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// 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, cl_UP_RA* 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);
}
cl_boolean 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());
}
cl_boolean 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);
}
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
CL_REQUIRE(cl_RA_ring)
// Returns the n-th Legendre polynomial (n >= 0).
extern const cl_UP_RA legendre (sintL n);
} // namespace cln
#endif /* _CL_UNIVPOLY_RATIONAL_H */