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* \file GyotoAstrobj.h
* \brief Astronomical objects (light emitters)
*
* The target of ray-traced Gyoto::Photon
*/
/*
Copyright 2011-2016 Thibaut Paumard, Frederic Vincent
This file is part of Gyoto.
Gyoto is free software: you can redistribute it and/or modify
it under the terms of the GNU General Public License as published by
the Free Software Foundation, either version 3 of the License, or
(at your option) any later version.
Gyoto is distributed in the hope that it will be useful,
but WITHOUT ANY WARRANTY; without even the implied warranty of
MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
GNU General Public License for more details.
You should have received a copy of the GNU General Public License
along with Gyoto. If not, see <http://www.gnu.org/licenses/>.
*/
#ifndef __GyotoAstrobj_H_
#define __GyotoAstrobj_H_
#include "GyotoConfig.h"
#include <iostream>
#include <fstream>
#include <iomanip>
#include <string>
#include <GyotoDefs.h>
#include <GyotoSmartPointer.h>
#include <GyotoConverters.h>
#include <GyotoObject.h>
namespace Gyoto{
class Photon;
namespace Register { class Entry; }
namespace Metric { class Generic; }
class FactoryMessenger;
namespace Astrobj {
class Generic;
class Properties;
/**
* This is a more specific version of the
* SmartPointee::Subcontractor_t type. An Astrobj::Subcontrator_t
* is called by the Gyoto::Factory to build an instance of the
* kind of astronomical object specified in an XML file (see
* Register()). The Factory and Subcontractor_t function
* communicate through a Gyoto::FactoryMessenger. A template is
* provided so that you may not have to code anything.
*/
typedef SmartPointer<Gyoto::Astrobj::Generic>
Subcontractor_t(Gyoto::FactoryMessenger*, std::vector<std::string> const &);
///< A function to build instances of a specific Astrobj::Generic sub-class
/**
* Instead of reimplementing the wheel, your subcontractor can simply be
* Gyoto::Astrobj::Subcontractor<MyKind>.
*
* If MyKind accepts any XML parameters, it should re-implement
* Astrobj::Generic::setParameter() or, if low-level access to the
* FactoryMessenger is needed, Generic::setParameters().
*
* \tparam T Gyoto::Astrobj::Generic sub-class
*/
template<typename T> SmartPointer<Astrobj::Generic> Subcontractor
(FactoryMessenger* fmp, std::vector<std::string> const &plugin) {
SmartPointer<T> ao = new T();
ao -> plugins(plugin) ;
#ifdef GYOTO_USE_XERCES
if (fmp) ao -> setParameters(fmp);
#endif
return ao;
}
///< A template for Subcontractor_t functions
/// Query the Astrobj register
/**
* Query the Astrobj register to get the Astrobj::Subcontractor_t
* corresponding to a given kind name. This function is normally
* called only from the Factory. If plugin is specified, only a
* subcontractor matching both name and plugin will be returned,
* loading the plug-in if necessary. If plugin is the empty
* string, then the first subcontractor matching name will be
* returned, and the name of the plug-in it belongs to will be
* returned in plugin upon output.
*
* \param[in] name e.g. "Star"
* \param[inout] plugin e.g. "stdplug".
* \param[in] errmode 1 to return NULL in case of failure instead of
* throwing an Error.
* \return pointer to the corresponding subcontractor.
*/
Gyoto::Astrobj::Subcontractor_t* getSubcontractor(std::string name,
std::vector<std::string> &plugin,
int errmode = 0);
/**
* Use the Astrobj::initRegister() once in your program to
* initiliaze it, the Astrobj::Register() function to fill it, and
* the Astrobj::getSubcontractor() function to query it.
*/
extern Gyoto::Register::Entry * Register_;
///< The Astrobj register
/**
* This must be called once.
*/
void initRegister();
///< Empty the Astrobj register
/**
* Register a new Astrobj::Generic sub-class so that the
* Gyoto::Factory knows it.
*
* \param name The kind name which identifies this object type in
* an XML file, as in <Astrobj kind="name">
*
* \param scp A pointer to the subcontractor, which will
* communicate with the Gyoto::Factory to build an instance of
* the class from its XML description
*/
void Register(std::string name, Gyoto::Astrobj::Subcontractor_t* scp);
///< Make an Astrobj kind known to the Factory
}
}
/**
* \namespace Gyoto::Astrobj
* \brief Access to astronomical objects
*
* Objects which are supposed to be the target of the ray-tracing
* code should inherit from the Gyoto::Astrobj::Generic class.
