Intrepid2_HGRAD_LINE_Cn_FEMDef.hpp

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#ifndef __INTREPID2_HGRAD_LINE_CN_FEM_DEF_HPP__
#define __INTREPID2_HGRAD_LINE_CN_FEM_DEF_HPP__
 
namespace Intrepid2 {
 
  // -------------------------------------------------------------------------------------
  namespace Impl {
    
    template<EOperator opType>
    template<typename OutputViewType,
             typename inputViewType,
             typename workViewType,
             typename vinvViewType>
    KOKKOS_INLINE_FUNCTION
    void
    Basis_HGRAD_LINE_Cn_FEM::Serial<opType>::
    getValues(       OutputViewType output,
               const inputViewType  input,
                     workViewType   work,
               const vinvViewType   vinv,
               const ordinal_type   operatorDn ) {    
      ordinal_type opDn = operatorDn;
 
      const ordinal_type card = vinv.extent(0);
      const ordinal_type npts = input.extent(0);
 
      const ordinal_type order = card - 1;
      const double alpha = 0.0, beta = 0.0;
 
      typedef typename Kokkos::DynRankView<typename workViewType::value_type, typename workViewType::memory_space> viewType;
      auto vcprop = Kokkos::common_view_alloc_prop(work);
      
      switch (opType) {
      case OPERATOR_VALUE: {
        viewType phis(Kokkos::view_wrap(work.data(), vcprop), card, npts);     
 
        Impl::Basis_HGRAD_LINE_Cn_FEM_JACOBI::
          Serial<opType>::getValues(phis, input, order, alpha, beta);
 
        for (ordinal_type i=0;i<card;++i) 
          for (ordinal_type j=0;j<npts;++j) {
            output.access(i,j) = 0.0;
            for (ordinal_type k=0;k<card;++k)
              output.access(i,j) += vinv(k,i)*phis.access(k,j);
          }
        break;
      }
      case OPERATOR_GRAD:
      case OPERATOR_D1:
      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: 
        opDn = getOperatorOrder(opType);
      case OPERATOR_Dn: {
        // dkcard is always 1 for 1D element
        const ordinal_type dkcard = 1;
        viewType phis(Kokkos::view_wrap(work.data(), vcprop), card, npts, dkcard);     
        Impl::Basis_HGRAD_LINE_Cn_FEM_JACOBI::
          Serial<opType>::getValues(phis, input, order, alpha, beta, opDn);
 
        for (ordinal_type i=0;i<card;++i) 
          for (ordinal_type j=0;j<npts;++j) 
            for (ordinal_type k=0;k<dkcard;++k) {
              output.access(i,j,k) = 0.0;
              for (ordinal_type l=0;l<card;++l)
                output.access(i,j,k) += vinv(l,i)*phis.access(l,j,k);
            }
        break;
      }
      default: {
        INTREPID2_TEST_FOR_ABORT( true,
                                  ">>> ERROR: (Intrepid2::Basis_HGRAD_LINE_Cn_FEM::Serial::getValues) operator is not supported." );
      }
      }
    }
    
 
    template<typename DT, ordinal_type numPtsPerEval,
             typename outputValueValueType, class ...outputValueProperties,
             typename inputPointValueType,  class ...inputPointProperties,
             typename vinvValueType,        class ...vinvProperties>
    void
    Basis_HGRAD_LINE_Cn_FEM::
    getValues(       Kokkos::DynRankView<outputValueValueType,outputValueProperties...> outputValues,
               const Kokkos::DynRankView<inputPointValueType, inputPointProperties...>  inputPoints,
               const Kokkos::DynRankView<vinvValueType,       vinvProperties...>        vinv,
               const EOperator operatorType ) {
      typedef          Kokkos::DynRankView<outputValueValueType,outputValueProperties...>         outputValueViewType;
      typedef          Kokkos::DynRankView<inputPointValueType, inputPointProperties...>          inputPointViewType;
      typedef          Kokkos::DynRankView<vinvValueType,       vinvProperties...>                vinvViewType;
      typedef typename ExecSpace<typename inputPointViewType::execution_space,typename DT::execution_space>::ExecSpaceType ExecSpaceType;
 
      // loopSize corresponds to cardinality
      const auto loopSizeTmp1 = (inputPoints.extent(0)/numPtsPerEval);
      const auto loopSizeTmp2 = (inputPoints.extent(0)%numPtsPerEval != 0);
      const auto loopSize = loopSizeTmp1 + loopSizeTmp2;
      Kokkos::RangePolicy<ExecSpaceType,Kokkos::Schedule<Kokkos::Static> > policy(0, loopSize);
 
      typedef typename inputPointViewType::value_type inputPointType;
 
      const ordinal_type cardinality = outputValues.extent(0);
 
      auto vcprop = Kokkos::common_view_alloc_prop(inputPoints);
      typedef typename Kokkos::DynRankView< inputPointType, typename inputPointViewType::memory_space> workViewType;
      workViewType  work(Kokkos::view_alloc("Basis_HGRAD_LINE_Cn_FEM::getValues::work", vcprop), cardinality, inputPoints.extent(0));
 
      switch (operatorType) {
      case OPERATOR_VALUE: {
        typedef Functor<outputValueViewType,inputPointViewType,vinvViewType,workViewType,
            OPERATOR_VALUE,numPtsPerEval> FunctorType;
        Kokkos::parallel_for( policy, FunctorType(outputValues, inputPoints, vinv, work) );
        break;
      }
      case OPERATOR_GRAD:
      case OPERATOR_D1:
      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: {
        typedef Functor<outputValueViewType,inputPointViewType,vinvViewType,workViewType,
            OPERATOR_Dn,numPtsPerEval> FunctorType;
        Kokkos::parallel_for( policy, FunctorType(outputValues, inputPoints, vinv, work,
                                                  getOperatorOrder(operatorType)) );
        break;
      }
      default: {
        INTREPID2_TEST_FOR_EXCEPTION( true , std::invalid_argument,
                                      ">>> ERROR (Basis_HGRAD_LINE_Cn_FEM): Operator type not implemented" );
        //break; commented out because this always throws
      }
      }
    }
  }
 
  // -------------------------------------------------------------------------------------
  template<typename DT, typename OT, typename PT>
  Basis_HGRAD_LINE_Cn_FEM<DT,OT,PT>::
  Basis_HGRAD_LINE_Cn_FEM( const ordinal_type order,
                           const EPointType   pointType ) {
    this->pointType_         = pointType;
    this->basisCardinality_  = order+1;
    this->basisDegree_       = order;
    this->basisCellTopology_ = shards::CellTopology(shards::getCellTopologyData<shards::Line<2> >() );
    this->basisType_         = BASIS_FEM_LAGRANGIAN;
    this->basisCoordinates_  = COORDINATES_CARTESIAN;
    this->functionSpace_     = FUNCTION_SPACE_HGRAD;
 
    const ordinal_type card = this->basisCardinality_;
    
    // points are computed in the host and will be copied 
    Kokkos::DynRankView<typename ScalarViewType::value_type,typename DT::execution_space::array_layout,Kokkos::HostSpace>
      dofCoords("Hgrad::Line::Cn::dofCoords", card, 1);
 
    //Default is Equispaced
    auto pointT = (pointType == POINTTYPE_DEFAULT) ? POINTTYPE_EQUISPACED : pointType;
 
    switch (pointT) {
    case POINTTYPE_EQUISPACED:
    case POINTTYPE_WARPBLEND: {
      // lattice ordering 
      {
        const ordinal_type offset = 0;
        PointTools::getLattice( dofCoords,
                                this->basisCellTopology_, 
                                order, offset, 
                                pointT );
        
      }
      // topological order
      // { 
      //   // two vertices
      //   dofCoords(0,0) = -1.0;
      //   dofCoords(1,0) =  1.0;
        
      //   // internal points
      //   typedef Kokkos::pair<ordinal_type,ordinal_type> range_type;
      //   auto pts = Kokkos::subview(dofCoords, range_type(2, card), Kokkos::ALL());
        
      //   const auto offset = 1;
      //   PointTools::getLattice( pts,
      //                           this->basisCellTopology_, 
      //                           order, offset, 
      //                           pointType );
      // }
      break;
    }
    case POINTTYPE_GAUSS: {
      // internal points only
      PointTools::getGaussPoints( dofCoords, 
                                  order );
      break;
    }
    default: {
      INTREPID2_TEST_FOR_EXCEPTION( !isValidPointType(pointT),
                                    std::invalid_argument , 
                                    ">>> ERROR: (Intrepid2::Basis_HGRAD_LINE_Cn_FEM) invalid pointType." );
    }
    }
 
    this->dofCoords_ = Kokkos::create_mirror_view(typename DT::memory_space(), dofCoords);
    Kokkos::deep_copy(this->dofCoords_, dofCoords);
    
    // form Vandermonde matrix; actually, this is the transpose of the VDM,
    // this matrix is used in LAPACK so it should be column major and left layout
    const ordinal_type lwork = card*card;
    Kokkos::DynRankView<typename ScalarViewType::value_type,Kokkos::LayoutLeft,Kokkos::HostSpace>
      vmat("Hgrad::Line::Cn::vmat", card, card), 
      work("Hgrad::Line::Cn::work", lwork),
      ipiv("Hgrad::Line::Cn::ipiv", card);
 
    const double alpha = 0.0, beta = 0.0;
    Impl::Basis_HGRAD_LINE_Cn_FEM_JACOBI::
      getValues<Kokkos::HostSpace::execution_space,Parameters::MaxNumPtsPerBasisEval>
      (vmat, dofCoords, order, alpha, beta, OPERATOR_VALUE);
 
    ordinal_type info = 0;
    Teuchos::LAPACK<ordinal_type,typename ScalarViewType::value_type> lapack;
 
    lapack.GETRF(card, card, 
                 vmat.data(), vmat.stride_1(),
                 (ordinal_type*)ipiv.data(),
                 &info);
 
