49 #ifndef __INTREPID2_HDIV_TET_IN_FEM_DEF_HPP__ 50 #define __INTREPID2_HDIV_TET_IN_FEM_DEF_HPP__ 61 template<EOperator opType>
62 template<
typename OutputViewType,
63 typename inputViewType,
64 typename workViewType,
65 typename vinvViewType>
66 KOKKOS_INLINE_FUNCTION
68 Basis_HDIV_TET_In_FEM::Serial<opType>::
69 getValues( OutputViewType output,
70 const inputViewType input,
72 const vinvViewType coeffs ) {
74 constexpr ordinal_type spaceDim = 3;
76 cardPn = coeffs.extent(0)/spaceDim,
77 card = coeffs.extent(1),
78 npts = input.extent(0);
81 ordinal_type order = 0;
83 if (card == CardinalityHDivTet(p)) {
89 typedef typename Kokkos::DynRankView<typename workViewType::value_type, typename workViewType::memory_space> viewType;
90 auto vcprop = Kokkos::common_view_alloc_prop(work);
91 auto ptr = work.data();
94 case OPERATOR_VALUE: {
95 const viewType phis(Kokkos::view_wrap(ptr, vcprop), card, npts);
96 workViewType dummyView;
98 Impl::Basis_HGRAD_TET_Cn_FEM_ORTH::
99 Serial<opType>::getValues(phis, input, dummyView, order);
101 for (ordinal_type i=0;i<card;++i)
102 for (ordinal_type j=0;j<npts;++j)
103 for (ordinal_type d=0;d<spaceDim;++d) {
104 output.access(i,j,d) = 0.0;
105 for (ordinal_type k=0;k<cardPn;++k)
106 output.access(i,j,d) += coeffs(k+d*cardPn,i) * phis.access(k,j);
111 const viewType phis(Kokkos::view_wrap(ptr, vcprop), card, npts, spaceDim);
112 ptr += card*npts*spaceDim*get_dimension_scalar(work);
113 const viewType workView(Kokkos::view_wrap(ptr, vcprop), card, npts, spaceDim+1);
115 Impl::Basis_HGRAD_TET_Cn_FEM_ORTH::
116 Serial<OPERATOR_GRAD>::getValues(phis, input, workView, order);
118 for (ordinal_type i=0;i<card;++i)
119 for (ordinal_type j=0;j<npts;++j) {
120 output.access(i,j) = 0.0;
121 for (ordinal_type k=0; k<cardPn; ++k)
122 for (ordinal_type d=0; d<spaceDim; ++d)
123 output.access(i,j) += coeffs(k+d*cardPn,i)*phis.access(k,j,d);
128 INTREPID2_TEST_FOR_ABORT(
true,
129 ">>> ERROR (Basis_HDIV_TET_In_FEM): Operator type not implemented");
134 template<
typename DT, ordinal_type numPtsPerEval,
135 typename outputValueValueType,
class ...outputValueProperties,
136 typename inputPointValueType,
class ...inputPointProperties,
137 typename vinvValueType,
class ...vinvProperties>
139 Basis_HDIV_TET_In_FEM::
140 getValues( Kokkos::DynRankView<outputValueValueType,outputValueProperties...> outputValues,
141 const Kokkos::DynRankView<inputPointValueType, inputPointProperties...> inputPoints,
142 const Kokkos::DynRankView<vinvValueType, vinvProperties...> coeffs,
143 const EOperator operatorType) {
144 typedef Kokkos::DynRankView<outputValueValueType,outputValueProperties...> outputValueViewType;
145 typedef Kokkos::DynRankView<inputPointValueType, inputPointProperties...> inputPointViewType;
146 typedef Kokkos::DynRankView<vinvValueType, vinvProperties...> vinvViewType;
147 typedef typename ExecSpace<typename inputPointViewType::execution_space,typename DT::execution_space>::ExecSpaceType ExecSpaceType;
150 const auto loopSizeTmp1 = (inputPoints.extent(0)/numPtsPerEval);
151 const auto loopSizeTmp2 = (inputPoints.extent(0)%numPtsPerEval != 0);
152 const auto loopSize = loopSizeTmp1 + loopSizeTmp2;
153 Kokkos::RangePolicy<ExecSpaceType,Kokkos::Schedule<Kokkos::Static> > policy(0, loopSize);
155 typedef typename inputPointViewType::value_type inputPointType;
157 const ordinal_type cardinality = outputValues.extent(0);
158 const ordinal_type spaceDim = 3;
160 auto vcprop = Kokkos::common_view_alloc_prop(inputPoints);
161 typedef typename Kokkos::DynRankView< inputPointType, typename inputPointViewType::memory_space> workViewType;
163 switch (operatorType) {
164 case OPERATOR_VALUE: {
165 workViewType work(Kokkos::view_alloc(
"Basis_HDIV_TET_In_FEM::getValues::work", vcprop), cardinality, inputPoints.extent(0));
166 typedef Functor<outputValueViewType,inputPointViewType,vinvViewType, workViewType,
167 OPERATOR_VALUE,numPtsPerEval> FunctorType;