*
* When implementing a new object, you must:
* - make sure the object can be loaded from XML by providing a
* Subcontractor_t using the Gyoto::Astrobj::Register(std::string
* name, Gyoto::Astrobj::Subcontractor_t* scp) function;
* - make sure this subcontractor is registerred in the initialization
* routine of your plug-in;
* - make sure Generic::Impact() works (see below).
*
* In addition, you should make sure that your object plays nicely in
* the Yorick plug-in, which means:
* - implement the copy constructor and the Generic::clone() method;
* - implement the fillElement method, used for printing and saving to
* XML.
*
* There are basically two ways of making Generic::Impact() work:
* either by making the Astrobj a sub-class of the low-level
* Gyoto::Astrobj::Generic class ans providing your own
* Generic::Impact() function (which, in principle, should rely on
* Generic::processHitQuantities()), or by making the Astrobj a
* sub-class of the higher-level Gyoto::Astrobj::Standard class and
* implementing two lower level, simpler functions which are
* used by the Standard::Impact():
* - Standard::operator()() yields a distance or potential defining
* the interior of the object;
* - Standard::getVelocity() yields the velocity field of the fluid.
*
* Generic::processHitQuantities() itself is an intermediate-level
* function which you may choose to reimplement. It uses three
* low-level, easy to implement functions:
* - Generic::emission();
* - Generic::integrateEmission();
* - Generic::transmission().
* Default implementations of these three functions exist, they have
* little physical relevance but allow quick 0-th order vizualisation
* of your object.
*
* To be usable, a Astrobj::Generic (or Astrobj::Standard) sub-classe
* should register an Astrobj::Subcontractor_t function using the
* Astrobj::Register() function. See also \ref writing_plugins_page
* . If your clas implements setParameter() and/or, if necessary,
* setParameters(), registering it is normally done using the provided
* template:
* \code
* Astrobj::Register("MyKind", &(Astrobj::Subcontractor<Astrobj::MyKind>));
* \endcode
*/
/**
* \class Gyoto::Astrobj::Generic
* \brief Base class for astronomical object
*
* See introduction in the Gyoto::Astrobj namespace.
*/
class Gyoto::Astrobj::Generic
: public Gyoto::SmartPointee,
public Gyoto::Object
{
friend class Gyoto::SmartPointer<Gyoto::Astrobj::Generic>;
// Data :
// -----
protected:
/**
* \brief The Metric in this end of the Universe
*/
SmartPointer<Gyoto::Metric::Generic> gg_;
/**
* Maximum distance from the center of the coordinate system at
* which a photon may hit the object. Child classes may compute a
* decent value for #rmax_ at any time if #rmax_ is
* DBL_MAX. External classes (Photons in particular) must use rMax()
* to access this information.
*
* #rmax_ is in geometrical units.
*/
double rmax_; ///< Maximum distance to the center of the coordinate system [geometrical units]
bool flag_radtransf_; ///< 1 if radiative transfer inside Astrobj, else 0
int radiativeq_; ///< 1 to use the new radiativeQ function (under dvp)
int shadow_; ///< 1 to highlight the shadow region in the image
int noredshift_; ///< 1 to impose redshift factor g = 1
// Constructors - Destructor
// -------------------------
public:
GYOTO_OBJECT;
/**
* #kind_ = "Default", #rmax_ = DBL_MAX
*/
Generic(); ///< Default constructor.
/**
* #kind_ = "Default", #rmax_ = radmax
*/
Generic(double radmax); ///< Set rmax in constructor.
/**
* #kind_ = kind, #rmax_ = DBL_MAX
*/
Generic(std::string kind); ///< Set kind in constructor.
/**
* Make a deep copy of an Astrobj::Generic instance
*/
Generic(const Generic& ) ; ///< Copy constructor.
/**
* This method must be implemented by the various Astrobj::Generic
* subclasses in order to support cloning:
* \code
* SmartPointer<Astrobj> deep_copy = original->clone();
* \endcode
*
* Cloning is necessary for multi-threading, recommended for
* interaction with the Yorick plug-in etc.
*
* Implementing it is very straightforward, as long as the copy
* constructor Generic(const Generic& ) has been implemented:
* \code
* MyAstrobj* MyAstrobj::clone() const { return new MyAstrobj(*this); }
* \endcode
*/
virtual Generic* clone() const = 0 ; ///< Cloner
virtual ~Generic() ; ///< Destructor: does nothing.
// Accessors
// ---------
public:
/**
* \brief Get the Metric #gg_
*/
virtual SmartPointer<Metric::Generic> metric() const;
/**
* \brief Set the Metric #gg_
*/
virtual void metric(SmartPointer<Metric::Generic>) ;
/**
* Get maximal distance from center of coordinate system at which a
* Photon may hit the object.
*
* Child classes may use the #rmax_ member to cache this value, if
* its current value is DBL_MAX.
*
* It can also be set using rMax().
*
* \return rmax_ in geometrical units
*/
virtual double rMax(); ///< Get maximal distance from center of coordinate system
virtual double rMax() const; ///< Get maximal distance from center of coordinate system
/**
* Call rMax() and convert result to unit.
*
* \param unit string
* \return double rmax converted to unit
*/
virtual double rMax(std::string const &unit); ///< Get rmax_ is specified unit
virtual double rMax(std::string const &unit) const; ///< Get rmax_ is specified unit
/// Get max step constraint for adaptive integration
/**
* \param[in] coord position
* \return max step to find this object reliably
*/
virtual double deltaMax(double coord[8]);
const std::string kind() const; ///< Get the kind of the Astrobj (e.g. "Star")
/**
* Set maximal distance from center of coordinate system at which a
* Photon may hit the object.
*
* \param val new #rmax_ in geometrical units.
*/
virtual void rMax(double val); ///< Set maximal distance from center of coordinate system
/**
* Call Generic::rMax(double val) after converting val from unit
* to geometrical units.
*
* \param val #rmax_ expressed in unit "unit";
* \param unit string...
*/
virtual void rMax(double val, std::string const &unit); ///< Set maximal distance from center of coordinate system
/**
* Set flag indicating that radiative transfer should be integrated,
* i.e. the object is to be considered optically thin.
* \param flag: 1 if optically thin, 0 if optically thick.
*/
void opticallyThin(bool flag);
///< Set whether the object is optically thin.
/**
* See opticallyThin(bool flag).
*/
bool opticallyThin() const ;
///< Query whether object is optically thin.
void radiativeQ(bool flag);
bool radiativeQ() const ;
void showshadow(bool flag);
bool showshadow() const ;
void redshift(bool flag);
bool redshift() const ;
/**
* Return a Gyoto::Quantity_t suitable as input to
* Gyoto::Scenery::setRequestedQuantities() to set de default
* quantities to compute for this object. The default of these
* defaults GYOTO_QUANTITY_INTENSITY.
*/
virtual Gyoto::Quantity_t getDefaultQuantities();
///< Which quantities to compute if know was requested
//XML I/O
public:
#ifdef GYOTO_USE_XERCES
/**
* \brief Main loop in Subcontractor_t function
*
* The Subcontractor_t function for each Astrobj kind should look
* somewhat like this (templated as
* Gyoto::Astrobj::Subcontractor<MyKind>):
* \code
* SmartPointer<Astrobj::Generic>
* Gyoto::Astrobj::MyKind::Subcontractor(FactoryMessenger* fmp) {
* SmartPointer<MyKind> ao = new MyKind();
* ao -> setParameters(fmp);
* return ao;
* }
* \endcode
*
* Each object kind should implement setParameter(string name,
* string content, string unit) to interpret the individual XML
* elements. setParameters() can be overloaded in case the specific
* Astrobj class needs low level access to the FactoryMessenger. See
* UniformSphere::setParameters().
*/
virtual void setParameters(FactoryMessenger *fmp);
#endif
// Outputs
// -------
public:
/**
* Impact() checks whether a Photon impacts the object between two
* integration steps of the photon's trajectory (those two steps are
* photon->getCoord(index, coord1) and photon->getCoord(index+1,
* coord2)). Impact returns 1 if the photon impacts the object
* between these two steps, else 0. In many cases of geometrically
* thick obects, the implementation Astrobj::Standard::Impact() will
* be fine.
*
* Impact will call Generic::processHitQuantities() (which is
* virtual and may be re-implemented) to compute observable
* properties on demand: if the data pointer is non-NULL, the object
* will look in it for pointers to properties which apply to its
* kind. If a pointer to a property known to this object is present,
* then the property is computed and store at the pointed-to
* address. For instance, all objects know the "intensity"
* property. If data->intensity != NULL, the instensity is computed
* and stored in *data->intensity.
