/usr/include/ThePEG/PDF/PDFBase.h is in libthepeg-dev 1.8.0-1.
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//
// PDFBase.h is a part of ThePEG - Toolkit for HEP Event Generation
// Copyright (C) 1999-2011 Leif Lonnblad
//
// ThePEG is licenced under version 2 of the GPL, see COPYING for details.
// Please respect the MCnet academic guidelines, see GUIDELINES for details.
//
#ifndef ThePEG_PDFBase_H
#define ThePEG_PDFBase_H
// This is the declaration of the PDFBase class.
#include "ThePEG/Config/ThePEG.h"
#include "ThePEG/Handlers/HandlerBase.h"
#include "ThePEG/PDF/PDFCuts.h"
#include "PDFBase.xh"
namespace ThePEG {
/**
* PDFBase is the base class for implementing parton density functions
* for particles with sub-structure. A number of of virtual methods
* are defined which should be overridden by sub-classes.
*
* It is essential that either xfx or xfl is overidden to avoid
* infinite recursive function calls.
*
* A PDFBase object can be assigned to a BeamParticleData object
* and/or to a PartonExtractor object. A PDFBase has a pointer to a
* RemnantHandler object which should be capable of generating
* remnants for all partons which may be extracted by the PDF.
*
* @see \ref PDFBaseInterfaces "The interfaces"
* defined for PDFBase.
* @see BeamParticleData
* @see PartonExtractor
* @see RemnantHandler
* @see PDFCuts
*/
class PDFBase: public HandlerBase {
public:
/** @name Standard constructors and destructors. */
//@{
/**
* Default constructor.
*/
PDFBase();
/**
* Copy-constructor.
*/
PDFBase(const PDFBase &);
/**
* Destructor.
*/
virtual ~PDFBase();
//@}
public:
/** @name Virtual functions to be overridden by sub-classes. */
//@{
/**
* Return true if this PDF can handle the extraction of partons from
* the given \a particle.
*/
virtual bool canHandleParticle(tcPDPtr particle) const = 0;
/**
* Return true if canHandleParticle() and if the corresponding
* method for remnantHandler() returns true for the given \a
* particle.
*/
virtual bool canHandle(tcPDPtr particle) const;
/**
* Return true if this PDF has a pole at $x=1$ for the given \a
* particle and \a parton. This default version of the function
* returns false.
*/
virtual bool hasPoleIn1(tcPDPtr particle, tcPDPtr parton) const;
/**
* Return the partons which this PDF may extract from the given
* \a particle.
*/
virtual cPDVector partons(tcPDPtr particle) const = 0;
/**
* The density. Return the pdf for the given \a parton inside the
* given \a particle for the virtuality \a partonScale and
* logarithmic momentum fraction \a l \f$(l=\log(1/x)\f$. The \a
* particle is assumed to have a virtuality \a particleScale.
*/
virtual double xfl(tcPDPtr particle, tcPDPtr parton, Energy2 partonScale,
double l, Energy2 particleScale = ZERO) const;
/**
* The density. Return the pdf for the given \a parton inside the
* given \a particle for the virtuality \a partonScale and momentum
* fraction \a x. The \a particle is assumed to have a virtuality \a
* particleScale.
*/
virtual double xfx(tcPDPtr particle, tcPDPtr parton, Energy2 partonScale,
double x, double eps = 0.0,
Energy2 particleScale = ZERO) const;
/**
* The valence density. Return the pdf for the given cvalence \a
* parton inside the given \a particle for the virtuality \a
* partonScale and logarithmic momentum fraction \a l
* \f$(l=\log(1/x)\f$. The \a particle is assumed to have a
* virtuality \a particleScale. If not overidden by a sub class this
* implementation will assume that the difference between a quark
* and anti-quark distribution is due do valense quarks, but return
* zero for anything else.
*/
virtual double xfvl(tcPDPtr particle, tcPDPtr parton, Energy2 partonScale,
double l, Energy2 particleScale = ZERO) const;
/**
* The valence density. Return the pdf for the given cvalence \a
* parton inside the given \a particle for the virtuality \a
* partonScale and momentum fraction \a x. The \a particle is
* assumed to have a virtuality \a particleScale. If not overidden
* by a sub class this implementation will assume that the
* difference between a quark and anti-quark distribution is due do
* valense quarks, but return zero for anything else.
