Intrepid_HGRAD_QUAD_Cn_FEMDef.hpp

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#ifndef INTREPID_HGRAD_QUAD_CN_FEMDEF_HPP
#define INTREPID_HGRAD_QUAD_CN_FEMDEF_HPP
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using Teuchos::Array;
using Teuchos::RCP;
 
namespace Intrepid {
  template<class Scalar, class ArrayScalar>
  Basis_HGRAD_QUAD_Cn_FEM<Scalar,ArrayScalar>::Basis_HGRAD_QUAD_Cn_FEM( const int orderx , const int ordery,
                                                                        const ArrayScalar &pts_x ,
                                                                        const ArrayScalar &pts_y ): 
    ptsx_( pts_x.dimension(0) , 1 ) ,
    ptsy_( pts_y.dimension(0) , 1 )
  {
    Array<Array<RCP<Basis<Scalar,ArrayScalar> > > > bases(1);
    bases[0].resize(2);
    bases[0][0] = Teuchos::rcp( new Basis_HGRAD_LINE_Cn_FEM<Scalar,ArrayScalar>( orderx , pts_x ) );
    bases[0][1] = Teuchos::rcp( new Basis_HGRAD_LINE_Cn_FEM<Scalar,ArrayScalar>( ordery , pts_y ) );
    this->setBases( bases );
 
    this->basisCardinality_ = (orderx+1)*(ordery+1);
    if (orderx > ordery) {
      this->basisDegree_ = orderx;
    }
    else {
      this->basisDegree_ = ordery;
    }
    this -> basisCellTopology_ = shards::CellTopology(shards::getCellTopologyData<shards::Quadrilateral<4> >() );
    this -> basisType_         = BASIS_FEM_FIAT;
    this -> basisCoordinates_  = COORDINATES_CARTESIAN;
    this -> basisTagsAreSet_   = false;
 
    for (int i=0;i<pts_x.dimension(0);i++)
      {
        ptsx_(i,0) = pts_x(i,0);
      }
 
    for (int i=0;i<pts_y.dimension(0);i++)
      {
        ptsy_(i,0) = pts_y(i,0);
      }
 
  }
 
  template<class Scalar, class ArrayScalar>
  Basis_HGRAD_QUAD_Cn_FEM<Scalar,ArrayScalar>::Basis_HGRAD_QUAD_Cn_FEM( const int order,
                                                                        const EPointType &pointType ):
    ptsx_( order+1 , 1 ) ,
    ptsy_( order+1 , 1 )
  {
    Array<Array<RCP<Basis<Scalar,ArrayScalar> > > > bases(1);
    bases[0].resize(2);
    bases[0][0] = Teuchos::rcp( new Basis_HGRAD_LINE_Cn_FEM<Scalar,ArrayScalar>( order , pointType ) );
    bases[0][1] = Teuchos::rcp( new Basis_HGRAD_LINE_Cn_FEM<Scalar,ArrayScalar>( order , pointType ) );
    this->setBases( bases );
 
    this->basisCardinality_ = (order+1)*(order+1);
    this->basisDegree_ = order;
    this -> basisCellTopology_ = shards::CellTopology(shards::getCellTopologyData<shards::Quadrilateral<4> >() );
    this -> basisType_         = BASIS_FEM_FIAT;
    this -> basisCoordinates_  = COORDINATES_CARTESIAN;
    this -> basisTagsAreSet_   = false;
 
    // fill up the pt arrays with calls to the lattice
    EPointType pt = (pointType==POINTTYPE_EQUISPACED)?pointType:POINTTYPE_WARPBLEND;
    PointTools::getLattice<Scalar,FieldContainer<Scalar> >( ptsx_ ,
                                                            shards::CellTopology(shards::getCellTopologyData<shards::Line<2> >()) ,
                                                            order ,
                                                            0 ,
                                                            pt );
          
    for (int i=0;i<order+1;i++)
      {
        ptsy_(i,0) = ptsx_(i,0);
      }
  }
 
  template<class Scalar, class ArrayScalar>
  void Basis_HGRAD_QUAD_Cn_FEM<Scalar,ArrayScalar>::initializeTags()
  {
    // Basis-dependent initializations
    int tagSize  = 4;        // size of DoF tag, i.e., number of fields in the tag
    int posScDim = 0;        // position in the tag, counting from 0, of the subcell dim 
    int posScOrd = 1;        // position in the tag, counting from 0, of the subcell ordinal
    int posDfOrd = 2;        // position in the tag, counting from 0, of DoF ordinal relative to the subcell
  