*
* If data is non-NULL and only in this case, processHitQuantities()
* will also call ph->transmit() to update the transmissions of the
* Photon (see Photon::transmit(size_t, double)). This must not be
* done if data is NULL (see Astrobj::Complex::Impact() for an
* explanation).
*
* \param ph Gyoto::Photon aimed at the object;
* \param index Index of the last photon step;
* \param data Pointer to a structure to hold the observables at impact.
*
* \return 1 if impact, 0 if not.
*/
virtual int Impact(Gyoto::Photon* ph, size_t index,
Astrobj::Properties *data=NULL) = 0 ;
///< Does a photon at these coordinates impact the object?
/**
* \brief Fills Astrobj::Properties
*
* processHitQuantities fills the requested data in Impact. To use
* it, you need to call it in the Impact() method for your object in
* case of hit. It will fill Redshift, Intensity, Spectrum,
* BinSpectrum and update the Photon's transmission by calling
* Photon::transmit(), only if data==NULL.
*
* You can overload it for your Astrobj. The generic implementation
* calls emission(), integrateEmission() and transmission() below.
*/
virtual void processHitQuantities(Photon* ph, double* coord_ph_hit,
double* coord_obj_hit, double dt,
Astrobj::Properties* data) const;
/**
* \brief Specific intensity I<SUB>ν</SUB>
*
* Called by the default implementation for processHitQuantities().
*
* emission() computes the intensity I<SUB>ν</SUB> emitted by the
* small volume of length ds<SUB>em</SUB>, in the emitter's
* frame. It should take self-absorption along ds<SUB>em</SUB> into
* account.
*
* Reminder :
* - intensity = I<SUB>ν</SUB> [J m^-2 s^-1 ster^-1 Hz^-1];
*
* - invariant intensity = I<SUB>ν</SUB>/ν<SUP>3</SUP>, which
* has the same value in any frame;
*
* - emission coefficient = j<SUB>ν</SUB> [J m^-3 s^-1 ster^-1
* Hz^-1] , defined by dI<SUB>ν</SUB> = j<SUB>ν</SUB>*ds,
* where ds is the distance travelled by the photon inside the
* object;
* - invariant emission coef = j<SUB>ν</SUB>/ν<SUP>2</SUP>,
* which has the same value in any frame.
*
* The equation used for radiative transfer (without absorption) is:
*
* d(I<SUB>ν</SUB>/ν<SUP>3</SUP>)/dλ = (j<SUB>ν</SUB>/ν<SUP>2</SUP>) [*]
*
* where λ is the integration parameter along the null geodesic.
*
* NB: Let us consider a particular observer, with ν being the
* frequency measured by this observer, and ds being the proper
* distance (as measured by the observer) that the photon travels
* as it moves from λ to λ+dλ along its
* geodesic. Then it can be shown that:
*
* dλ = ds/ν
*
* This shows that Eq. [*] is homogeneous.
*
* The default implementation returns 1. if optically thick and ds<SUB>em</SUB>
* if optically thin. It allows for a quick implementation of your
* object for visualization purposes.
*
* \param nu_em Frequency at emission [Hz]
* \param dsem length over which to integrate inside the object
* [geometrical units]
* \param coord_ph Photon coordinate
* \param coord_obj Emitter coordinate at current photon position
*/
virtual double emission(double nu_em, double dsem, double coord_ph[8],
double coord_obj[8]=NULL)
const ;
/**
* \brief Specific intensity I<SUB>ν</SUB> for several values of ν<SUB>em</SUB>
*
* Called by the default implementation for processHitQuantities().
*
* emission() computes the intensity I<SUB>ν</SUB> emitted by the small
* volume of length dsem. It should take self-absorption along dsem
* into account.
*
* Same as emission(double nu_em, double dsem, double coord_ph[8],
* double coord_obj[8]=NULL) const
* looping on several values of nu_em.
