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/* This file is part of the OpenLB library
*
* Copyright (C) 2017 Adrian Kummerlaender
* E-mail contact: info@openlb.net
* The most recent release of OpenLB can be downloaded at
* <http://www.openlb.net/>
*
* This program 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 2
* of the License, or (at your option) any later version.
*
* This program 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 this program; if not, write to the Free
* Software Foundation, Inc., 51 Franklin Street, Fifth Floor,
* Boston, MA 02110-1301, USA.
*/
#ifndef SUPER_PLANE_INTEGRAL_FLUX_F_3D_H
#define SUPER_PLANE_INTEGRAL_FLUX_F_3D_H
#include "superPlaneIntegralF3D.h"
#include "functors/lattice/superLatticeLocalF3D.h"
namespace olb {
/// Template class for building flux integrals based on SuperLatticePhysF3D functors
/**
* e.g. phys pressure flux is derived from SuperPlaneIntegralFluxF3D<T,SuperLatticePhysPressure3D> and only adds a print method.
* All required constructors are provided by this class and need only be inherited.
*
* The constructors correspond to SuperPlaneIntegralF3D's with the difference
* that they accept a super lattice and a unit converter reference instead of
* a functor.
* The appropropriate SuperLatticePhysF3D derived functor is then instantiated
* internally as defined by the template argument F.
*
* See SuperPlaneIntegralF3D for further documentation.
**/
template<typename T, template<typename, typename> class F>
class SuperPlaneIntegralFluxF3D : public SuperPlaneIntegralF3D<T> {
public:
template<typename DESCRIPTOR>
SuperPlaneIntegralFluxF3D(SuperLattice3D<T, DESCRIPTOR>& sLattice,
const UnitConverter<T,DESCRIPTOR>& converter,
SuperGeometry3D<T>& geometry,
const HyperplaneLattice3D<T>& hyperplaneLattice,
FunctorPtr<SuperIndicatorF3D<T>>&& integrationIndicator,
FunctorPtr<IndicatorF2D<T>>&& subplaneIndicator,
BlockDataReductionMode mode=BlockDataReductionMode::Analytical);
template<typename DESCRIPTOR>
SuperPlaneIntegralFluxF3D(SuperLattice3D<T, DESCRIPTOR>& sLattice,
const UnitConverter<T,DESCRIPTOR>& converter,
SuperGeometry3D<T>& geometry,
const Hyperplane3D<T>& hyperplane,
FunctorPtr<SuperIndicatorF3D<T>>&& integrationIndicator,
FunctorPtr<IndicatorF2D<T>>&& subplaneIndicator,
BlockDataReductionMode mode=BlockDataReductionMode::Analytical);
template<typename DESCRIPTOR>
SuperPlaneIntegralFluxF3D(SuperLattice3D<T, DESCRIPTOR>& sLattice,
const UnitConverter<T,DESCRIPTOR>& converter,
SuperGeometry3D<T>& geometry,
const Hyperplane3D<T>& hyperplane,
FunctorPtr<SuperIndicatorF3D<T>>&& integrationIndicator,
BlockDataReductionMode mode=BlockDataReductionMode::Analytical);
template<typename DESCRIPTOR>
SuperPlaneIntegralFluxF3D(SuperLattice3D<T, DESCRIPTOR>& sLattice,
const UnitConverter<T,DESCRIPTOR>& converter,
SuperGeometry3D<T>& geometry,
const Vector<T,3>& origin,
const Vector<T,3>& u, const Vector<T,3>& v,
std::vector<int> materials,
BlockDataReductionMode mode=BlockDataReductionMode::Analytical);
template<typename DESCRIPTOR>
SuperPlaneIntegralFluxF3D(SuperLattice3D<T, DESCRIPTOR>& sLattice,