    INTREPID2_TEST_FOR_EXCEPTION( info != 0,
                                  std::runtime_error , 
                                  ">>> ERROR: (Intrepid2::Basis_HGRAD_LINE_Cn_FEM) lapack.GETRF returns nonzero info." );
 
    lapack.GETRI(card, 
                 vmat.data(), vmat.stride_1(),
                 (ordinal_type*)ipiv.data(),
                 work.data(), lwork,
                 &info);
 
    INTREPID2_TEST_FOR_EXCEPTION( info != 0,
                                  std::runtime_error , 
                                  ">>> ERROR: (Intrepid2::Basis_HGRAD_LINE_Cn_FEM) lapack.GETRI returns nonzero info." );
    
    // create host mirror 
    Kokkos::DynRankView<typename ScalarViewType::value_type,typename DT::execution_space::array_layout,Kokkos::HostSpace>
      vinv("Hgrad::Line::Cn::vinv", card, card);
 
    for (ordinal_type i=0;i<card;++i) 
      for (ordinal_type j=0;j<card;++j) 
        vinv(i,j) = vmat(j,i);
 
    this->vinv_ = Kokkos::create_mirror_view(typename DT::memory_space(), vinv);
    Kokkos::deep_copy(this->vinv_ , vinv);
 
    // initialize tags
    {
      const bool is_vertex_included = (pointType != POINTTYPE_GAUSS);
 
      // Basis-dependent initializations
      const ordinal_type tagSize  = 4;        // size of DoF tag, i.e., number of fields in the tag
      const ordinal_type posScDim = 0;        // position in the tag, counting from 0, of the subcell dim 
      const ordinal_type posScOrd = 1;        // position in the tag, counting from 0, of the subcell ordinal
      const ordinal_type posDfOrd = 2;        // position in the tag, counting from 0, of DoF ordinal relative to the subcell
      
 
      ordinal_type tags[Parameters::MaxOrder+1][4];
 
      // now we check the points for association 
      if (is_vertex_included) {
        // lattice order
        {
          const auto v0 = 0;
          tags[v0][0] = 0; // vertex dof
          tags[v0][1] = 0; // vertex id
          tags[v0][2] = 0; // local dof id
          tags[v0][3] = 1; // total number of dofs in this vertex
          
          const ordinal_type iend = card - 2;
          for (ordinal_type i=0;i<iend;++i) {
            const auto e = i + 1;
            tags[e][0] = 1;    // edge dof
            tags[e][1] = 0;    // edge id
            tags[e][2] = i;    // local dof id
            tags[e][3] = iend; // total number of dofs in this edge
          }
 
          const auto v1 = card -1;
          tags[v1][0] = 0; // vertex dof
          tags[v1][1] = 1; // vertex id
          tags[v1][2] = 0; // local dof id
          tags[v1][3] = 1; // total number of dofs in this vertex
        }
 
        // topological order
        // {
        //   tags[0][0] = 0; // vertex dof
        //   tags[0][1] = 0; // vertex id
        //   tags[0][2] = 0; // local dof id
        //   tags[0][3] = 1; // total number of dofs in this vertex
          
        //   tags[1][0] = 0; // vertex dof
        //   tags[1][1] = 1; // vertex id
        //   tags[1][2] = 0; // local dof id
        //   tags[1][3] = 1; // total number of dofs in this vertex
          
        //   const ordinal_type iend = card - 2;
        //   for (ordinal_type i=0;i<iend;++i) {
        //     const auto ii = i + 2;
        //     tags[ii][0] = 1;    // edge dof
        //     tags[ii][1] = 0;    // edge id
        //     tags[ii][2] = i;    // local dof id
        //     tags[ii][3] = iend; // total number of dofs in this edge
        //   }
        // }
      } else {
        for (ordinal_type i=0;i<card;++i) {
          tags[i][0] = 1;    // edge dof
          tags[i][1] = 0;    // edge id
          tags[i][2] = i;    // local dof id
          tags[i][3] = card; // total number of dofs in this edge
        }
      }
 
      OrdinalTypeArray1DHost tagView(&tags[0][0], card*4);
 
      // Basis-independent function sets tag and enum data in tagToOrdinal_ and ordinalToTag_ arrays:
      // tags are constructed on host
      this->setOrdinalTagData(this->tagToOrdinal_,
                              this->ordinalToTag_,
                              tagView,
                              this->basisCardinality_,
                              tagSize,
                              posScDim,
                              posScOrd,
                              posDfOrd);
    }  
  }
  
}// namespace Intrepid2
 
#endif