*/
virtual double xfvx(tcPDPtr particle, tcPDPtr parton, Energy2 partonScale,
double x, double eps = 0.0,
Energy2 particleScale = ZERO) const;
/**
* The sea density. Return the pdf for the given cvalence \a
* parton inside the given \a particle for the virtuality \a
* partonScale and logarithmic momentum fraction \a l
* \f$(l=\log(1/x)\f$. The \a particle is assumed to have a
* virtuality \a particleScale. If not overidden by a sub class this
* implementation will assume that the difference between a quark
* and anti-quark distribution is due do valense quarks.
*/
virtual double xfsl(tcPDPtr particle, tcPDPtr parton, Energy2 partonScale,
double l, Energy2 particleScale = ZERO) const;
/**
* The sea density. Return the pdf for the given cvalence \a
* parton inside the given \a particle for the virtuality \a
* partonScale and momentum fraction \a x. The \a particle is
* assumed to have a virtuality \a particleScale. If not overidden
* by a sub class this implementation will assume that the
* difference between a quark and anti-quark distribution is due do
* valense quarks.
*/
virtual double xfsx(tcPDPtr particle, tcPDPtr parton, Energy2 partonScale,
double x, double eps = 0.0,
Energy2 particleScale = ZERO) const;
/**
* Generate a momentum fraction. If the PDF contains strange peaks
* which can be difficult to handle, this function may be
* overwritten to return an appropriate \f$l=\log(1/x)\f$ for a \a z
* uniformly distributed in ]0,1[. Also the jacobobian of the
* \f$l\rightarrow z\f$ variable transformation must in the function
* multiply the \a jacobian argument. The default version will
* simply use the function \f$l(z) = l_{\min} +
* z*(l_{\max}-l_{\min})\f$ (where the limits are set by \a cut).
*/
virtual double flattenL(tcPDPtr particle, tcPDPtr parton, const PDFCuts &cut,
double z, double & jacobian) const;
/**
* Generate scale (as a fraction of the maximum scale). If the PDF
* contains strange peaks which can be difficult to handle, this
* function may be overwritten to return an appropriate scale
* \f$Q^2/Q^2_{\max}\f$ for a \a z uniformly distributed in
* ]0,1[. Also the jacobobian of the \f$Q^2/Q^2_{\max}\rightarrow
* z\f$ variable transformation must multiply the \a jacobian
* argument. The default version will simply use the function
* \f$Q^2/Q^2_{\max} = (Q^2_{\max}/Q^2_{\min})^(z-1)\f$ or, if
* \f$Q^2_{\min}\f$ is zero, \f$Q^2/Q^2_{\max} = z\f$ (where the
* limits are set by \a cut).
*/
virtual double flattenScale(tcPDPtr particle, tcPDPtr parton,
const PDFCuts & cut, double l, double z,
double & jacobian) const;
//@}
/**
* Pointer to the remnant handler to handle remnant when extracting
* partons according to these densities.
*/
tcRemHPtr remnantHandler() const { return theRemnantHandler; }
public:
/** @name Functions used by the persistent I/O system. */
//@{
/**
* Function used to write out object persistently.
* @param os the persistent output stream written to.
*/
void persistentOutput(PersistentOStream & os) const;
/**
* Function used to read in object persistently.
* @param is the persistent input stream read from.
* @param version the version number of the object when written.
*/
void persistentInput(PersistentIStream & is, int version);
//@}
/**
* Standard Init function used to initialize the interface.
*/
static void Init();
protected:
/** @name Standard Interfaced functions. */
//@{
/**
* Initialize this object after the setup phase before saving an
* EventGenerator to disk.
* @throws InitException if object could not be initialized properly.
*/
virtual void doinit();
protected:
/**
* A remnant handler which can generate remnants for the parton
* extracted withfor this PDF
*/
RemHPtr theRemnantHandler;
protected:
/**
* Indicate how to deal with x and Q2 which are out of range.
*/
enum RangeException {
rangeFreeze, /**> Freeze the value of the PDF outside the limits. */
rangeZero, /**> Set the PDF to zero outside the limits. */
rangeThrow /**> Throw an exception if outside the limits. */
};
/**
* Indicate to subclasses how to deal with x and Q2 which are out of
* range.
*/
RangeException rangeException;
private:
/**
* The static object used to initialize the description of this class.
* Indicates that this is an abstract class with persistent data.
*/
static AbstractClassDescription<PDFBase> initPDFBase;
/**
* Private and non-existent assignment operator.
*/
PDFBase & operator=(const PDFBase &);
};
ThePEG_DECLARE_CLASS_TRAITS(PDFBase,HandlerBase);
}
#endif /* ThePEG_PDFBase_H */
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