const UnitConverter<T,DESCRIPTOR>& converter,
SuperGeometry3D<T>& geometry,
const Vector<T,3>& origin,
const Vector<T,3>& u, const Vector<T,3>& v,
BlockDataReductionMode mode=BlockDataReductionMode::Analytical);
template<typename DESCRIPTOR>
SuperPlaneIntegralFluxF3D(SuperLattice3D<T, DESCRIPTOR>& sLattice,
const UnitConverter<T,DESCRIPTOR>& converter,
SuperGeometry3D<T>& geometry,
const Vector<T,3>& origin,
const Vector<T,3>& normal,
std::vector<int> materials,
BlockDataReductionMode mode=BlockDataReductionMode::Analytical);
template<typename DESCRIPTOR>
SuperPlaneIntegralFluxF3D(SuperLattice3D<T, DESCRIPTOR>& sLattice,
const UnitConverter<T,DESCRIPTOR>& converter,
SuperGeometry3D<T>& geometry,
const Vector<T,3>& origin,
const Vector<T,3>& normal,
BlockDataReductionMode mode=BlockDataReductionMode::Analytical);
template<typename DESCRIPTOR>
SuperPlaneIntegralFluxF3D(SuperLattice3D<T, DESCRIPTOR>& sLattice,
const UnitConverter<T,DESCRIPTOR>& converter,
SuperGeometry3D<T>& geometry,
const Vector<T,3>& normal,
std::vector<int> materials,
BlockDataReductionMode mode=BlockDataReductionMode::Analytical);
template<typename DESCRIPTOR>
SuperPlaneIntegralFluxF3D(SuperLattice3D<T, DESCRIPTOR>& sLattice,
const UnitConverter<T,DESCRIPTOR>& converter,
SuperGeometry3D<T>& geometry,
const Vector<T,3>& normal,
BlockDataReductionMode mode=BlockDataReductionMode::Analytical);
template<typename DESCRIPTOR>
SuperPlaneIntegralFluxF3D(SuperLattice3D<T, DESCRIPTOR>& sLattice,
const UnitConverter<T,DESCRIPTOR>& converter,
SuperGeometry3D<T>& geometry,
IndicatorCircle3D<T>& circle,
std::vector<int> materials,
BlockDataReductionMode mode=BlockDataReductionMode::Analytical);
template<typename DESCRIPTOR>
SuperPlaneIntegralFluxF3D(SuperLattice3D<T, DESCRIPTOR>& sLattice,
const UnitConverter<T,DESCRIPTOR>& converter,
SuperGeometry3D<T>& geometry,
IndicatorCircle3D<T>& circle,
BlockDataReductionMode mode=BlockDataReductionMode::Analytical);
};
/// Pressure flux plane integral
/**
* Only adds a print method.
* Calculation is implemented in SuperPlaneIntegralF3D which is constructed around
* SuperLatticePhysPressure3D by SuperPlaneIntegralFluxF3D.
**/
template<typename T>
class SuperPlaneIntegralFluxPressure3D final
: public SuperPlaneIntegralFluxF3D<T, SuperLatticePhysPressure3D> {
public:
using SuperPlaneIntegralFluxF3D<T, SuperLatticePhysPressure3D>::SuperPlaneIntegralFluxF3D;
void print(std::string regionName = "",
std::string fluxSiScaleName = "N",
std::string meanSiScaleName = "Pa");
};
/// Velocity flux plane integral
/**
* Only adds a print method.
* Calculation is implemented in SuperPlaneIntegralF3D which is constructed around
* SuperLatticePhysVelocity3D by SuperPlaneIntegralFluxF3D.
**/
template<typename T>
class SuperPlaneIntegralFluxVelocity3D final
: public SuperPlaneIntegralFluxF3D<T, SuperLatticePhysVelocity3D> {
public:
using SuperPlaneIntegralFluxF3D<T, SuperLatticePhysVelocity3D>::SuperPlaneIntegralFluxF3D;
void print(std::string regionName = "",
std::string fluxSiScaleName = "m^3/s",
std::string meanSiScaleName = "m/s");
};
}
#endif
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