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359 lines
14 KiB
359 lines
14 KiB
// Public rational number operations.
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#ifndef _CL_RATIONAL_H
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#define _CL_RATIONAL_H
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#include "cln/number.h"
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#include "cln/rational_class.h"
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#include "cln/integer_class.h"
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#include "cln/exception.h"
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namespace cln {
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CL_DEFINE_AS_CONVERSION(cl_RA)
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// numerator(r) liefert den Zähler der rationalen Zahl r.
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extern const cl_I numerator (const cl_RA& r);
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// denominator(r) liefert den Nenner (> 0) der rationalen Zahl r.
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extern const cl_I denominator (const cl_RA& r);
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// Liefert (- r), wo r eine rationale Zahl ist.
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extern const cl_RA operator- (const cl_RA& r);
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// (+ r s), wo r und s rationale Zahlen sind.
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extern const cl_RA operator+ (const cl_RA& r, const cl_RA& s);
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// Dem C++-Compiler muß man auch das Folgende sagen:
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inline const cl_RA operator+ (const int x, const cl_RA& y)
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{ return cl_I(x) + y; }
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inline const cl_RA operator+ (const unsigned int x, const cl_RA& y)
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{ return cl_I(x) + y; }
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inline const cl_RA operator+ (const long x, const cl_RA& y)
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{ return cl_I(x) + y; }
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inline const cl_RA operator+ (const unsigned long x, const cl_RA& y)
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{ return cl_I(x) + y; }
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#ifdef HAVE_LONGLONG
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inline const cl_RA operator+ (const long long x, const cl_RA& y)
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{ return cl_I(x) + y; }
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inline const cl_RA operator+ (const unsigned long long x, const cl_RA& y)
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{ return cl_I(x) + y; }
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#endif
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inline const cl_RA operator+ (const cl_RA& x, const int y)
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{ return x + cl_I(y); }
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inline const cl_RA operator+ (const cl_RA& x, const unsigned int y)
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{ return x + cl_I(y); }
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inline const cl_RA operator+ (const cl_RA& x, const long y)
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{ return x + cl_I(y); }
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inline const cl_RA operator+ (const cl_RA& x, const unsigned long y)
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{ return x + cl_I(y); }
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#ifdef HAVE_LONGLONG
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inline const cl_RA operator+ (const cl_RA& x, const long long y)
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{ return x + cl_I(y); }
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inline const cl_RA operator+ (const cl_RA& x, const unsigned long long y)
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{ return x + cl_I(y); }
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#endif
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// (- r s), wo r und s rationale Zahlen sind.
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extern const cl_RA operator- (const cl_RA& r, const cl_RA& s);
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// Dem C++-Compiler muß man auch das Folgende sagen:
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inline const cl_RA operator- (const int x, const cl_RA& y)
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{ return cl_I(x) - y; }
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inline const cl_RA operator- (const unsigned int x, const cl_RA& y)
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{ return cl_I(x) - y; }
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inline const cl_RA operator- (const long x, const cl_RA& y)
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{ return cl_I(x) - y; }
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inline const cl_RA operator- (const unsigned long x, const cl_RA& y)
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{ return cl_I(x) - y; }
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#ifdef HAVE_LONGLONG
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inline const cl_RA operator- (const long long x, const cl_RA& y)
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{ return cl_I(x) - y; }
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inline const cl_RA operator- (const unsigned long long x, const cl_RA& y)
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{ return cl_I(x) - y; }
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#endif
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inline const cl_RA operator- (const cl_RA& x, const int y)
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{ return x - cl_I(y); }
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inline const cl_RA operator- (const cl_RA& x, const unsigned int y)
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{ return x - cl_I(y); }
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inline const cl_RA operator- (const cl_RA& x, const long y)
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{ return x - cl_I(y); }
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inline const cl_RA operator- (const cl_RA& x, const unsigned long y)
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{ return x - cl_I(y); }
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#ifdef HAVE_LONGLONG
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inline const cl_RA operator- (const cl_RA& x, const long long y)
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{ return x - cl_I(y); }
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inline const cl_RA operator- (const cl_RA& x, const unsigned long long y)
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{ return x - cl_I(y); }
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#endif
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// (1+ r), wo r eine rationale Zahl ist.
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extern const cl_RA plus1 (const cl_RA& r);
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// (1- r), wo r eine rationale Zahl ist.
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extern const cl_RA minus1 (const cl_RA& r);
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// (abs r), wo r eine rationale Zahl ist.
