_RND_CEIL, truncate = GNC_HOW_RND_TRUNC, promote = GNC_HOW_RND_PROMOTE, half_down = GNC_HOW_RND_ROUND_HALF_DOWN, half_up = GNC_HOW_RND_ROUND_HALF_UP, bankers = GNC_HOW_RND_ROUND, never = GNC_HOW_RND_NEVER, }; enum class DenomType { den_auto = GNC_DENOM_AUTO, exact = GNC_HOW_DENOM_EXACT, reduce = GNC_HOW_DENOM_REDUCE, lcd = GNC_HOW_DENOM_LCD, fixed = GNC_HOW_DENOM_FIXED, sigfigs = GNC_HOW_DENOM_SIGFIG, }; template struct RT2T { RoundType value = rt; }; /* The following templates implement the rounding policies for the convert and * convert_sigfigs template functions. */ template inline T round(T num, T den, T rem, RT2T) { if (rem == 0) return num; throw std::domain_error("Rounding required when 'never round' specified."); } template inline T round(T num, T den, T rem, RT2T) { // std::cout << "Rounding to floor with num " << num << " den " << den // << ", and rem " << rem << ".\n"; if (rem == 0) return num; // floor num==0 that is the quotient of two numbers with opposite signs if (num < 0 || (num == 0 && !quotient_is_positive(rem, den))) return num - 1; return num; } template <> inline GncInt128 round(GncInt128 num, GncInt128 den, GncInt128 rem, RT2T) { // std::cout << "Rounding to floor with num " << num << " den " << den // << ", and rem " << rem << ".\n"; if (rem == 0) return num; if (num.isNeg()) return num - 1; return num; } template inline T round(T num, T den, T rem, RT2T) { if (rem == 0) return num; if (num > 0 || (num == 0 && quotient_is_positive(rem, den))) return num + 1; return num; } template <> inline GncInt128 round(GncInt128 num, GncInt128 den, GncInt128 rem, RT2T) { if (rem == 0) return num; if (!num.isNeg()) return num + 1; return num; } template inline T round(T num, T den, T rem, RT2T) { return num; } template inline T round(T num, T den, T rem, RT2T) { if (rem == 0) return num; if (num == 0) return (!quotient_is_positive(rem, den) ? -1 : 1); return num + (num < 0 ? -1 : 1); } template <> inline GncInt128 round(GncInt128 num, GncInt128 den, GncInt128 rem, RT2T) { if (rem == 0) return num; return num + (num.isNeg() ? -1 : 1); } template inline T round(T num, T den, T rem, RT2T) { if (rem == 0) return num; if (std::abs(rem * 2) > std::abs(den)) { if (num == 0) return (!quotient_is_positive(rem, den) ? -1 : 1); return num + (num < 0 ? -1 : 1); } return num; } template <> inline GncInt128 round(GncInt128 num, GncInt128 den, GncInt128 rem, RT2T) { if (rem == 0) return num; if (rem.abs() * 2 > den.abs()) return num + (num.isNeg() ? -1 : 1); return num; } template inline T round(T num, T den, T rem, RT2T) { if (rem == 0) return num; if (std::abs(rem) * 2 >= std::abs(den)) { if (num == 0) return (!quotient_is_positive(rem, den) ? -1 : 1); return num + (num < 0 ? -1 : 1); } return num; } template <> inline GncInt128 round(GncInt128 num, GncInt128 den, GncInt128 rem, RT2T) { if (rem == 0) return num; if (rem.abs() * 2 >= den.abs()) return num + (num.isNeg() ? -1 : 1); return num; } template inline T round(T num, T den, T rem, RT2T) { if (rem == 0) return num; if (std::abs(rem * 2) > std::abs(den) || (std::abs(rem * 2) == std::abs(den) && num % 2)) { if (num == 0) return (!quotient_is_positive(rem, den) ? -1 : 1); return num + (num < 0 ? -1 : 1); } return num; } template <> inline GncInt128 round(GncInt128 num, GncInt128 den, GncInt128 rem, RT2T) { if (rem == 0) return num; if (rem.abs() * 2 > den.abs() || (rem.abs() * 2 == den.abs() && num % 2)) return num + (num.isNeg() ? -1 : 1); return num; } #endif //__GNC_RATIONAL_ROUNDING_HPP__