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/* This file is part of the KDE libraries
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Copyright (C) 2005 Klaus Niederkrueger <kniederk@math.uni-koeln.de>
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This library is free software; you can redistribute it and/or
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modify it under the terms of the GNU Library General Public
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License as published by the Free Software Foundation; either
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version 2 of the License, or (at your option) any later version.
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This library is distributed in the hope that it will be useful,
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but WITHOUT ANY WARRANTY; without even the implied warranty of
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MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU
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Library General Public License for more details.
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You should have received a copy of the GNU Library General Public License
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along with this library; see the file COPYING.LIB. If not, write to
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the Free Software Foundation, Inc., 51 Franklin Street, Fifth Floor,
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Boston, MA 02110-1301, USA.
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*/
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#ifndef _KNUMBER_H
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#define _KNUMBER_H
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#include <tdelibs_export.h>
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#include "knumber_priv.h"
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class TQString;
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/**
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*
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* @short Class that provides arbitrary precision numbers
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*
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* KNumber provides access to arbitrary precision numbers from within
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* KDE.
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*
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* KNumber is based on the GMP (GNU Multiprecision) library and
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* provides transparent support to integer, fractional and floating
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* point number. It contains rudimentary error handling, and also
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* includes methods for converting the numbers to TQStrings for
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* output, and to read TQStrings to obtain a KNumber.
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*
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* The different types of numbers that can be represented by objects
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* of this class will be described below:
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*
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* @li @p NumType::SpecialType - This type represents an error that
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* has occurred, e.g. trying to divide 1 by 0 gives an object that
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* represents infinity.
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*
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* @li @p NumType::IntegerType - The number is an integer. It can be
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* arbitrarily large (restricted by the memory of the system).
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*
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* @li @p NumType::FractionType - A fraction is a number of the form
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* denominator divided by nominator, where both denominator and
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* nominator are integers of arbitrary size.
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*
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* @li @p NumType::FloatType - The number is of floating point
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* type. These numbers are usually rounded, so that they do not
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* represent precise values.
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*
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*
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* @author Klaus Niederkrueger <kniederk@math.uni-koeln.de>
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*/
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class KDE_EXPORT KNumber
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{
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public:
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static KNumber const Zero;
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static KNumber const One;
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static KNumber const MinusOne;
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static KNumber const Pi;
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static KNumber const Euler;
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static KNumber const NotDefined;
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/**
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* KNumber tries to provide transparent access to the following type
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* of numbers:
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*
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* @li @p NumType::SpecialType - Some type of error has occurred,
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* further inspection with @p KNumber::ErrorType
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*
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* @li @p NumType::IntegerType - the number is an integer
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*
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* @li @p NumType::FractionType - the number is a fraction
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*
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* @li @p NumType::FloatType - the number is of floating point type
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*
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*/
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enum NumType {SpecialType, IntegerType, FractionType, FloatType};
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/**
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* A KNumber that represents an error, i.e. that is of type @p
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* NumType::SpecialType can further distinguished:
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*
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* @li @p ErrorType::UndefinedNumber - This is e.g. the result of
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* taking the square root of a negative number or computing
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* \f$ \infty - \infty \f$.
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*
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* @li @p ErrorType::Infinity - Such a number can be e.g. obtained
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* by dividing 1 by 0. Some further calculations are still allowed,
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* e.g. \f$ \infty + 5 \f$ still gives \f$\infty\f$.
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*
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* @li @p ErrorType::MinusInfinity - MinusInfinity behaves similarly
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* to infinity above. It can be obtained by changing the sign of
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* infinity.
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*
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*/
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enum ErrorType {UndefinedNumber, Infinity, MinusInfinity};
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KNumber(signed int num = 0);
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KNumber(unsigned int num);
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KNumber(signed long int num);
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KNumber(unsigned long int num);
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KNumber(unsigned long long int num);
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KNumber(double num);
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KNumber(KNumber const & num);
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KNumber(TQString const & num);
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~KNumber()
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{
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delete _num;
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}
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KNumber const & operator=(KNumber const & num);
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/**
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* Returns the type of the number, as explained in @p KNumber::NumType.
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*/
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NumType type(void) const;
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/**
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* Set whether the output of numbers (with KNumber::toTQString)
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* should happen as floating point numbers or not. This method has
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* in fact only an effect on numbers of type @p
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* NumType::FractionType, which can be either displayed as fractions
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* or in decimal notation.
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*
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* The default behavior is not to display fractions in floating
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* point notation.
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*/
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static void setDefaultFloatOutput(bool flag);
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/**
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* Set whether a number constructed from a TQString should be
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* initialized as a fraction or as a float, e.g. "1.01" would be
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* treated as 101/100, if this flag is set to true.
