/usr/include/cln/univpoly_rational.h is in libcln-dev 1.3.4-1.
This file is owned by root:root, with mode 0o644.
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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 99 100 101 102 103 104 105 106 107 108 109 110 111 112 113 114 115 116 117 118 119 120 121 122 123 124 125 126 127 128 129 130 131 132 133 134 135 136 137 138 139 140 141 142 143 144 145 146 147 148 149 150 151 152 153 154 155 156 157 158 159 160 161 162 163 164 165 166 167 168 169 170 171 172 173 174 175 176 177 178 179 180 181 182 183 184 185 186 187 188 189 190 191 192 193 194 195 196 197 198 199 200 201 202 203 204 205 206 207 208 209 210 211 212 213 214 215 216 217 218 219 220 221 222 223 224 225 226 227 228 229 230 231 232 | // Univariate Polynomials over the rational numbers.
#ifndef _CL_UNIVPOLY_RATIONAL_H
#define _CL_UNIVPOLY_RATIONAL_H
#include "cln/ring.h"
#include "cln/univpoly.h"
#include "cln/number.h"
#include "cln/rational_class.h"
#include "cln/integer_class.h"
#include "cln/rational_ring.h"
namespace cln {
// Normal univariate polynomials with stricter static typing:
// `cl_RA' instead of `cl_ring_element'.
#ifdef notyet
typedef cl_UP_specialized<cl_RA> cl_UP_RA;
typedef cl_univpoly_specialized_ring<cl_RA> cl_univpoly_rational_ring;
//typedef cl_heap_univpoly_specialized_ring<cl_RA> cl_heap_univpoly_rational_ring;
#else
class cl_heap_univpoly_rational_ring;
class cl_univpoly_rational_ring : public cl_univpoly_ring {
public:
// Default constructor.
cl_univpoly_rational_ring () : cl_univpoly_ring () {}
// Copy constructor.
cl_univpoly_rational_ring (const cl_univpoly_rational_ring&);
// Assignment operator.
cl_univpoly_rational_ring& operator= (const cl_univpoly_rational_ring&);
// Automatic dereferencing.
cl_heap_univpoly_rational_ring* operator-> () const
{ return (cl_heap_univpoly_rational_ring*)heappointer; }
};
// Copy constructor and assignment operator.
CL_DEFINE_COPY_CONSTRUCTOR2(cl_univpoly_rational_ring,cl_univpoly_ring)
CL_DEFINE_ASSIGNMENT_OPERATOR(cl_univpoly_rational_ring,cl_univpoly_rational_ring)
class cl_UP_RA : public cl_UP {
public:
const cl_univpoly_rational_ring& ring () const { return The(cl_univpoly_rational_ring)(_ring); }
// Conversion.
CL_DEFINE_CONVERTER(cl_ring_element)
// Destructive modification.
void set_coeff (uintL index, const cl_RA& y);
void finalize();
// Evaluation.
const cl_RA operator() (const cl_RA& y) const;
public: // Ability to place an object at a given address.
void* operator new (size_t size) { return malloc_hook(size); }
void* operator new (size_t size, void* ptr) { (void)size; return ptr; }
void operator delete (void* ptr) { free_hook(ptr); }
};
class cl_heap_univpoly_rational_ring : public cl_heap_univpoly_ring {
SUBCLASS_cl_heap_univpoly_ring()
// High-level operations.
void fprint (std::ostream& stream, const cl_UP_RA& x)
{
cl_heap_univpoly_ring::fprint(stream,x);
}
bool equal (const cl_UP_RA& x, const cl_UP_RA& y)
{
return cl_heap_univpoly_ring::equal(x,y);
}
const cl_UP_RA zero ()
{
return The2(cl_UP_RA)(cl_heap_univpoly_ring::zero());
}
bool zerop (const cl_UP_RA& x)
{
return cl_heap_univpoly_ring::zerop(x);
}
const cl_UP_RA plus (const cl_UP_RA& x, const cl_UP_RA& y)
{
return The2(cl_UP_RA)(cl_heap_univpoly_ring::plus(x,y));
}
const cl_UP_RA minus (const cl_UP_RA& x, const cl_UP_RA& y)
{
return The2(cl_UP_RA)(cl_heap_univpoly_ring::minus(x,y));
}
const cl_UP_RA uminus (const cl_UP_RA& x)
{
return The2(cl_UP_RA)(cl_heap_univpoly_ring::uminus(x));
}
const cl_UP_RA one ()
{
return The2(cl_UP_RA)(cl_heap_univpoly_ring::one());
}
const cl_UP_RA canonhom (const cl_I& x)
{
return The2(cl_UP_RA)(cl_heap_univpoly_ring::canonhom(x));
}
const cl_UP_RA mul (const cl_UP_RA& x, const cl_UP_RA& y)
{
return The2(cl_UP_RA)(cl_heap_univpoly_ring::mul(x,y));
}
const cl_UP_RA square (const cl_UP_RA& x)
{
return The2(cl_UP_RA)(cl_heap_univpoly_ring::square(x));
}
const cl_UP_RA expt_pos (const cl_UP_RA& x, const cl_I& y)
