/usr/include/givaro/modular-integer.h is in libgivaro-dev 4.0.2-5.
This file is owned by root:root, with mode 0o644.
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// Copyright(c)'1994-2015 by The Givaro group
// This file is part of Givaro.
// Givaro is governed by the CeCILL-B license under French law
// and abiding by the rules of distribution of free software.
// see the COPYRIGHT file for more details.
// Authors: JG Dumas
// A. Breust (taken from FFLAS-FFPACK)
// ==========================================================================
/*! @file givzpzInt.h
* @ingroup zpz
* @brief Arithmetic on Z/pZ, with p a prime number in arbitrary precision.
*/
#ifndef __GIVARO_zpz_int_H
#define __GIVARO_zpz_int_H
#include "givaro/givbasictype.h"
#include "givaro/giverror.h"
#include "givaro/givinteger.h"
#include "givaro/givcaster.h"
#include "givaro/givranditer.h"
#include "givaro/modular-general.h"
#include "givaro/ring-interface.h"
namespace Givaro
{
/*! @brief This class implement the standard arithmetic with Modulo Elements.
* - The representation of an integer a in Zpz is the value a % p
* .
*/
template<>
class Modular<Integer, Integer> : public virtual FiniteFieldInterface<Integer>
{
public:
// ----- Exported Types and constantes
typedef Modular<Integer> Self_t;
typedef Integer Residu_t; // - type to store residue
enum { size_rep = sizeof(Residu_t) }; // - size of the storage type
// ----- Constantes
const Element zero;
const Element one;
const Element mOne;
// ----- Constructors
~Modular() noexcept {};
Modular()
: zero(static_cast<Element>(0))
, one(static_cast<Element>(1))
, mOne(static_cast<Element>(-1))
, _p(static_cast<Residu_t>(0)) {}
Modular(const Residu_t p)
: zero(static_cast<Element>(0))
, one(static_cast<Element>(1))
, mOne(static_cast<Element>(p-1))
, _p(static_cast<Residu_t>(p))
{
assert(_p >= minCardinality());
}
Modular(const Self_t& F)
: zero(F.zero), one(F.one), mOne(F.mOne), _p(F._p) {}
// ----- Accessors
inline Element minElement() const override { return zero; }
inline Element maxElement() const override { return mOne; }
// ----- Access to the modulus
inline Residu_t residu() const { return _p; }
inline Residu_t size() const { return _p; }
inline Residu_t characteristic() const { return _p; }
inline Residu_t cardinality() const { return _p; }
template<class T> inline T& characteristic(T& p) const { return p = _p; }
template<class T> inline T& cardinality(T& p) const { return p = _p; }
static inline Residu_t maxCardinality() { return -1; }
static inline Residu_t minCardinality() { return 2; }
// ----- Checkers
inline bool isZero(const Element& a) const override { return a == zero; }
inline bool isOne (const Element& a) const override { return a == one; }
inline bool isMOne(const Element& a) const override { return a == mOne; }
inline bool areEqual(const Element& a, const Element& b) const override { return a == b; }
inline size_t length(const Element a) const { return size_rep; }
// ----- Ring-wise operators
inline bool operator==(const Self_t& F) const { return _p == F._p; }
inline bool operator!=(const Self_t& F) const { return _p != F._p; }
inline Self_t& operator=(const Self_t& F)
{
F.assign(const_cast<Element&>(one), F.one);
F.assign(const_cast<Element&>(zero), F.zero);
F.assign(const_cast<Element&>(mOne), F.mOne);
_p = F._p;
return *this;
}
// ----- Initialisation
Element& init (Element& x) const;
template<typename T> Element& init(Element& r, const T& a) const
{ r = Caster<Element>(a); return reduce(r); }
Element& assign (Element& x, const Element& y) const;
// ----- Convert and reduce
template<typename T> T& convert(T& r, const Element& a) const
{ return r = static_cast<T>(a); }
Element& reduce (Element& x, const Element& y) const;
Element& reduce (Element& x) const;
// ----- Classic arithmetic
Element& mul(Element& r, const Element& a, const Element& b) const override;
Element& div(Element& r, const Element& a, const Element& b) const override;
Element& add(Element& r, const Element& a, const Element& b) const override;
Element& sub(Element& r, const Element& a, const Element& b) const override;
Element& neg(Element& r, const Element& a) const override;
Element& inv(Element& r, const Element& a) const override;
Element& mulin(Element& r, const Element& a) const override;
Element& divin(Element& r, const Element& a) const override;
Element& addin(Element& r, const Element& a) const override;
Element& subin(Element& r, const Element& a) const override;
Element& negin(Element& r) const override;
Element& invin(Element& r) const override;
// -- axpy: r <- a * x + y
// -- axpyin: r <- a * x + r
Element& axpy (Element& r, const Element& a, const Element& x, const Element& y) const override;
Element& axpyin(Element& r, const Element& a, const Element& x) const override;
// -- axmy: r <- a * x - y
// -- axmyin: r <- a * x - r
Element& axmy (Element& r, const Element& a, const Element& x, const Element& y) const override;
Element& axmyin(Element& r, const Element& a, const Element& x) const override;
// -- maxpy: r <- y - a * x
// -- maxpyin: r <- r - a * x
Element& maxpy (Element& r, const Element& a, const Element& x, const Element& y) const override;
Element& maxpyin(Element& r, const Element& a, const Element& x) const override;
// ----- Random generators
typedef ModularRandIter<Self_t> RandIter;
typedef GeneralRingNonZeroRandIter<Self_t> NonZeroRandIter;
template< class Random > Element& random(Random& g, Element& r) const
{ return init(r, g()); }
template< class Random > Element& nonzerorandom(Random& g, Element& a) const
{ while (isZero(init(a, g())))
;
return a; }
// --- IO methods
std::ostream& write( std::ostream& s ) const;
std::istream& read ( std::istream& s, Element& a ) const;
std::ostream& write( std::ostream& s, const Element& a ) const;
protected:
Residu_t _p;
};
/* Specialisation for Modular<integer> field*/
template <>
class ModularRandIter<Modular<Integer> >
{
public:
typedef Modular<Integer> Ring;
typedef Ring::Element Element;
ModularRandIter(const Ring& R, const size_t& size = 0, const size_t& seed = 0)
: _ring(R)
{
unsigned long s=seed;
if (! seed) {
struct timeval tp;
gettimeofday(&tp, 0) ;
s = (unsigned long)(tp.tv_usec);
}
Givaro::Integer::seeding(s);
}
Element& operator()(Element& elt)
{
// Create new random Elements
Givaro::Integer::random_lessthan(elt,_ring.residu());
return elt;
}
Element& random(Element& elt)
{
return this->operator()(elt);
}
Element operator()()
{
Element elt; return this->operator()(elt);
}
Element random()
{
return this->operator()();
}
const Ring& ring() const { return _ring; }
private:
const Ring& _ring;
}; // class ModularRandIter<Integer>
}// namespace Givaro
#include "givaro/modular-integer.inl"
#endif // __GIVARO_zpz_int_H
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