    // An array with local DoF tags assigned to the basis functions, in the order of their local enumeration 
 
    std::vector<int> tags( tagSize * this->getCardinality() );
 
    // temporarily just put everything on the cell itself
    for (int i=0;i<this->getCardinality();i++) {
       tags[tagSize*i] = 2;
       tags[tagSize*i+1] = 0;
       tags[tagSize*i+2] = i;
       tags[tagSize*i+3] = this->getCardinality();
     }
 
    Basis<Scalar,ArrayScalar> &xBasis_ = *this->getBases()[0][0];
    Basis<Scalar,ArrayScalar> &yBasis_ = *this->getBases()[0][1];
 
    // now let's try to do it "right"
    // let's get the x and y bases and their dof
    const std::vector<std::vector<int> >& xdoftags = xBasis_.getAllDofTags();
    const std::vector<std::vector<int> >& ydoftags = yBasis_.getAllDofTags();
 
    std::map<int,std::map<int,int> > total_dof_per_entity;
    std::map<int,std::map<int,int> > current_dof_per_entity;
 
    for (int i=0;i<4;i++) {
      total_dof_per_entity[0][i] = 0;
      current_dof_per_entity[0][i] = 0;
    }
    for (int i=0;i<4;i++) {
      total_dof_per_entity[1][i] = 0;
      current_dof_per_entity[1][i] = 0;
    }
    total_dof_per_entity[2][0] = 0;
    current_dof_per_entity[2][0] = 0;
    
    // let's tally the total degrees of freedom on each entity
    for (int j=0;j<yBasis_.getCardinality();j++) {
      const int ydim = ydoftags[j][0];
      const int yent = ydoftags[j][1];
      for (int i=0;i<xBasis_.getCardinality();i++) {
        const int xdim = xdoftags[i][0];
        const int xent = xdoftags[i][1];
        int dofdim;
        int dofent;
        ProductTopology::lineProduct2d( xdim , xent , ydim , yent , dofdim , dofent );
        total_dof_per_entity[dofdim][dofent] += 1;
      }
    }
 
    int tagcur = 0;
    for (int j=0;j<yBasis_.getCardinality();j++) {
      const int ydim = ydoftags[j][0];
      const int yent = ydoftags[j][1];
      for (int i=0;i<xBasis_.getCardinality();i++) {
        const int xdim = xdoftags[i][0];
        const int xent = xdoftags[i][1];
        int dofdim;
        int dofent;
        ProductTopology::lineProduct2d( xdim , xent , ydim , yent , dofdim , dofent );
        tags[4*tagcur] = dofdim;
        tags[4*tagcur+1] = dofent;
        tags[4*tagcur+2] = current_dof_per_entity[dofdim][dofent];
        current_dof_per_entity[dofdim][dofent]++;
        tags[4*tagcur+3] = total_dof_per_entity[dofdim][dofent];
        tagcur++;
      }
    }
 
    setOrdinalTagData(this -> tagToOrdinal_,
                      this -> ordinalToTag_,
                      &(tags[0]),
                      this -> basisCardinality_,
                      tagSize,
                      posScDim,
                      posScOrd,
                      posDfOrd);
 
  }
 
  template<class Scalar, class ArrayScalar>
  void Basis_HGRAD_QUAD_Cn_FEM<Scalar,ArrayScalar>::getValues( ArrayScalar &outputValues ,
                                                               const ArrayScalar &inputPoints ,
                                                               const EOperator operatorType ) const 
  {
#ifdef HAVE_INTREPID_DEBUG
    getValues_HGRAD_Args<Scalar, ArrayScalar>(outputValues,
                                              inputPoints,
                                              operatorType,
                                              this -> getBaseCellTopology(),
                                              this -> getCardinality() );
#endif
 
