/* -*- Mode: C++; tab-width: 4; indent-tabs-mode: nil; c-basic-offset: 4 -*- */ /* * This file is part of the LibreOffice project. * * This Source Code Form is subject to the terms of the Mozilla Public * License, v. 2.0. If a copy of the MPL was not distributed with this * file, You can obtain one at http://mozilla.org/MPL/2.0/. * * This file incorporates work covered by the following license notice: * * Licensed to the Apache Software Foundation (ASF) under one or more * contributor license agreements. See the NOTICE file distributed * with this work for additional information regarding copyright * ownership. The ASF licenses this file to you under the Apache * License, Version 2.0 (the "License"); you may not use this file * except in compliance with the License. You may obtain a copy of * the License at http://www.apache.org/licenses/LICENSE-2.0 . */ #include #include #include #include #include #include #include #include #include #if BOOST_VERSION >= 106700 #include #else #include #endif #include static boost::rational rational_FromDouble(double dVal); static void rational_ReduceInaccurate(boost::rational& rRational, unsigned nSignificantBits); static boost::rational toRational(sal_Int32 n, sal_Int32 d) { return boost::rational(n, d); } // Initialized by setting nNum as nominator and nDen as denominator // Negative values in the denominator are invalid and cause the // inversion of both nominator and denominator signs // in order to return the correct value. Fraction::Fraction( sal_Int64 nNum, sal_Int64 nDen ) : mnNumerator(nNum), mnDenominator(nDen) { assert( nNum >= std::numeric_limits::min() ); assert( nNum <= std::numeric_limits::max( )); assert( nDen >= std::numeric_limits::min() ); assert( nDen <= std::numeric_limits::max( )); if ( nDen == 0 ) { mbValid = false; SAL_WARN( "tools.fraction", "'Fraction(" << nNum << ",0)' invalid fraction created" ); return; } } /** * only here to prevent passing of NaN */ Fraction::Fraction( double nNum, double nDen ) : mnNumerator(sal_Int64(nNum)), mnDenominator(sal_Int64(nDen)) { assert( !std::isnan(nNum) ); assert( !std::isnan(nDen) ); assert( nNum >= std::numeric_limits::min() ); assert( nNum <= std::numeric_limits::max( )); assert( nDen >= std::numeric_limits::min() ); assert( nDen <= std::numeric_limits::max( )); if ( nDen == 0 ) { mbValid = false; SAL_WARN( "tools.fraction", "'Fraction(" << nNum << ",0)' invalid fraction created" ); return; } } Fraction::Fraction( double dVal ) { try { boost::rational v = rational_FromDouble( dVal ); mnNumerator = v.numerator(); mnDenominator = v.denominator(); } catch (const boost::bad_rational&) { mbValid = false; SAL_WARN( "tools.fraction", "'Fraction(" << dVal << ")' invalid fraction created" ); } } Fraction::operator double() const { if (!mbValid) { SAL_WARN( "tools.fraction", "'double()' on invalid fraction" ); return 0.0; } // https://github.com/boostorg/boost/issues/335 when these are std::numeric_limits::min if (mnNumerator == mnDenominator) return 1.0; return boost::rational_cast(toRational(mnNumerator, mnDenominator)); } // This methods first validates both values. // If one of the arguments is invalid, the whole operation is invalid. // After computation detect if result overflows a sal_Int32 value // which cause the operation to be marked as invalid Fraction& Fraction::operator += ( const Fraction& rVal ) { if ( !rVal.mbValid ) mbValid = false; if ( !mbValid ) { SAL_WARN( "tools.fraction", "'operator +=' with invalid fraction" ); return *this; } boost::rational a = toRational(mnNumerator, mnDenominator); a += toRational(rVal.mnNumerator, rVal.mnDenominator); mnNumerator = a.numerator(); mnDenominator = a.denominator(); return *this; } Fraction& Fraction::operator -= ( const Fraction& rVal ) { if ( !rVal.mbValid ) mbValid = false; if ( !mbValid ) { SAL_WARN( "tools.fraction", "'operator -=' with invalid fraction" ); return *this; } boost::rational a = toRational(mnNumerator, mnDenominator); a -= toRational(rVal.mnNumerator, rVal.mnDenominator); mnNumerator = a.numerator(); mnDenominator = a.denominator(); return *this; } namespace { template bool checked_multiply_by(boost::rational& i, const boost::rational& r) { // Protect against self-modification T num = r.numerator(); T den = r.denominator(); // Avoid overflow and preserve normalization #if BOOST_VERSION >= 106700 T gcd1 = boost::integer::gcd(i.numerator(), den); T gcd2 = boost::integer::gcd(num, i.denominator()); #else T gcd1 = boost::math::gcd(i.numerator(), den); T gcd2 = boost::math::gcd(num, i.denominator()); #endif bool fail = false; fail |= o3tl::checked_multiply(i.numerator() / gcd1, num / gcd2, num); fail |= o3tl::checked_multiply(i.denominator() / gcd2, den / gcd1, den); if (!fail) i.assign(num, den); return fail; } } Fraction& Fraction::operator *= ( const Fraction& rVal ) { if ( !rVal.mbValid ) mbValid = false; if ( !mbValid ) { SAL_WARN( "tools.fraction", "'operator *=' with invalid fraction" ); return *this; } boost::rational a = toRational(mnNumerator, mnDenominator); boost::rational b = toRational(rVal.mnNumerator, rVal.mnDenominator); bool bFail = checked_multiply_by(a, b); mnNumerator = a.numerator(); mnDenominator = a.denominator(); if (bFail) { mbValid = false; } return *this; } Fraction& Fraction::operator /= ( const Fraction& rVal ) { if ( !rVal.mbValid ) mbValid = false; if ( !mbValid ) { SAL_WARN( "tools.fraction", "'operator /=' with invalid fraction" ); return *this; } boost::rational a = toRational(mnNumerator, mnDenominator); a /= toRational(rVal.mnNumerator, rVal.mnDenominator); mnNumerator = a.numerator(); mnDenominator = a.denominator(); return *this; } /** Inaccurate cancellation for a fraction. Clip both nominator and denominator to said number of bits. If either of those already have equal or less number of bits used, this method does nothing. @param nSignificantBits denotes, how many significant binary digits to maintain, in both nominator and denominator. @example ReduceInaccurate(8) has an error <1% [1/2^(8-1)] - the largest error occurs with the following pair of values: binary 1000000011111111111111111111111b/1000000000000000000000000000000b = 1082130431/1073741824 = approx. 1.007812499 A ReduceInaccurate(8) yields 1/1. */ void Fraction::ReduceInaccurate( unsigned nSignificantBits ) { if ( !mbValid ) { SAL_WARN( "tools.fraction", "'ReduceInaccurate' on invalid fraction" ); return; } if ( !mnNumerator ) return; auto a = toRational(mnNumerator, mnDenominator); rational_ReduceInaccurate(a, nSignificantBits); mnNumerator = a.numerator(); mnDenominator = a.denominator(); } sal_Int32 Fraction::GetNumerator() const { if ( !mbValid ) { SAL_WARN( "tools.fraction", "'GetNumerator()' on invalid fraction" ); return 0; } return mnNumerator; } sal_Int32 Fraction::GetDenominator() const { if ( !mbValid ) { SAL_WARN( "tools.fraction", "'GetDenominator()' on invalid fraction" ); return -1; } return mnDenominator; } Fraction::operator sal_Int32() const { if ( !mbValid ) { SAL_WARN( "tools.fraction", "'operator sal_Int32()' on invalid fraction" ); return 0; } return boost::rational_cast(toRational(mnNumerator, mnDenominator)); } Fraction operator+( const Fraction& rVal1, const Fraction& rVal2 ) { Fraction aErg( rVal1 ); aErg += rVal2; return aErg; } Fraction operator-( const Fraction& rVal1, const Fraction& rVal2 ) { Fraction aErg( rVal1 ); aErg -= rVal2; return aErg; } Fraction operator*( const Fraction& rVal1, const Fraction& rVal2 ) { Fraction aErg( rVal1 ); aErg *= rVal2; return aErg; } Fraction operator/( const Fraction& rVal1, const Fraction& rVal2 ) { Fraction aErg( rVal1 ); aErg /= rVal2; return aErg; } bool operator !=( const Fraction& rVal1, const Fraction& rVal2 ) { return !(rVal1 == rVal2); } bool operator <=( const Fraction& rVal1, const Fraction& rVal2 ) { return !(rVal1 > rVal2); } bool operator >=( const Fraction& rVal1, const Fraction& rVal2 ) { return !(rVal1 < rVal2); } bool operator == ( const Fraction& rVal1, const Fraction& rVal2 ) { if ( !rVal1.mbValid || !rVal2.mbValid ) { SAL_WARN( "tools.fraction", "'operator ==' with an invalid fraction" ); return false; } return toRational(rVal1.mnNumerator, rVal1.mnDenominator) == toRational(rVal2.mnNumerator, rVal2.mnDenominator); } bool operator < ( const Fraction& rVal1, const Fraction& rVal2 ) { if ( !rVal1.mbValid || !rVal2.mbValid ) { SAL_WARN( "tools.fraction", "'operator <' with an invalid fraction" ); return false; } return toRational(rVal1.mnNumerator, rVal1.mnDenominator) < toRational(rVal2.mnNumerator, rVal2.mnDenominator); } bool operator > ( const Fraction& rVal1, const Fraction& rVal2 ) { if ( !rVal1.mbValid || !rVal2.mbValid ) { SAL_WARN( "tools.fraction", "'operator >' with an invalid fraction" ); return false; } return