source: libcfa/src/rational.hfa@ bc61563

//
// Cforall Version 1.0.0 Copyright (C) 2016 University of Waterloo
//
// The contents of this file are covered under the licence agreement in the
// file "LICENCE" distributed with Cforall.
//
// rational -- Rational numbers are numbers written as a ratio, i.e., as a fraction, where the numerator (top number)
//     and the denominator (bottom number) are whole numbers. When creating and computing with rational numbers, results
//     are constantly reduced to keep the numerator and denominator as small as possible.
//
// Author           : Peter A. Buhr
// Created On       : Wed Apr  6 17:56:25 2016
// Last Modified By : Peter A. Buhr
// Last Modified On : Fri Oct  6 07:52:20 2023
// Update Count     : 122
//

#pragma once

#include "iostream.hfa"
#include "math.trait.hfa"                                                               // arithmetic

// implementation

forall( T | arithmetic( T ) ) {
        struct rational {
                T numerator, denominator;                                               // invariant: denominator > 0
        }; // rational

        // constructors

        void ?{}( rational(T) & r );
        void ?{}( rational(T) & r, zero_t );
        void ?{}( rational(T) & r, one_t );
        void ?{}( rational(T) & r, T n );
        void ?{}( rational(T) & r, T n, T d );

        // numerator/denominator getter

        T numerator( rational(T) r );
        T denominator( rational(T) r );
        [ T, T ] ?=?( & [ T, T ] dst, rational(T) src );

        // numerator/denominator setter

        T numerator( rational(T) r, T n );
        T denominator( rational(T) r, T d );

        // comparison

        int ?==?( rational(T) l, rational(T) r );
        int ?!=?( rational(T) l, rational(T) r );
        int ?!=?( rational(T) l, zero_t );                                      // => !
        int ?<?( rational(T) l, rational(T) r );
        int ?<=?( rational(T) l, rational(T) r );
        int ?>?( rational(T) l, rational(T) r );
        int ?>=?( rational(T) l, rational(T) r );

        // arithmetic

        rational(T) +?( rational(T) r );
        rational(T) -?( rational(T) r );
        rational(T) ?+?( rational(T) l, rational(T) r );
        rational(T) ?+=?( rational(T) & l, rational(T) r );
        rational(T) ?+=?( rational(T) & l, one_t );                     // => ++?, ?++
        rational(T) ?-?( rational(T) l, rational(T) r );
        rational(T) ?-=?( rational(T) & l, rational(T) r );
        rational(T) ?-=?( rational(T) & l, one_t );                     // => --?, ?--
        rational(T) ?*?( rational(T) l, rational(T) r );
        rational(T) ?*=?( rational(T) & l, rational(T) r );
        rational(T) ?/?( rational(T) l, rational(T) r );
        rational(T) ?/=?( rational(T) & l, rational(T) r );

        // I/O
        forall( istype & | istream( istype ) | { istype & ?|?( istype &, T & ); } )
        istype & ?|?( istype &, rational(T) & );

        forall( ostype & | ostream( ostype ) | { ostype & ?|?( ostype &, T ); } ) {
                ostype & ?|?( ostype &, rational(T) );
                OSTYPE_VOID( rational(T) );
        } // distribution
} // distribution

forall( T | arithmetic( T ) | { T ?\?( T, unsigned long ); } ) {
        rational(T) ?\?( rational(T) x, long int y );
        rational(T) ?\=?( rational(T) & x, long int y );
} // distribution

// conversion
forall( T | arithmetic( T ) | { double convert( T ); } )
double widen( rational(T) r );
forall( T | arithmetic( T ) | { double convert( T );  T convert( double );} )
rational(T) narrow( double f, T md );

// Local Variables: //
// mode: c //
// tab-width: 4 //
// End: //