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/* This file is part of the OpenLB library
*
* Copyright (C) 2006, 2007 Jonas Latt
* E-mail contact: info@openlb.net
* The most recent release of OpenLB can be downloaded at
* <http://www.openlb.net/>
*
* Generic version of the collision, which modifies the particle
* distribution functions, by Orestis Malaspinas.
*
* 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 FD_BOUNDARIES_2D_H
#define FD_BOUNDARIES_2D_H
#include "core/postProcessing.h"
#include "momentaOnBoundaries.h"
#include "core/blockLattice2D.h"
namespace olb {
/**
* This class computes the skordos BC
* on a flat wall in 2D but with a limited number of terms added to the
* equilibrium distributions (i.e. only the Q_i : Pi term)
*/
template<typename T, typename DESCRIPTOR, int direction, int orientation>
class StraightFdBoundaryProcessor2D : public LocalPostProcessor2D<T,DESCRIPTOR> {
public:
StraightFdBoundaryProcessor2D(int x0_, int x1_, int y0_, int y1_);
int extent() const override
{
return 1;
}
int extent(int whichDirection) const override
{
return 1;
}
void process(BlockLattice2D<T,DESCRIPTOR>& blockLattice) override;
void processSubDomain ( BlockLattice2D<T,DESCRIPTOR>& blockLattice,
int x0_, int x1_, int y0_, int y1_ ) override;
private:
template<int deriveDirection>
void interpolateGradients (
BlockLattice2D<T,DESCRIPTOR> const& blockLattice,
T velDeriv[DESCRIPTOR::d], int iX, int iY ) const;
private:
int x0, x1, y0, y1;
};
template<typename T, typename DESCRIPTOR, int direction, int orientation>
class StraightFdBoundaryProcessorGenerator2D : public PostProcessorGenerator2D<T,DESCRIPTOR> {
public:
StraightFdBoundaryProcessorGenerator2D(int x0_, int x1_, int y0_, int y1_);
PostProcessor2D<T,DESCRIPTOR>* generate() const override;
PostProcessorGenerator2D<T,DESCRIPTOR>* clone() const override;
};
/**
* This class computes a convection BC on a flat wall in 2D
*/
template<typename T, typename DESCRIPTOR, int direction, int orientation>
class StraightConvectionBoundaryProcessor2D : public LocalPostProcessor2D<T,DESCRIPTOR> {
public:
StraightConvectionBoundaryProcessor2D(int x0_, int x1_, int y0_, int y1_, T* uAv_ = NULL);
~StraightConvectionBoundaryProcessor2D() override;
int extent() const override
{
return 1;
}
int extent(int whichDirection) const override
{
return 1;
}
void process(BlockLattice2D<T,DESCRIPTOR>& blockLattice) override;
void processSubDomain ( BlockLattice2D<T,DESCRIPTOR>& blockLattice,
int x0_, int x1_, int y0_, int y1_ ) override;
private:
int x0, x1, y0, y1;
T*** saveCell;
T* uAv;
};
template<typename T, typename DESCRIPTOR, int direction, int orientation>
class StraightConvectionBoundaryProcessorGenerator2D : public PostProcessorGenerator2D<T,DESCRIPTOR> {
public:
StraightConvectionBoundaryProcessorGenerator2D(int x0_, int x1_, int y0_, int y1_, T* uAv_ = NULL);
PostProcessor2D<T,DESCRIPTOR>* generate() const override;
PostProcessorGenerator2D<T,DESCRIPTOR>* clone() const override;
private:
T* uAv;
};
/**
* This class computes a slip BC in 2D
*/
template<typename T, typename DESCRIPTOR>
class SlipBoundaryProcessor2D : public LocalPostProcessor2D<T,DESCRIPTOR> {
public:
SlipBoundaryProcessor2D(int x0_, int x1_, int y0_, int y1_, int discreteNormalX_, int discreteNormalY_);
int extent() const override
{
return 0;
}
int extent(int whichDirection) const override
{
return 0;
}
void process(BlockLattice2D<T,DESCRIPTOR>& blockLattice) override;