{
return The2(cl_UP_RA)(cl_heap_univpoly_ring::expt_pos(x,y));
}
const cl_UP_RA scalmul (const cl_RA& x, const cl_UP_RA& y)
{
return The2(cl_UP_RA)(cl_heap_univpoly_ring::scalmul(cl_ring_element(cl_RA_ring,x),y));
}
sintL degree (const cl_UP_RA& x)
{
return cl_heap_univpoly_ring::degree(x);
}
sintL ldegree (const cl_UP_RA& x)
{
return cl_heap_univpoly_ring::ldegree(x);
}
const cl_UP_RA monomial (const cl_RA& x, uintL e)
{
return The2(cl_UP_RA)(cl_heap_univpoly_ring::monomial(cl_ring_element(cl_RA_ring,x),e));
}
const cl_RA coeff (const cl_UP_RA& x, uintL index)
{
return The(cl_RA)(cl_heap_univpoly_ring::coeff(x,index));
}
const cl_UP_RA create (sintL deg)
{
return The2(cl_UP_RA)(cl_heap_univpoly_ring::create(deg));
}
void set_coeff (cl_UP_RA& x, uintL index, const cl_RA& y)
{
cl_heap_univpoly_ring::set_coeff(x,index,cl_ring_element(cl_RA_ring,y));
}
void finalize (cl_UP_RA& x)
{
cl_heap_univpoly_ring::finalize(x);
}
const cl_RA eval (const cl_UP_RA& x, const cl_RA& y)
{
return The(cl_RA)(cl_heap_univpoly_ring::eval(x,cl_ring_element(cl_RA_ring,y)));
}
private:
// No need for any constructors.
cl_heap_univpoly_rational_ring ();
};
// Lookup of polynomial rings.
inline const cl_univpoly_rational_ring find_univpoly_ring (const cl_rational_ring& r)
{ return The(cl_univpoly_rational_ring) (find_univpoly_ring((const cl_ring&)r)); }
inline const cl_univpoly_rational_ring find_univpoly_ring (const cl_rational_ring& r, const cl_symbol& varname)
{ return The(cl_univpoly_rational_ring) (find_univpoly_ring((const cl_ring&)r,varname)); }
// Operations on polynomials.
// Add.
inline const cl_UP_RA operator+ (const cl_UP_RA& x, const cl_UP_RA& y)
{ return x.ring()->plus(x,y); }
// Negate.
inline const cl_UP_RA operator- (const cl_UP_RA& x)
{ return x.ring()->uminus(x); }
// Subtract.
inline const cl_UP_RA operator- (const cl_UP_RA& x, const cl_UP_RA& y)
{ return x.ring()->minus(x,y); }
// Multiply.
inline const cl_UP_RA operator* (const cl_UP_RA& x, const cl_UP_RA& y)
{ return x.ring()->mul(x,y); }
// Squaring.
inline const cl_UP_RA square (const cl_UP_RA& x)
{ return x.ring()->square(x); }
// Exponentiation x^y, where y > 0.
inline const cl_UP_RA expt_pos (const cl_UP_RA& x, const cl_I& y)
{ return x.ring()->expt_pos(x,y); }
// Scalar multiplication.
#if 0 // less efficient
inline const cl_UP_RA operator* (const cl_I& x, const cl_UP_RA& y)
{ return y.ring()->mul(y.ring()->canonhom(x),y); }
inline const cl_UP_RA operator* (const cl_UP_RA& x, const cl_I& y)
{ return x.ring()->mul(x.ring()->canonhom(y),x); }
#endif
inline const cl_UP_RA operator* (const cl_I& x, const cl_UP_RA& y)
{ return y.ring()->scalmul(x,y); }
inline const cl_UP_RA operator* (const cl_UP_RA& x, const cl_I& y)
{ return x.ring()->scalmul(y,x); }
inline const cl_UP_RA operator* (const cl_RA& x, const cl_UP_RA& y)
{ return y.ring()->scalmul(x,y); }
inline const cl_UP_RA operator* (const cl_UP_RA& x, const cl_RA& y)
{ return x.ring()->scalmul(y,x); }
// Coefficient.
inline const cl_RA coeff (const cl_UP_RA& x, uintL index)
{ return x.ring()->coeff(x,index); }
// Destructive modification.
inline void set_coeff (cl_UP_RA& x, uintL index, const cl_RA& y)
{ x.ring()->set_coeff(x,index,y); }
inline void finalize (cl_UP_RA& x)
{ x.ring()->finalize(x); }
inline void cl_UP_RA::set_coeff (uintL index, const cl_RA& y)
{ ring()->set_coeff(*this,index,y); }
inline void cl_UP_RA::finalize ()
{ ring()->finalize(*this); }
// Evaluation. (No extension of the base ring allowed here for now.)
inline const cl_RA cl_UP_RA::operator() (const cl_RA& y) const
{
return ring()->eval(*this,y);
}
// Derivative.
inline const cl_UP_RA deriv (const cl_UP_RA& x)
{ return The2(cl_UP_RA)(deriv((const cl_UP&)x)); }
#endif
// Returns the n-th Legendre polynomial (n >= 0).
extern const cl_UP_RA legendre (sintL n);
} // namespace cln
#endif /* _CL_UNIVPOLY_RATIONAL_H */
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