    FieldContainer<Scalar> xInputPoints(inputPoints.dimension(0),1);
    FieldContainer<Scalar> yInputPoints(inputPoints.dimension(0),1);
 
    const Basis<Scalar,ArrayScalar> &xBasis_ = *this->bases_[0][0];
    const Basis<Scalar,ArrayScalar> &yBasis_ = *this->bases_[0][1];
 
    for (int i=0;i<inputPoints.dimension(0);i++) {
      xInputPoints(i,0) = inputPoints(i,0);
      yInputPoints(i,0) = inputPoints(i,1);
    }
 
    switch (operatorType) {
    case OPERATOR_VALUE:
      {
        FieldContainer<Scalar> xBasisValues(xBasis_.getCardinality(),xInputPoints.dimension(0));
        FieldContainer<Scalar> yBasisValues(yBasis_.getCardinality(),yInputPoints.dimension(0));
 
        xBasis_.getValues(xBasisValues,xInputPoints,OPERATOR_VALUE);
        yBasis_.getValues(yBasisValues,yInputPoints,OPERATOR_VALUE);
 
        int bfcur = 0;
        for (int j=0;j<yBasis_.getCardinality();j++) {
          for (int i=0;i<xBasis_.getCardinality();i++) {
            for (int k=0;k<inputPoints.dimension(0);k++) {
              outputValues(bfcur,k) = xBasisValues(i,k) * yBasisValues(j,k);
            }
            bfcur++;
          }
        }
      }
      break;
    case OPERATOR_GRAD:
    case OPERATOR_D1:
      {
        FieldContainer<Scalar> xBasisValues(xBasis_.getCardinality(),xInputPoints.dimension(0));
        FieldContainer<Scalar> yBasisValues(yBasis_.getCardinality(),yInputPoints.dimension(0));
        FieldContainer<Scalar> xBasisDerivs(xBasis_.getCardinality(),xInputPoints.dimension(0),1);
        FieldContainer<Scalar> yBasisDerivs(yBasis_.getCardinality(),yInputPoints.dimension(0),1);
 
        xBasis_.getValues(xBasisValues,xInputPoints,OPERATOR_VALUE);
        yBasis_.getValues(yBasisValues,yInputPoints,OPERATOR_VALUE);
        xBasis_.getValues(xBasisDerivs,xInputPoints,OPERATOR_D1);
        yBasis_.getValues(yBasisDerivs,yInputPoints,OPERATOR_D1);       
 
        // there are two multiindices: I need the (1,0) and (0,1) derivatives
        int bfcur = 0;
 
        for (int j=0;j<yBasis_.getCardinality();j++) {
          for (int i=0;i<xBasis_.getCardinality();i++) {
            for (int k=0;k<inputPoints.dimension(0);k++) {
              outputValues(bfcur,k,0) = xBasisDerivs(i,k,0) * yBasisValues(j,k);
              outputValues(bfcur,k,1) = xBasisValues(i,k) * yBasisDerivs(j,k,0);
            }
            bfcur++;
          }
        }
      }
      break;
    case OPERATOR_D2:
    case OPERATOR_D3:
    case OPERATOR_D4:
    case OPERATOR_D5: 
    case OPERATOR_D6:
    case OPERATOR_D7:
    case OPERATOR_D8:
    case OPERATOR_D9:
    case OPERATOR_D10:
      {
        FieldContainer<Scalar> xBasisValues(xBasis_.getCardinality(),xInputPoints.dimension(0));
        FieldContainer<Scalar> yBasisValues(yBasis_.getCardinality(),yInputPoints.dimension(0));
 
        Teuchos::Array<int> partialMult;
 
        for (int d=0;d<getDkCardinality(operatorType,2);d++) {
          getDkMultiplicities( partialMult , d , operatorType , 2 );
          if (partialMult[0] == 0) {
            xBasisValues.resize(xBasis_.getCardinality(),xInputPoints.dimension(0));
            xBasis_.getValues( xBasisValues , xInputPoints, OPERATOR_VALUE );
          }
          else {
            xBasisValues.resize(xBasis_.getCardinality(),xInputPoints.dimension(0),1);
            EOperator xop = (EOperator) ( (int) OPERATOR_D1 + partialMult[0] - 1 );
            xBasis_.getValues( xBasisValues , xInputPoints, xop );
            xBasisValues.resize(xBasis_.getCardinality(),xInputPoints.dimension(0));
          }
          if (partialMult[1] == 0) {
            yBasisValues.resize(yBasis_.getCardinality(),yInputPoints.dimension(0));
            yBasis_.getValues( yBasisValues , yInputPoints, OPERATOR_VALUE );
          }
          else {
            yBasisValues.resize(yBasis_.getCardinality(),yInputPoints.dimension(0),1);
            EOperator yop = (EOperator) ( (int) OPERATOR_D1 + partialMult[1] - 1 );
            yBasis_.getValues( yBasisValues , yInputPoints, yop );
            yBasisValues.resize(yBasis_.getCardinality(),yInputPoints.dimension(0));
          }
 