toRational(rVal1.mnNumerator, rVal1.mnDenominator) > toRational(rVal2.mnNumerator, rVal2.mnDenominator); } SvStream& ReadFraction( SvStream& rIStream, Fraction & rFract ) { sal_Int32 num(0), den(0); rIStream.ReadInt32( num ); rIStream.ReadInt32( den ); if ( den <= 0 ) { SAL_WARN( "tools.fraction", "'ReadFraction()' read an invalid fraction" ); rFract.mbValid = false; } else { rFract.mnNumerator = num; rFract.mnDenominator = den; rFract.mbValid = true; } return rIStream; } SvStream& WriteFraction( SvStream& rOStream, const Fraction& rFract ) { if ( !rFract.mbValid ) { SAL_WARN( "tools.fraction", "'WriteFraction()' write an invalid fraction" ); rOStream.WriteInt32( 0 ); rOStream.WriteInt32( -1 ); } else { rOStream.WriteInt32( rFract.mnNumerator ); rOStream.WriteInt32( rFract.mnDenominator ); } return rOStream; } // If dVal > LONG_MAX or dVal < LONG_MIN, the rational throws a boost::bad_rational. // Otherwise, dVal and denominator are multiplied by 10, until one of them // is larger than (LONG_MAX / 10). // // NOTE: here we use 'sal_Int32' due that only values in sal_Int32 range are valid. static boost::rational rational_FromDouble(double dVal) { if ( dVal > std::numeric_limits::max() || dVal < std::numeric_limits::min() || std::isnan(dVal) ) throw boost::bad_rational(); const sal_Int32 nMAX = std::numeric_limits::max() / 10; sal_Int32 nDen = 1; while ( std::abs( dVal ) < nMAX && nDen < nMAX ) { dVal *= 10; nDen *= 10; } return boost::rational( sal_Int32(dVal), nDen ); } // Similar to clz_table that can be googled const char nbits_table[32] = { 32, 1, 23, 2, 29, 24, 14, 3, 30, 27, 25, 18, 20, 15, 10, 4, 31, 22, 28, 13, 26, 17, 19, 9, 21, 12, 16, 8, 11, 7, 6, 5 }; static int impl_NumberOfBits( sal_uInt32 nNum ) { // http://en.wikipedia.org/wiki/De_Bruijn_sequence // background paper: Using de Bruijn Sequences to Index a 1 in a // Computer Word (1998) Charles E. Leiserson, // Harald Prokop, Keith H. Randall // (e.g. http://citeseer.ist.psu.edu/leiserson98using.html) const sal_uInt32 nDeBruijn = 0x7DCD629; if ( nNum == 0 ) return 0; // Get it to form like 0000001111111111b nNum |= ( nNum >> 1 ); nNum |= ( nNum >> 2 ); nNum |= ( nNum >> 4 ); nNum |= ( nNum >> 8 ); nNum |= ( nNum >> 16 ); sal_uInt32 nNumber; int nBonus; nNumber = nNum; nBonus = 0; // De facto shift left of nDeBruijn using multiplication (nNumber // is all ones from topmost bit, thus nDeBruijn + (nDeBruijn * // nNumber) => nDeBruijn * (nNumber+1) clears all those bits to // zero, sets the next bit to one, and thus effectively shift-left // nDeBruijn by lg2(nNumber+1). This generates a distinct 5bit // sequence in the msb for each distinct position of the last // leading 0 bit - that's the property of a de Bruijn number. nNumber = nDeBruijn + ( nDeBruijn * nNumber ); // 5-bit window indexes the result return ( nbits_table[nNumber >> 27] ) + nBonus; } /** Inaccurate cancellation for a fraction. Clip both nominator and denominator to said number of bits. If either of those already have equal or less number of bits used, this method does nothing. @param nSignificantBits denotes, how many significant binary digits to maintain, in both nominator and denominator. @example ReduceInaccurate(8) has an error <1% [1/2^(8-1)] - the largest error occurs with the following pair of values: binary 1000000011111111111111111111111b/1000000000000000000000000000000b = 1082130431/1073741824 = approx. 1.007812499 A ReduceInaccurate(8) yields 1/1. */ static void rational_ReduceInaccurate(boost::rational& rRational, unsigned nSignificantBits) { if ( !rRational ) return; // http://www.boost.org/doc/libs/release/libs/rational/rational.html#Internal%20representation const bool bNeg = ( rRational.numerator() < 0 ); sal_Int32 nMul = bNeg? -rRational.numerator(): rRational.numerator(); sal_Int32 nDiv = rRational.denominator(); DBG_ASSERT(nSignificantBits<65, "More than 64 bit of significance is overkill!"); // How much bits can we lose? const int nMulBitsToLose = std::max( ( impl_NumberOfBits( nMul ) - int( nSignificantBits ) ), 0 ); const int nDivBitsToLose = std::max( ( impl_NumberOfBits( nDiv ) - int( nSignificantBits ) ), 0 ); const int nToLose = std::min( nMulBitsToLose, nDivBitsToLose ); // Remove the bits nMul >>= nToLose; nDiv >>= nToLose; if ( !nMul || !nDiv ) { // Return without reduction OSL_FAIL( "Oops, we reduced too much..." ); return; } rRational.assign( bNeg ? -nMul : nMul, nDiv ); } /* vim:set shiftwidth=4 softtabstop=4 expandtab: */