BoxCornerDomain.h 6.56 KB
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//
// Class BoxCornerDomain
//   :FIXME: add brief description
//
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// Copyright (c) 2008,        Yves Ineichen, ETH Zürich,
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//               2013 - 2015, Tülin Kaman, Paul Scherrer Institut, Villigen PSI, Switzerland
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//               2017 - 2020, Paul Scherrer Institut, Villigen PSI, Switzerland
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// All rights reserved
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//
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// Implemented as part of the master thesis
// "A Parallel Multigrid Solver for Beam Dynamics"
// and the paper
// "A fast parallel Poisson solver on irregular domains applied to beam dynamics simulations"
// (https://doi.org/10.1016/j.jcp.2010.02.022)
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//
// This file is part of OPAL.
//
// OPAL 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.
//
// You should have received a copy of the GNU General Public License
// along with OPAL. If not, see <https://www.gnu.org/licenses/>.
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//
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#ifndef BOXCORNER_DOMAIN_H
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#define BOXCORNER_DOMAIN_H
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#include <map>
#include <string>
#include <cmath>
#include <iostream>  // Neeeded for stream I/O
#include <fstream>   // Needed for file I/O
#include "IrregularDomain.h"


/*

    A_m and B_m are the half apperture of the box


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                                     / (A_m,B_m)
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                                    /
                                   /
                                  /
    L1_m                         /
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------------      --------------+ (-A_m,B_m)
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           | L2_m |             |
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        C_m|      |             |
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           |------|             |      /
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         .....                  |     /
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(0,0)---.......-----------------+    /
         .....                  |   /
   z                            |  /
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   |                            | /
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--------------------------------+/ (-A_m,-B_m)

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            Length_m
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Test in which of the 3 parts of the geometry we are in.

    if((z < L1_m) || (z > (L1_m + L2_m)))
        b = B_m;
    else
        b = B_m-C_m;

*/

class BoxCornerDomain : public IrregularDomain {

public:
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    using IrregularDomain::StencilIndex_t;
    using IrregularDomain::StencilValue_t;
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    BoxCornerDomain(Vector_t nr, Vector_t hr);
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    BoxCornerDomain(double A, double B, double C, double Length, double L1, double L2, Vector_t nr, Vector_t hr,
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                    std::string interpl);
    ~BoxCornerDomain();

    /// returns discretization at (x,y,z)
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    void getBoundaryStencil(int x, int y, int z, StencilValue_t& value, double &scaleFactor);
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    /// we do not need this
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    int getNumXY(int /*z*/) { return -1;}
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    /// as a function of z, determine the hight (B) of the geometry
    inline double getB(double z) {
      if((z < L1_m) || (z > (L1_m + L2_m)))
            return B_m;
        else
            return B_m - C_m;
    }

    /// queries if a given (x,y,z) coordinate lies inside the domain
    inline bool isInside(int x, int y, int z) {
        const double xx = (x - (nr[0] - 1) / 2.0) * hr[0];
        const double yy = (y - (nr[1] - 1) / 2.0) * hr[1];
        const double b = getB(z * hr[2]);
        return (xx < A_m && yy < b && z != 0 && z != nr[2] - 1);
    }

    /// set semi-minor
    //void setSemiMinor(double sm) {SemiMinor = sm;}
    /// set semi-major
    //void setSemiMajor(double sm) {SemiMajor = sm;}

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    void compute(Vector_t hr, NDIndex<3> localId);
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    double getXRangeMin() { return -A_m; }
    double getXRangeMax() { return  A_m; }
    double getYRangeMin() { return  -B_m;} // actBMin_m; }
    double getYRangeMax() { return  B_m; } // actBMax_m; }
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    double getZRangeMin() { return  L1_m;}
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    double getZRangeMax() { return  L1_m+L2_m; }
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    //TODO: ?
    int getStartIdx() {return 0;}

private:

    //XXX: since the Y coorindate is dependent on the Z value we need (int,
    //int) -> intersection. To simplify things (for now) we use the same
    //structure for X...
    /// Map from a ([(x or y], z) to a list of intersection values with
    /// boundary.
    typedef std::multimap< std::pair<int, int>, double > BoxCornerPointList;

    /// all intersection points with grid lines in X direction
    BoxCornerPointList IntersectXDir;

    /// all intersection points with grid lines in Y direction
    BoxCornerPointList IntersectYDir;

    /// mapping (x,y,z) -> idx
    std::map<int, int> IdxMap;

    /// mapping idx -> (x,y,z)
    std::map<int, int> CoordMap;

    /// depth of the box
    double A_m;

    /// the maximal hight of the box
    double B_m;

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    /// because the geometry can change in the y direction
    double actBMin_m;

    double actBMax_m;

    /// hight of the corner
    double C_m;

    /// lenght of the structure
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    double Length_m;
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    /// lenght of the first part of the structure
    double L1_m;

    /// lenght of the corner
    double L2_m;

    /// semi-major of the ellipse
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    // :FIXME: unused
    //double SemiMajor;
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    /// semi-minor of the ellipse
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    // :FIXME: unused
    //double SemiMinor;
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    /// interpolation type
    int interpolationMethod;

    /// for debug reasons
   std::ofstream os_m;





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    inline double getXIntersection(double cx, int /*z*/) {
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        if(cx < 0)
            return -A_m;
        else
            return  A_m;
    }

    inline double getYIntersection(double cy, int z) {
        if(cy < 0)
            return -B_m;
        else
            return getB(z * hr[2]);
    }

    /// conversion from (x,y,z) to index in xyz plane
    inline int toCoordIdx(int x, int y, int z) {
        return (z * nr[1] + y) * nr[0] + x;
    }

    /// conversion from (x,y,z) to index on the 3D grid
    /*inline*/
    inline int getIdx(int x, int y, int z) {
        if(isInside(x, y, z) && x >= 0 && y >= 0 && z >= 0)
            return IdxMap[toCoordIdx(x, y, z)];
        else
            return -1;
    }

    /// conversion from a 3D index to (x,y,z)
    inline void getCoord(int idx, int &x, int &y, int &z) {

        int idxx = CoordMap[idx];

        x = idxx % (int)nr[0];
        idxx /= nr[0];
        y = idxx % (int)nr[1];
        idxx /= nr[1];
        z = idxx;

    }

    /// different interpolation methods for boundary points
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    void constantInterpolation(int x, int y, int z, StencilValue_t& value,
                               double &scaleFactor);

    void linearInterpolation(int x, int y, int z, StencilValue_t& value,
                             double &scaleFactor);

    void quadraticInterpolation(int x, int y, int z, StencilValue_t& value,
                                double &scaleFactor);
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};

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#endif

// vi: set et ts=4 sw=4 sts=4:
// Local Variables:
// mode:c
// c-basic-offset: 4
// indent-tabs-mode: nil
// require-final-newline: nil
// End: