/usr/include/givaro/modular-integer.h is in libgivaro-dev 4.0.2-8ubuntu1.
This file is owned by root:root, with mode 0o644.
The actual contents of the file can be viewed below.
1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 21 22 23 24 25 26 27 28 29 30 31 32 33 34 35 36 37 38 39 40 41 42 43 44 45 46 47 48 49 50 51 52 53 54 55 56 57 58 59 60 61 62 63 64 65 66 67 68 69 70 71 72 73 74 75 76 77 78 79 80 81 82 83 84 85 86 87 88 89 90 91 92 93 94 95 96 97 98 99 100 101 102 103 104 105 106 107 108 109 110 111 112 113 114 115 116 117 118 119 120 121 122 123 124 125 126 127 128 129 130 131 132 133 134 135 136 137 138 139 140 141 142 143 144 145 146 147 148 149 150 151 152 153 154 155 156 157 158 159 160 161 162 163 164 165 166 167 168 169 170 171 172 173 174 175 176 177 178 179 180 181 182 183 184 185 186 187 188 189 190 191 192 193 194 195 196 197 198 199 200 201 202 203 204 205 206 207 208 209 210 211 212 213 214 215 216 217 218 219 220 221 | // ==========================================================================
// 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
// vim:sts=8:sw=8:ts=8:noet:sr:cino=>s,f0,{0,g0,(0,\:0,t0,+0,=s
|