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extern const cl_RA abs (const cl_RA& r);
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// equal(r,s) vergleicht zwei rationale Zahlen r und s auf Gleichheit.
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extern bool equal (const cl_RA& r, const cl_RA& s);
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// equal_hashcode(r) liefert einen equal-invarianten Hashcode für r.
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extern uint32 equal_hashcode (const cl_RA& r);
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// compare(r,s) vergleicht zwei rationale Zahlen r und s.
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// Ergebnis: 0 falls r=s, +1 falls r>s, -1 falls r<s.
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extern cl_signean compare (const cl_RA& r, const cl_RA& s);
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inline bool operator== (const cl_RA& x, const cl_RA& y)
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{ return equal(x,y); }
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inline bool operator!= (const cl_RA& x, const cl_RA& y)
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{ return !equal(x,y); }
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inline bool operator<= (const cl_RA& x, const cl_RA& y)
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{ return compare(x,y)<=0; }
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inline bool operator< (const cl_RA& x, const cl_RA& y)
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{ return compare(x,y)<0; }
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inline bool operator>= (const cl_RA& x, const cl_RA& y)
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{ return compare(x,y)>=0; }
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inline bool operator> (const cl_RA& x, const cl_RA& y)
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{ return compare(x,y)>0; }
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// minusp(x) == (< x 0)
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extern bool minusp (const cl_RA& x);
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// zerop(x) stellt fest, ob eine rationale Zahl = 0 ist.
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extern bool zerop (const cl_RA& x);
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// plusp(x) == (> x 0)
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extern bool plusp (const cl_RA& x);
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// Kehrwert (/ r), wo r eine rationale Zahl ist.
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extern const cl_RA recip (const cl_RA& r);
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// Liefert (* r s), wo r und s rationale Zahlen sind.
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extern const cl_RA operator* (const cl_RA& r, const cl_RA& s);
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// Dem C++-Compiler muß man auch das Folgende sagen:
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inline const cl_RA operator* (const int x, const cl_RA& y)
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{ return cl_I(x) * y; }
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inline const cl_RA operator* (const unsigned int x, const cl_RA& y)
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{ return cl_I(x) * y; }
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inline const cl_RA operator* (const long x, const cl_RA& y)
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{ return cl_I(x) * y; }
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inline const cl_RA operator* (const unsigned long x, const cl_RA& y)
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{ return cl_I(x) * y; }
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#ifdef HAVE_LONGLONG
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inline const cl_RA operator* (const long long x, const cl_RA& y)
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{ return cl_I(x) * y; }
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inline const cl_RA operator* (const unsigned long long x, const cl_RA& y)
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{ return cl_I(x) * y; }
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#endif
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inline const cl_RA operator* (const cl_RA& x, const int y)
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{ return x * cl_I(y); }
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inline const cl_RA operator* (const cl_RA& x, const unsigned int y)
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{ return x * cl_I(y); }
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inline const cl_RA operator* (const cl_RA& x, const long y)
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{ return x * cl_I(y); }
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inline const cl_RA operator* (const cl_RA& x, const unsigned long y)
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{ return x * cl_I(y); }
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#ifdef HAVE_LONGLONG
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inline const cl_RA operator* (const cl_RA& x, const long long y)
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{ return x * cl_I(y); }
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inline const cl_RA operator* (const cl_RA& x, const unsigned long long y)
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{ return x * cl_I(y); }
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#endif
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// Quadrat (* r r), wo r eine rationale Zahl ist.
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extern const cl_RA square (const cl_RA& r);
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// Liefert (/ r s), wo r und s rationale Zahlen sind.
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extern const cl_RA operator/ (const cl_RA& r, const cl_RA& s);
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// Dem C++-Compiler muß man auch das Folgende sagen:
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inline const cl_RA operator/ (const int x, const cl_RA& y)
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{ return cl_I(x) / y; }
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inline const cl_RA operator/ (const unsigned int x, const cl_RA& y)
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{ return cl_I(x) / y; }
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inline const cl_RA operator/ (const long x, const cl_RA& y)
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{ return cl_I(x) / y; }
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inline const cl_RA operator/ (const unsigned long x, const cl_RA& y)
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{ return cl_I(x) / y; }
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#ifdef HAVE_LONGLONG
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inline const cl_RA operator/ (const long long x, const cl_RA& y)
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{ return cl_I(x) / y; }
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inline const cl_RA operator/ (const unsigned long long x, const cl_RA& y)
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{ return cl_I(x) / y; }
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#endif
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inline const cl_RA operator/ (const cl_RA& x, const int y)
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{ return x / cl_I(y); }
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inline const cl_RA operator/ (const cl_RA& x, const unsigned int y)
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{ return x / cl_I(y); }
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inline const cl_RA operator/ (const cl_RA& x, const long y)
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{ return x / cl_I(y); }
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inline const cl_RA operator/ (const cl_RA& x, const unsigned long y)
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{ return x / cl_I(y); }
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#ifdef HAVE_LONGLONG
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inline const cl_RA operator/ (const cl_RA& x, const long long y)
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{ return x / cl_I(y); }
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inline const cl_RA operator/ (const cl_RA& x, const unsigned long long y)
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{ return x / cl_I(y); }
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#endif
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// Return type for rounding operators.
