libgmsh-dev 2.8.5+dfsg-1.1+b1 / usr / include / gmsh / femTerm.h

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// Gmsh - Copyright (C) 1997-2014 C. Geuzaine, J.-F. Remacle
//
// See the LICENSE.txt file for license information. Please report all
// bugs and problems to the public mailing list <gmsh@geuz.org>.

#ifndef _FEM_TERM_H_
#define _FEM_TERM_H_

#include <math.h>
#include <map>
#include <vector>
#include "fullMatrix.h"
#include "simpleFunction.h"
#include "dofManager.h"
#include "GModel.h"
#include "SElement.h"
#include "groupOfElements.h"

// a nodal finite element term : variables are always defined at nodes
// of the mesh
template<class T>
class femTerm {
 private:
  typedef typename dofTraits<T>::VecType dataVec;
  typedef typename dofTraits<T>::MatType dataMat;
 protected:
  GModel *_gm;
 public:
  femTerm(GModel *gm) : _gm(gm) {}
  virtual ~femTerm() {}
  // return the number of columns of the element matrix
  virtual int sizeOfC(SElement *se) const = 0;
  // return the number of rows of the element matrix
  virtual int sizeOfR(SElement *se) const = 0;
  // in a given element, return the dof associated to a given row (column)
  // of the local element matrix
  virtual Dof getLocalDofR(SElement *se, int iRow) const = 0;
  // default behavior: symmetric
  virtual Dof getLocalDofC(SElement *se, int iCol) const
  {
    return getLocalDofR(se, iCol);
  }
  // compute the elementary matrix
  virtual void elementMatrix(SElement *se, fullMatrix<dataMat> &m) const = 0;
  virtual void elementVector(SElement *se, fullVector<dataVec> &m) const
  {
     m.scale(0.0);
  }

  // add the contribution from all the elements in the intersection
  // of two element groups L and C
  void addToMatrix(dofManager<dataVec> &dm,
                   groupOfElements &L,
                   groupOfElements &C) const
  {
    groupOfElements::elementContainer::const_iterator it = L.begin();
    for ( ; it != L.end() ; ++it){
      MElement *eL = *it;
      if (&C == &L || C.find(eL)){
        SElement se(eL);
        addToMatrix(dm, &se);
      }
    }
  }

  // add the contribution from a single element to the dof manager
  void addToMatrix(dofManager<dataVec> &dm, SElement *se) const
  {
    const int nbR = sizeOfR(se);
    const int nbC = sizeOfC(se);
    fullMatrix<dataMat> localMatrix(nbR, nbC);
    elementMatrix(se, localMatrix);
    addToMatrix(dm, localMatrix, se);
  }
  void addToMatrix(dofManager<dataVec> &dm,
                   fullMatrix<dataMat> &localMatrix,
                   SElement *se) const
  {
    const int nbR = localMatrix.size1();
    const int nbC = localMatrix.size2();
    std::vector<Dof> R,C; // better use default consdtructors and reserve the right amount of space to avoid reallocation
    R.reserve(nbR);
    C.reserve(nbC);
    bool sym=true; 
    if (nbR == nbC)
    {
      for (int j = 0; j < nbR; j++)
       {
        Dof r(getLocalDofR(se, j));
        Dof c(getLocalDofC(se, j));
        R.push_back(r);
        C.push_back(c);
        if (!(r==c)) sym=false;
      }
    }
    else
    {
      sym=false;
      for (int j = 0; j < nbR; j++)
        R.push_back(getLocalDofR(se, j));
      for (int k = 0; k < nbC; k++)
        C.push_back(getLocalDofC(se, k));
    }
    if (!sym)
      dm.assemble(R, C, localMatrix);
    else
      dm.assemble(R, localMatrix);
  }

  void dirichletNodalBC(int physical, int dim, int comp, int field,
                        const simpleFunction<dataVec> &e,
                        dofManager<dataVec> &dm)
  {
    std::vector<MVertex *> v;
    GModel *m = _gm;
    m->getMeshVerticesForPhysicalGroup(dim, physical, v);
    for (unsigned int i = 0; i < v.size(); i++)
      dm.fixVertex(v[i], comp, field, e(v[i]->x(), v[i]->y(), v[i]->z()));
  }

  void neumannNodalBC(int physical, int dim, int comp, int field,
                      const simpleFunction<dataVec> &fct,
                      dofManager<dataVec> &dm)
  {
    std::map<int, std::vector<GEntity*> > groups[4];
    GModel *m = _gm;
    m->getPhysicalGroups(groups);
    std::map<int, std::vector<GEntity*> >::iterator it = groups[dim].find(physical);
    if (it == groups[dim].end()) return;
    double jac[3][3];
    double sf[256];
    for (unsigned int i = 0; i < it->second.size(); ++i){
      GEntity *ge = it->second[i];
      for (unsigned int j = 0; j < ge->getNumMeshElements(); j++){
        MElement *e = ge->getMeshElement(j);
        int integrationOrder = 2 * e->getPolynomialOrder();
        int nbNodes = e->getNumVertices();
        int npts;
        IntPt *GP;
        e->getIntegrationPoints(integrationOrder, &npts, &GP);
        for (int ip = 0; ip < npts; ip++){
          const double u = GP[ip].pt[0];
          const double v = GP[ip].pt[1];
          const double w = GP[ip].pt[2];
          const double weight = GP[ip].weight;
          const double detJ = e->getJacobian(u, v, w, jac);
          SPoint3 p; e->pnt(u, v, w, p);
          e->getShapeFunctions(u, v, w, sf);
          const dataVec FCT = fct(p.x(), p.y(), p.z());
          for (int k = 0; k < nbNodes; k++){
            dm.assemble(e->getVertex(k), comp, field, detJ * weight * sf[k] * FCT);
          }
        }
      }
    }
  }

  void addToRightHandSide(dofManager<dataVec> &dm, groupOfElements &C) const
  {
    groupOfElements::elementContainer::const_iterator it = C.begin();
    for ( ; it != C.end(); ++it){
      MElement *eL = *it;
      SElement se(eL);
      int nbR = sizeOfR(&se);
      fullVector<dataVec> V(nbR);
      elementVector(&se, V);
      // assembly
      for (int j = 0; j < nbR; j++) dm.assemble(getLocalDofR(&se, j), V(j));
    }
  }
};



class DummyfemTerm : public femTerm<double>
{
 public:
  typedef dofTraits<double>::VecType dataVec;
  typedef dofTraits<double>::MatType dataMat;
  DummyfemTerm(GModel *gm) : femTerm<double>(gm) {}
  virtual ~DummyfemTerm() {}
 private : // i dont want to mess with this anymore
  virtual int sizeOfC(SElement *se) const {return 0;}
  virtual int sizeOfR(SElement *se) const {return 0;}
  virtual Dof getLocalDofR(SElement *se, int iRow) const {return Dof(0,0);}
  virtual Dof getLocalDofC(SElement *se, int iCol) const {return Dof(0,0);}
  virtual void elementMatrix(SElement *se, fullMatrix<dataMat> &m) const {m.scale(0.);}
  virtual void elementVector(SElement *se, fullVector<dataVec> &m) const {m.scale(0.);}
};





#endif

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