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*
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* The default setting is false.
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*/
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static void setDefaultFractionalInput(bool flag);
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/**
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* Set the default precision to be *at least* @p prec (decimal)
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* digits. All subsequent initialized floats will use at least this
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* precision, but previously initialized variables are unaffected.
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*/
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static void setDefaultFloatPrecision(unsigned int prec);
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/**
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* What a terrible method name!! When displaying a fraction, the
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* default mode gives @p "nomin/denom". With this method one can
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* choose to display a fraction as @p "integer nomin/denom".
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*
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* Examples: Default representation mode is 47/17, but if @p flag is
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* @p true, then the result is 2 13/17.
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*/
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static void setSplitoffIntegerForFractionOutput(bool flag);
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/**
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* Return a TQString representing the KNumber.
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*
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* @param width This number specifies the maximal length of the
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* output, before the method switches to exponential notation and
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* does rounding. For negative numbers, this option is ignored.
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*
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* @param prec This parameter controls the number of digits
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* following the decimal point. For negative numbers, this option
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* is ignored.
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*
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*/
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TQString const toTQString(int width = -1, int prec = -1) const;
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/**
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* Compute the absolute value, i.e. @p x.abs() returns the value
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*
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* \f[ \left\{\begin{array}{cl} x, & x \ge 0 \\ -x, & x <
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* 0\end{array}\right.\f]
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* This method works for \f$ x = \infty \f$ and \f$ x = -\infty \f$.
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*/
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KNumber const abs(void) const;
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/**
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* Compute the square root. If \f$ x < 0 \f$ (including \f$
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* x=-\infty \f$), then @p x.sqrt() returns @p
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* ErrorType::UndefinedNumber.
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*
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* If @p x is an integer or a fraction, then @p x.sqrt() tries to
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* compute the exact square root. If the square root is not a
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* fraction, then a float with the default precision is returned.
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*
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* This method works for \f$ x = \infty \f$ giving \f$ \infty \f$.
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*/
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KNumber const sqrt(void) const;
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/**
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* Compute the cube root.
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*
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* If @p x is an integer or a fraction, then @p x.cbrt() tries to
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* compute the exact cube root. If the cube root is not a fraction,
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* then a float is returned, but
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*
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* WARNING: A float cube root is computed as a standard @p double
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* that is later transformed back into a @p KNumber.
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*
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* This method works for \f$ x = \infty \f$ giving \f$ \infty \f$,
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* and for \f$ x = -\infty \f$ giving \f$ -\infty \f$.
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*/
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KNumber const cbrt(void) const;
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/**
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* Truncates a @p KNumber to its integer type returning a number of
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* type @p NumType::IntegerType.
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*
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* If \f$ x = \pm\infty \f$, integerPart leaves the value unchanged,
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* i.e. it returns \f$ \pm\infty \f$.
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*/
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KNumber const integerPart(void) const;
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KNumber const power(KNumber const &exp) const;
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KNumber const operator+(KNumber const & arg2) const;
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KNumber const operator -(void) const;
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KNumber const operator-(KNumber const & arg2) const;
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KNumber const operator*(KNumber const & arg2) const;
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KNumber const operator/(KNumber const & arg2) const;
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KNumber const operator%(KNumber const & arg2) const;
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KNumber const operator&(KNumber const & arg2) const;
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KNumber const operator|(KNumber const & arg2) const;
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KNumber const operator<<(KNumber const & arg2) const;
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KNumber const operator>>(KNumber const & arg2) const;
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operator bool(void) const;
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operator signed long int(void) const;
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operator unsigned long int(void) const;
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operator unsigned long long int(void) const;
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operator double(void) const;
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bool const operator==(KNumber const & arg2) const
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{ return (compare(arg2) == 0); }
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bool const operator!=(KNumber const & arg2) const
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{ return (compare(arg2) != 0); }
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bool const operator>(KNumber const & arg2) const
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{ return (compare(arg2) > 0); }
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bool const operator<(KNumber const & arg2) const
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{ return (compare(arg2) < 0); }
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bool const operator>=(KNumber const & arg2) const
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{ return (compare(arg2) >= 0); }
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bool const operator<=(KNumber const & arg2) const
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{ return (compare(arg2) <= 0); }
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KNumber & operator +=(KNumber const &arg);
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KNumber & operator -=(KNumber const &arg);
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//KNumber const toFloat(void) const;
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private:
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void simplifyRational(void);
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int const compare(KNumber const & arg2) const;
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_knumber *_num;
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static bool _float_output;
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static bool _fraction_input;
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static bool _splitoffinteger_output;
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};
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#endif // _KNUMBER_H
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