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// x / y --> (q,r) with x = y*q+r.
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struct cl_RA_div_t {
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cl_I quotient;
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cl_RA remainder;
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// Constructor.
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cl_RA_div_t () {}
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cl_RA_div_t (const cl_I& q, const cl_RA& r) : quotient(q), remainder(r) {}
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};
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// Liefert ganzzahligen und gebrochenen Anteil einer rationalen Zahl.
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// (q,r) := (floor x)
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// floor2(x)
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// > x: rationale Zahl
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// < q,r: Quotient q, ein Integer, Rest r, eine rationale Zahl
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extern const cl_RA_div_t floor2 (const cl_RA& x);
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extern const cl_I floor1 (const cl_RA& x);
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// Liefert ganzzahligen und gebrochenen Anteil einer rationalen Zahl.
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// (q,r) := (ceiling x)
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// ceiling2(x)
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// > x: rationale Zahl
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// < q,r: Quotient q, ein Integer, Rest r, eine rationale Zahl
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extern const cl_RA_div_t ceiling2 (const cl_RA& x);
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extern const cl_I ceiling1 (const cl_RA& x);
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// Liefert ganzzahligen und gebrochenen Anteil einer rationalen Zahl.
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// (q,r) := (truncate x)
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// truncate2(x)
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// > x: rationale Zahl
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// < q,r: Quotient q, ein Integer, Rest r, eine rationale Zahl
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extern const cl_RA_div_t truncate2 (const cl_RA& x);
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extern const cl_I truncate1 (const cl_RA& x);
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// Liefert ganzzahligen und gebrochenen Anteil einer rationalen Zahl.
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// (q,r) := (round x)
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// round2(x)
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// > x: rationale Zahl
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// < q,r: Quotient q, ein Integer, Rest r, eine rationale Zahl
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extern const cl_RA_div_t round2 (const cl_RA& x);
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extern const cl_I round1 (const cl_RA& x);
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// floor2(x,y) liefert (floor x y).
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extern const cl_RA_div_t floor2 (const cl_RA& x, const cl_RA& y);
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extern const cl_I floor1 (const cl_RA& x, const cl_RA& y);
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// ceiling2(x,y) liefert (ceiling x y).
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extern const cl_RA_div_t ceiling2 (const cl_RA& x, const cl_RA& y);
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extern const cl_I ceiling1 (const cl_RA& x, const cl_RA& y);
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// truncate2(x,y) liefert (truncate x y).
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extern const cl_RA_div_t truncate2 (const cl_RA& x, const cl_RA& y);
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extern const cl_I truncate1 (const cl_RA& x, const cl_RA& y);
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// round2(x,y) liefert (round x y).
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extern const cl_RA_div_t round2 (const cl_RA& x, const cl_RA& y);
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extern const cl_I round1 (const cl_RA& x, const cl_RA& y);
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// max(x,y) liefert (max x y), wo x und y rationale Zahlen sind.
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extern const cl_RA max (const cl_RA& x, const cl_RA& y);
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// min(x,y) liefert (min x y), wo x und y rationale Zahlen sind.
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extern const cl_RA min (const cl_RA& x, const cl_RA& y);
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// signum(x) liefert (signum x), wo x eine rationale Zahl ist.
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extern const cl_RA signum (const cl_RA& x);
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// (expt x y), wo x eine rationale Zahl und y ein Integer >0 ist.
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extern const cl_RA expt_pos (const cl_RA& x, uintL y);
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extern const cl_RA expt_pos (const cl_RA& x, const cl_I& y);
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// (expt x y), wo x eine rationale Zahl und y ein Integer ist.
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extern const cl_RA expt (const cl_RA& x, sintL y);
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extern const cl_RA expt (const cl_RA& x, const cl_I& y);
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// Stellt fest, ob eine rationale Zahl >=0 das Quadrat einer rationalen Zahl
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// ist.
