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01 April 2022, 11:01:29 UTC
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Tip revision: 8a63aad14bd20455c14b1e165cdacd42c5cab1c1 authored by Dmitri Naumov on 01 October 2021, 18:56:32 UTC
[T/TES] Use direct solver in Zeolite Newton test.
Tip revision: 8a63aad
PrismRule6.cpp 
/**
 * \file
 * \copyright
 * Copyright (c) 2012-2021, OpenGeoSys Community (http://www.opengeosys.org)
 *            Distributed under a Modified BSD License.
 *              See accompanying file LICENSE.txt or
 *              http://www.opengeosys.org/project/license
 *
 */

#include "PrismRule6.h"

#include "BaseLib/Logging.h"
#include "MathLib/GeometricBasics.h"
#include "MeshLib/Node.h"
#include "Quad.h"
#include "Tri.h"

namespace MeshLib
{
const unsigned PrismRule6::face_nodes[5][4] = {
    {0, 2, 1, 99},  // Face 0
    {0, 1, 4, 3},   // Face 1
    {1, 2, 5, 4},   // Face 2
    {2, 0, 3, 5},   // Face 3
    {3, 4, 5, 99}   // Face 4
};

const unsigned PrismRule6::edge_nodes[9][2] = {
    {0, 1},  // Edge 0
    {1, 2},  // Edge 1
    {0, 2},  // Edge 2
    {0, 3},  // Edge 3
    {1, 4},  // Edge 4
    {2, 5},  // Edge 5
    {3, 4},  // Edge 6
    {4, 5},  // Edge 7
    {3, 5}   // Edge 8
};

const unsigned PrismRule6::n_face_nodes[5] = {3, 4, 4, 4, 3};

const Element* PrismRule6::getFace(const Element* e, unsigned i)
{
    if (i < n_faces)
    {
        unsigned nFaceNodes(PrismRule6::n_face_nodes[i]);
        auto** nodes = new Node*[nFaceNodes];
        for (unsigned j = 0; j < nFaceNodes; j++)
        {
            nodes[j] = const_cast<Node*>(e->getNode(face_nodes[i][j]));
        }

        if (i == 0 || i == 4)
        {
            return new Tri(nodes, e->getID());
        }

        return new Quad(nodes);
    }
    ERR("Error in MeshLib::Element::getFace() - Index {:d} does not exist.", i);
    return nullptr;
}

double PrismRule6::computeVolume(Node const* const* _nodes)
{
    return MathLib::calcTetrahedronVolume(
               *_nodes[0], *_nodes[1], *_nodes[2], *_nodes[3]) +
           MathLib::calcTetrahedronVolume(
               *_nodes[1], *_nodes[4], *_nodes[2], *_nodes[3]) +
           MathLib::calcTetrahedronVolume(
               *_nodes[2], *_nodes[4], *_nodes[5], *_nodes[3]);
}

bool PrismRule6::isPntInElement(Node const* const* nodes,
                                MathLib::Point3d const& pnt,
                                double eps)
{
    return (MathLib::isPointInTetrahedron(
                pnt, *nodes[0], *nodes[1], *nodes[2], *nodes[3], eps) ||
            MathLib::isPointInTetrahedron(
                pnt, *nodes[1], *nodes[4], *nodes[2], *nodes[3], eps) ||
            MathLib::isPointInTetrahedron(
                pnt, *nodes[2], *nodes[4], *nodes[5], *nodes[3], eps));
}

unsigned PrismRule6::identifyFace(Node const* const* _nodes,
                                  Node const* nodes[3])
{
    for (unsigned i = 0; i < 5; i++)
    {
        unsigned flag(0);
        for (unsigned j = 0; j < 4; j++)
        {
            for (unsigned k = 0; k < 3; k++)
            {
                if (face_nodes[i][j] != 99 &&
                    _nodes[face_nodes[i][j]] == nodes[k])
                {
                    flag++;
                }
            }
        }
        if (flag == 3)
        {
            return i;
        }
    }
    return std::numeric_limits<unsigned>::max();
}

ElementErrorCode PrismRule6::validate(const Element* e)
{
    ElementErrorCode error_code;
    error_code[ElementErrorFlag::ZeroVolume] = hasZeroVolume(*e);

    for (unsigned i = 1; i < 4; ++i)
    {
        const auto* quad(dynamic_cast<const MeshLib::Quad*>(e->getFace(i)));
        if (quad)
        {
            error_code |= quad->validate();
        }
        else
        {
            error_code.set(ElementErrorFlag::NodeOrder);
        }
        delete quad;
    }
    error_code[ElementErrorFlag::NodeOrder] = !e->testElementNodeOrder();
    return error_code;
}

}  // end namespace MeshLib
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