*
* \param Inu[nbnu] Output (must be set to a previously allocated
* array of doubles)
* \param nu_em[nbnu] Frequencies at emission
* \param nbnu Size of Inu[] and nu_em[]
* \param dsem Length over which to integrate inside the object
* \param coord_ph Photon coordinate
* \param coord_obj Emitter coordinate at current photon position
* \return I<SUB>ν</SUB> or dI<SUB>ν</SUB> [W m-2 sr-2]
*/
virtual void emission(double Inu[], double nu_em[], size_t nbnu,
double dsem, double coord_ph[8],
double coord_obj[8]=NULL) const ;
// Under development
virtual void radiativeQ(double Inu[], double Taunu[],
double nu_em[], size_t nbnu,
double dsem, double coord_ph[8],
double coord_obj[8]=NULL) const ;
/**
* Compute the integral of emission() from ν<SUB>1</SUB> to
* ν<SUB>2</SUB>. The default implementation is a numerical
* integrator which works well enough and is reasonably fast if
* emission() is a smooth function (i.e. no emission or absorption
* lines). If possible, it is wise to implement an analytical
* solution. It is used by processHitQuantities to compute the
* "BinSpectrum" quantity which is the most physical: it is the only
* quantity that can be actually measured directly by a real-life
* instrument.
*/
virtual double integrateEmission(double nu1, double nu2, double dsem,
double c_ph[8], double c_obj[8]=NULL) const;
///< ∫<SUB>ν<SUB>1</SUB></SUB><SUP>ν<SUB>2</SUB></SUP> I<SUB>ν</SUB> dν (or j<SUB>ν</SUB>)
/**
* Like double integrateEmission(double nu1, double nu2, double
* dsem, double c_ph[8], double c_obj[8]) const for each
* Spectrometer channel.
*/
virtual void integrateEmission(double * I, double const * boundaries,
size_t const * chaninds, size_t nbnu,
double dsem, double *cph, double *co) const;
///< ∫<SUB>ν<SUB>1</SUB></SUB><SUP>ν<SUB>2</SUB></SUP> I<SUB>ν</SUB> dν (or j<SUB>ν</SUB>)
/**
* transmission() computes the transmission of this fluid element or
* 0 if optically thick. The default implementation returns 1. (no
* attenuation) if optically thin, 0. if optically thick.
*
* \param nuem frequency in the fluid's frame
* \param coord Photon coordinate
* \param dsem geometrical length in geometrical units
*/
virtual double transmission(double nuem, double dsem, double coord[8]) const ;
///< Transmission: exp( α<SUB>ν</SUB> * ds<SUB>em</SUB> )
};
/**
* \class Gyoto::Astrobj::Properties
* \brief Observable properties of an Astronomical object
*
* The sort of properties one wants to measure on a ray-traced
* Gyoto::Photon which hits a Gyoto::Astrobj. Not all Astrobj are
* able to fill all of these properties.
*
* An instance of Properties essentially contains a bunch of pointers
* to memory areas where the observable quantities (see Quantity_t)
* should be stored.
*
* Astrobj::Generic::processHitQuantities() fills the various arrays
* upon request. A quantity is ignored if the corresponding pointer
* is NULL.
*
* Scenery::operator()() increments the Properties between each
* Photon using Properties::operator++().
*
* The main application (gyoto, the yorick plug-in, or your user
* application) is responsible for allocating the various arrays,
* filling the various members of Properties, and doing whatever
* meaninful with the arrays after they have been filled with values
* by the ray-tracing code (e.g. saving them to disk or displaying
* them).
*
* Also see Gyoto::Scenery and Gyoto::Quantity_t.
*/
class Gyoto::Astrobj::Properties : public Gyoto::SmartPointee {
friend class Gyoto::SmartPointer<Gyoto::Astrobj::Properties>;
public:
double *intensity; ///< GYOTO_QUANTITY_INTENSITY : Intensity
double *time; ///< GYOTO_QUANTITY_EMISSIONTIME: EmissionTime
/**
* Behaves like the square of the closest distance between Photon
* and Astrobj (but not exactly that). Initialize it to DBL_MAX from
* float.h.;
*/
double *distance; ///< GYOTO_QUANTITY_MIN_DISTANCE: MinDistance
/**
* First local minimum in distance from object
*/
double * first_dmin; ///< GYOTO_QUANTITY_FIRST_DMIN : FirstDmin
/**
* Properties::first_dmin will be set to the first local minimum and
* Properties::first_dmin_found will be set to 1 if a local minimum
* in distance is found. Initialize it to 0.
*/
int first_dmin_found; ///< Whether Properties::first_dmin was found
/**
* Redshift factor ν<SUB>obs</SUB>/ν<SUB>em</SUB> (necessary
* for emission lines computation)
*/
double *redshift; ///< GYOTO_QUANTITY_REDSHIFT : RedShift
/**
* I<SUB>ν</SUB> (ν) (observed specific intensity)
*/
double *spectrum; ///< GYOTO_QUANTITY_SPECTRUM : Spectrum
/**
* I<SUB>ν<SUB>1</SUB></SUB><SUP>ν<SUB>2</SUB></SUP>, the
* integral of I<SUB>ν</SUB> over each spectral channel
* (i.e. what a spectrometer would measure)
*/
double *binspectrum; ///< GYOTO_QUANTITY_BINSPECTRUM : BinSpectrum
/**
* Spectra elements are separated by offset doubles in memory. In
* other words, the ith spectral element is spectrum[i*offset].
*/
ptrdiff_t offset; ///< How to jump from one spectral element to the next
/**
* Coordinates of the object and photon at impact
*/
double * impactcoords; ///< GYOTO_QUANTITY_IMPACTCOORDS: ImpactCoords
/**
* \brief GYOTO_QUANTITY_USER1 : User1
* Astrobj-specific quantity
*/
double *user1;
/**
* \brief GYOTO_QUANTITY_USER2 : User2
* Astrobj-specific quantity
*/
double *user2;
/**
* \brief GYOTO_QUANTITY_USER3 : User3
* Astrobj-specific quantity
*/
double *user3;
/**
* \brief GYOTO_QUANTITY_USER4 : User4
* Astrobj-specific quantity
*/
double *user4;
/**
* \brief GYOTO_QUANTITY_USER5 : User5
* Astrobj-specific quantity
*/
double *user5;
# ifdef HAVE_UDUNITS
/**
* \brief Converter between SI (J.m <SUP> -2</SUP>.s<SUP>-1</SUP>.sr<SUP>-1</SUP>.Hz<SUP>-1</SUP>) and requested Intensity unit
*/
Gyoto::SmartPointer<Gyoto::Units::Converter> intensity_converter_ ;
/**
* \brief Converter between SI (J.m <SUP> -2</SUP>.s<SUP>-1</SUP>.sr<SUP>-1</SUP>.Hz<SUP>-1</SUP>) and requested Spectrum unit
*/
Gyoto::SmartPointer<Gyoto::Units::Converter> spectrum_converter_ ;
/**
* \brief Converter between SI (J.m <SUP> -2</SUP>.s<SUP>-1</SUP>.sr<SUP>-1</SUP>) and requested BinSpectrum unit
*/
Gyoto::SmartPointer<Gyoto::Units::Converter> binspectrum_converter_ ;
# endif
/// True if buffers are allocated for entire field (npix*npix)
bool alloc;
public:
Properties(); ///< Default constructor (everything is set to NULL);
Properties (double*, double*); ///<< Set intensity and time pointers.
/**
* \brief Initialize observable quantities
*
* The pointed-to values are initialized as follows (if the
* corresponding pointer is not NULL):
*
* - intensity, firt_dmin_found, redshift, userN: 0
* - time, distance, first_dmin: DBL_MAX
* - for spectrum and binspectrum, nbnuobs values separated by offset in memory are initialized to 0
* - for impactcoords, 16 contiguous values are initialized to DBL_MAX
*/
void init(size_t nbnuobs=0);
/**
* \brief Increment pointers
*
* All valid pointers are incremented by 1 (sizeof(double)), excepted
* impactcoords which is incremented by 16.
*/
Properties& operator++();
/**
* \brief Increment pointers by offset
*
* All valid pointers are incremented by offset (sizeof(double)), excepted
* impactcoords which is incremented by 16*offset.
*/
Properties& operator+=(ptrdiff_t offset);
operator Gyoto::Quantity_t () const;
# ifdef HAVE_UDUNITS
void intensityConverter(Gyoto::SmartPointer<Gyoto::Units::Converter>);
///< Set Properties::intentity_converter_
void intensityConverter(std::string);
///< Set Properties::intentity_converter_
void spectrumConverter(Gyoto::SmartPointer<Gyoto::Units::Converter>);
///< Set Properties::spectrum_converter_
void spectrumConverter(std::string);
///< Set Properties::spectrum_converter_
void binSpectrumConverter(Gyoto::SmartPointer<Gyoto::Units::Converter>);
///< Set Properties::binspectrum_converter_
void binSpectrumConverter(std::string);
///< Set Properties::binspectrum_converter_
# endif
};
#endif
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