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// sqrtp(x,&w)
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// > x: eine rationale Zahl >=0
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// < w: rationale Zahl (sqrt x) falls x Quadratzahl
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// < ergebnis: true ..................., false sonst
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extern bool sqrtp (const cl_RA& x, cl_RA* w);
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// Stellt fest, ob eine rationale Zahl >=0 die n-te Potenz einer rationalen Zahl
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// ist.
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// rootp(x,n,&w)
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// > x: eine rationale Zahl >=0
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// > n: ein Integer >0
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// < w: exakte n-te Wurzel (expt x (/ n)) falls x eine n-te Potenz
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// < ergebnis: true ........................, false sonst
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extern bool rootp (const cl_RA& x, uintL n, cl_RA* w);
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extern bool rootp (const cl_RA& x, const cl_I& n, cl_RA* w);
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// Liefert zu Integers a>0, b>1 den Logarithmus log(a,b),
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// falls er eine rationale Zahl ist.
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// logp(a,b,&l)
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// > a: ein Integer >0
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// > b: ein Integer >1
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// < l: log(a,b) falls er eine exakte rationale Zahl ist
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// < ergebnis: true ......................................., false sonst
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extern bool logp (const cl_I& a, const cl_I& b, cl_RA* l);
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// Liefert zu rationalen Zahlen a>0, b>0 den Logarithmus log(a,b),
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// falls er eine rationale Zahl ist.
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// logp(a,b,&l)
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// > a: eine rationale Zahl >0
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// > b: eine rationale Zahl >0, /=1
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// < l: log(a,b) falls er eine exakte rationale Zahl ist
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// < ergebnis: true ......................................., false sonst
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extern bool logp (const cl_RA& a, const cl_RA& b, cl_RA* l);
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// Konversion zu einem C "float".
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extern float float_approx (const cl_RA& x);
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// Konversion zu einem C "double".
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extern double double_approx (const cl_RA& x);
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#ifdef WANT_OBFUSCATING_OPERATORS
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// This could be optimized to use in-place operations.
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inline cl_RA& operator+= (cl_RA& x, const cl_RA& y) { return x = x + y; }
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inline cl_RA& operator+= (cl_RA& x, const int y) { return x = x + y; }
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inline cl_RA& operator+= (cl_RA& x, const unsigned int y) { return x = x + y; }
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inline cl_RA& operator+= (cl_RA& x, const long y) { return x = x + y; }
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inline cl_RA& operator+= (cl_RA& x, const unsigned long y) { return x = x + y; }
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#ifdef HAVE_LONGLONG
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inline cl_RA& operator+= (cl_RA& x, const long long y) { return x = x + y; }
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inline cl_RA& operator+= (cl_RA& x, const unsigned long long y) { return x = x + y; }
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#endif
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inline cl_RA& operator++ /* prefix */ (cl_RA& x) { return x = plus1(x); }
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inline void operator++ /* postfix */ (cl_RA& x, int dummy) { (void)dummy; x = plus1(x); }
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inline cl_RA& operator-= (cl_RA& x, const cl_RA& y) { return x = x - y; }
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inline cl_RA& operator-= (cl_RA& x, const int y) { return x = x - y; }
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inline cl_RA& operator-= (cl_RA& x, const unsigned int y) { return x = x - y; }
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inline cl_RA& operator-= (cl_RA& x, const long y) { return x = x - y; }
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inline cl_RA& operator-= (cl_RA& x, const unsigned long y) { return x = x - y; }
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#ifdef HAVE_LONGLONG
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inline cl_RA& operator-= (cl_RA& x, const long long y) { return x = x - y; }
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inline cl_RA& operator-= (cl_RA& x, const unsigned long long y) { return x = x - y; }
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#endif
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inline cl_RA& operator-- /* prefix */ (cl_RA& x) { return x = minus1(x); }
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inline void operator-- /* postfix */ (cl_RA& x, int dummy) { (void)dummy; x = minus1(x); }
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inline cl_RA& operator*= (cl_RA& x, const cl_RA& y) { return x = x * y; }
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inline cl_RA& operator/= (cl_RA& x, const cl_RA& y) { return x = x / y; }
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#endif
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// Runtime typing support.
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extern cl_class cl_class_ratio;
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// Debugging support.
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#ifdef CL_DEBUG
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extern int cl_RA_debug_module;
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CL_FORCE_LINK(cl_RA_debug_dummy, cl_RA_debug_module)
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#endif
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} // namespace cln
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#endif /* _CL_RATIONAL_H */
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