void processSubDomain ( BlockLattice2D<T,DESCRIPTOR>& blockLattice,
int x0_, int x1_, int y0_, int y1_ ) override;
private:
int reflectionPop[DESCRIPTOR::q];
int x0, x1, y0, y1;
};
template<typename T, typename DESCRIPTOR>
class SlipBoundaryProcessorGenerator2D : public PostProcessorGenerator2D<T,DESCRIPTOR> {
public:
SlipBoundaryProcessorGenerator2D(int x0_, int x1_, int y0_, int y1_, int discreteNormalX_, int discreteNormalY_);
PostProcessor2D<T,DESCRIPTOR>* generate() const override;
PostProcessorGenerator2D<T,DESCRIPTOR>* clone() const override;
private:
int discreteNormalX;
int discreteNormalY;
};
/**
* This class computes a partial slip BC in 2D
*/
template<typename T, typename DESCRIPTOR>
class PartialSlipBoundaryProcessor2D : public LocalPostProcessor2D<T,DESCRIPTOR> {
public:
PartialSlipBoundaryProcessor2D(T tuner_, int x0_, int x1_, int y0_, int y1_, int discreteNormalX_, int discreteNormalY_);
int extent() const override
{
return 0;
}
int extent(int whichDirection) const override
{
return 0;
}
void process(BlockLattice2D<T,DESCRIPTOR>& blockLattice) override;
void processSubDomain ( BlockLattice2D<T,DESCRIPTOR>& blockLattice,
int x0_, int x1_, int y0_, int y1_ ) override;
private:
int reflectionPop[DESCRIPTOR::q];
int x0, x1, y0, y1;
T tuner;
};
template<typename T, typename DESCRIPTOR>
class PartialSlipBoundaryProcessorGenerator2D : public PostProcessorGenerator2D<T,DESCRIPTOR> {
public:
PartialSlipBoundaryProcessorGenerator2D(T tuner_, int x0_, int x1_, int y0_, int y1_, int discreteNormalX_, int discreteNormalY_);
PostProcessor2D<T,DESCRIPTOR>* generate() const override;
PostProcessorGenerator2D<T,DESCRIPTOR>* clone() const override;
private:
int discreteNormalX;
int discreteNormalY;
T tuner;
};
/**
* This class computes the skordos BC in 2D on a convex
* corner but with a limited number of terms added to the
* equilibrium distributions (i.e. only the Q_i : Pi term)
*/
template<typename T, typename DESCRIPTOR, int xNormal,int yNormal>
class OuterVelocityCornerProcessor2D : public LocalPostProcessor2D<T, DESCRIPTOR> {
public:
OuterVelocityCornerProcessor2D(int x_, int y_);
int extent() const override
{
return 2;
}
int extent(int whichDirection) const override
{
return 2;
}
void process(BlockLattice2D<T,DESCRIPTOR>& blockLattice) override;
void processSubDomain(BlockLattice2D<T,DESCRIPTOR>& blockLattice,
int x0_,int x1_,int y0_,int y1_ ) override;
private:
int x, y;
};
template<typename T, typename DESCRIPTOR, int xNormal,int yNormal>
class OuterVelocityCornerProcessorGenerator2D : public PostProcessorGenerator2D<T, DESCRIPTOR> {
public:
OuterVelocityCornerProcessorGenerator2D(int x_, int y_);
PostProcessor2D<T,DESCRIPTOR>* generate() const override;
PostProcessorGenerator2D<T,DESCRIPTOR>* clone() const override;
};
/// PostProcessor for the wetting boundary condition in the free energy model. This is
/// required to set rho on the boundary (using the denisty of the neighbouring cell in
/// direction of inwards facing normal at the boundary), as the coupling between the
/// lattices requires the calculation of a density gradient.
template<typename T, typename DESCRIPTOR>
class FreeEnergyWallProcessor2D : public LocalPostProcessor2D<T, DESCRIPTOR> {
public:
FreeEnergyWallProcessor2D(int x0_, int x1_, int y0_, int y1_,
int discreteNormalX_, int discreteNormalY_, T addend_);
int extent() const override
{
return
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