 
          int bfcur = 0;
          for (int j=0;j<yBasis_.getCardinality();j++) {
            for (int i=0;i<xBasis_.getCardinality();i++) {
              for (int k=0;k<inputPoints.dimension(0);k++) {
                outputValues(bfcur,k,d) = xBasisValues(i,k) * yBasisValues(j,k);
              }
              bfcur++;
            }
          }
        }
      }
      break;
    case OPERATOR_CURL:
      {
        FieldContainer<Scalar> xBasisValues(xBasis_.getCardinality(),xInputPoints.dimension(0));
        FieldContainer<Scalar> yBasisValues(yBasis_.getCardinality(),yInputPoints.dimension(0));
        FieldContainer<Scalar> xBasisDerivs(xBasis_.getCardinality(),xInputPoints.dimension(0),1);
        FieldContainer<Scalar> yBasisDerivs(yBasis_.getCardinality(),yInputPoints.dimension(0),1);
 
        xBasis_.getValues(xBasisValues,xInputPoints,OPERATOR_VALUE);
        yBasis_.getValues(yBasisValues,yInputPoints,OPERATOR_VALUE);
        xBasis_.getValues(xBasisDerivs,xInputPoints,OPERATOR_D1);
        yBasis_.getValues(yBasisDerivs,yInputPoints,OPERATOR_D1);       
 
        // there are two multiindices: I need the (1,0) and (0,1) derivatives
        int bfcur = 0;
 
        for (int j=0;j<yBasis_.getCardinality();j++) {
          for (int i=0;i<xBasis_.getCardinality();i++) {
            for (int k=0;k<inputPoints.dimension(0);k++) {
              outputValues(bfcur,k,0) = xBasisValues(i,k) * yBasisDerivs(j,k,0);
              outputValues(bfcur,k,1) = -xBasisDerivs(i,k,0) * yBasisValues(j,k);
            }
            bfcur++;
          }
        }
      }
      break;      
    default:
        TEUCHOS_TEST_FOR_EXCEPTION( true , std::invalid_argument,
                            ">>> ERROR (Basis_HGRAD_QUAD_Cn_FEM): Operator type not implemented");
        break;
    }
  }
 
  template<class Scalar,class ArrayScalar>
  void Basis_HGRAD_QUAD_Cn_FEM<Scalar, ArrayScalar>::getValues(ArrayScalar&           outputValues,
                                                               const ArrayScalar &    inputPoints,
                                                               const ArrayScalar &    cellVertices,
                                                               const EOperator        operatorType) const {
    TEUCHOS_TEST_FOR_EXCEPTION( (true), std::logic_error,
                        ">>> ERROR (Basis_HGRAD_QUAD_Cn_FEM): FEM Basis calling an FVD member function");
  }
 
  template<class Scalar,class ArrayScalar>
  void Basis_HGRAD_QUAD_Cn_FEM<Scalar, ArrayScalar>::getDofCoords( ArrayScalar & dofCoords ) const
  {
    int cur = 0;
    for (int j=0;j<ptsy_.dimension(0);j++)
      {
        for (int i=0;i<ptsx_.dimension(0);i++)
          {
            dofCoords(cur,0) = ptsx_(i,0);
            dofCoords(cur,1) = ptsy_(j,0);
            cur++;
          }
      }
  }
 
  
}// namespace Intrepid
 
#endif
 
#if defined(Intrepid_SHOW_DEPRECATED_WARNINGS)
#ifdef __GNUC__
#warning "The Intrepid package is deprecated"
#endif
#endif