cgal/Polynomial/doc_tex/Polynomial_ref/PolynomialTraits_d_GcdUpToConstantFactor.tex

\begin{ccRefConcept}{PolynomialTraits_d::GcdUpToConstantFactor}

\ccDefinition

This \ccc{AdaptableBinaryFunction} computes the $gcd$  
{\em up to a constant factor (utcf)} of two polynomials of type 
\ccc{PolynomialTraits_d::Polynomial_d}. 

In case the base ring $R$ (\ccc{PolynomialTraits_d::Innermost_coefficient_type}) 
is not a \ccc{UniqueFactorizationDomain} or not a \ccc{Field} the polynomial ring 
$R[x_0,\dots,x_{d-1}]$ (\ccc{PolynomialTraits_d::Polynomial_d}) may not 
possesses greatest common divisors. However, since $R$ is an integral 
domain one can consider its quotient field $Q(R)$ for which $gcd$s of 
polynomials exist. 

This functor computes $gcd\_utcf(f,g) = D * gcd(f,g)$, 
for some $D \in R$ such that $gcd\_utcf(f,g) \in R[x_0,\dots,x_{d-1}]$.
Hence, $gcd\_utcf(f,g)$ may not be a divisor of $f$ and $g$ in $R[x_0,\dots,x_{d-1}]$.

\ccRefines 

\ccc{AdaptableBinaryFunction}\\
\ccc{CopyConstructible}\\
\ccc{DefaultConstructible}\\

\ccTypes


\ccSetThreeColumns{xxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxx}{xxx}{}
\ccCreationVariable{fo}
\ccTypedef{typedef PolynomialTraits_d::Polynomial_d   result_type;}{}\ccGlue
\ccTypedef{typedef PolynomialTraits_d::Polynomial_d   first_argument_type;}{}\ccGlue
\ccTypedef{typedef PolynomialTraits_d::Polynomial_d   second_argument_type;}{}

\ccOperations

\ccMethod{result_type operator()(first_argument_type  f,
                                 second_argument_type g);}
                {Computes $gcd(f,g)$ up to a constant factor.}



%\ccHasModels

\ccSeeAlso

\ccRefIdfierPage{Polynomial_d}\\
\ccRefIdfierPage{PolynomialTraits_d}\\
\ccRefIdfierPage{PolynomialTraits_d::IntegralDivisionUpToConstantFactor}\\
\ccRefIdfierPage{PolynomialTraits_d::UnivariateContentUpToConstantFactor}\\
\ccRefIdfierPage{PolynomialTraits_d::SquareFreeFactorizeUpToConstantFactor}\\

\end{ccRefConcept}