168 Kokkos::parallel_for( policy, FunctorType(outputValues, inputPoints, coeffs, work) );
172 workViewType work(Kokkos::view_alloc(
"Basis_HDIV_TET_In_FEM::getValues::work", vcprop), cardinality*(2*spaceDim+1), inputPoints.extent(0));
173 typedef Functor<outputValueViewType,inputPointViewType,vinvViewType, workViewType,
174 OPERATOR_DIV,numPtsPerEval> FunctorType;
175 Kokkos::parallel_for( policy, FunctorType(outputValues, inputPoints, coeffs, work) );
179 INTREPID2_TEST_FOR_EXCEPTION(
true , std::invalid_argument,
180 ">>> ERROR (Basis_HDIV_TET_In_FEM): Operator type not implemented" );
187 template<
typename DT,
typename OT,
typename PT>
192 constexpr ordinal_type spaceDim = 3;
193 this->basisCardinality_ = CardinalityHDivTet(order);
194 this->basisDegree_ = order;
195 this->basisCellTopology_ = shards::CellTopology(shards::getCellTopologyData<shards::Tetrahedron<4> >() );
196 this->basisType_ = BASIS_FEM_LAGRANGIAN;
197 this->basisCoordinates_ = COORDINATES_CARTESIAN;
198 this->functionSpace_ = FUNCTION_SPACE_HDIV;
199 pointType_ = pointType;
201 const ordinal_type card = this->basisCardinality_;
203 const ordinal_type cardPn = Intrepid2::getPnCardinality<spaceDim>(order);
204 const ordinal_type cardPnm1 = Intrepid2::getPnCardinality<spaceDim>(order-1);
205 const ordinal_type cardPnm2 = Intrepid2::getPnCardinality<spaceDim>(order-2);
206 const ordinal_type cardVecPn = spaceDim*cardPn;
207 const ordinal_type cardVecPnm1 = spaceDim*cardPnm1;
208 const ordinal_type dim_PkH = cardPnm1 - cardPnm2;
212 constexpr ordinal_type tagSize = 4;
214 ordinal_type tags[maxCard][tagSize];
217 Kokkos::DynRankView<scalarType,typename DT::execution_space::array_layout,Kokkos::HostSpace>
218 dofCoords(
"Hdiv::Tet::In::dofCoords", card, spaceDim);
220 Kokkos::DynRankView<scalarType,typename DT::execution_space::array_layout,Kokkos::HostSpace>
221 dofCoeffs(
"Hdiv::Tet::In::dofCoeffs", card, spaceDim);
223 Kokkos::DynRankView<scalarType,typename DT::execution_space::array_layout,Kokkos::HostSpace>
224 coeffs(
"Hdiv::Tet::In::coeffs", cardVecPn, card);
230 const ordinal_type lwork = card*card;
231 Kokkos::DynRankView<scalarType,typename DT::execution_space::array_layout,Kokkos::HostSpace>
232 V1(
"Hdiv::Tet::In::V1", cardVecPn, card);
243 for (ordinal_type i=0;i<cardPnm1;i++) {
244 for (ordinal_type k=0; k<3;k++) {
245 V1(k*cardPn+i,k*cardPnm1+i) = 1.0;
252 Kokkos::DynRankView<scalarType,typename DT::execution_space::array_layout,Kokkos::HostSpace> cubPoints(
"Hdiv::Tet::In::cubPoints", myCub.
getNumPoints() , spaceDim );
253 Kokkos::DynRankView<scalarType,typename DT::execution_space::array_layout,Kokkos::HostSpace> cubWeights(
"Hdiv::Tet::In::cubWeights", myCub.
getNumPoints() );
257 Kokkos::DynRankView<scalarType,typename DT::execution_space::array_layout,Kokkos::HostSpace> phisAtCubPoints(
"Hdiv::Tet::In::phisAtCubPoints", cardPn , myCub.
getNumPoints() );
258 Impl::Basis_HGRAD_TET_Cn_FEM_ORTH::getValues<Kokkos::HostSpace::execution_space,Parameters::MaxNumPtsPerBasisEval>(phisAtCubPoints, cubPoints, order, OPERATOR_VALUE);
261 for (ordinal_type i=0;i<dim_PkH;i++) {
262 for (ordinal_type j=0;j<cardPn;j++) {
263 V1(j,cardVecPnm1+i) = 0.0;
264 for (ordinal_type d=0; d< spaceDim; ++d)
266 V1(j+d*cardPn,cardVecPnm1+i) +=
267 cubWeights(k) * cubPoints(k,d)
268 * phisAtCubPoints(cardPnm2+i,k)
269 * phisAtCubPoints(j,k);
275 Kokkos::DynRankView<scalarType,typename DT::execution_space::array_layout,Kokkos::HostSpace>
276 V2(
"Hdiv::Tet::In::V2", card ,cardVecPn);
278 const ordinal_type numFaces = this->basisCellTopology_.getFaceCount();
280 shards::CellTopology faceTop(shards::getCellTopologyData<shards::Triangle<3> >() );
287 Kokkos::DynRankView<scalarType,typename DT::execution_space::array_layout,Kokkos::HostSpace> triPts(
"Hdiv::Tet::In::triPts", numPtsPerFace , 2 );
290 const ordinal_type offset = 1;
298 Kokkos::DynRankView<scalarType,typename DT::execution_space::array_layout,Kokkos::HostSpace> facePts(
"Hdiv::Tet::In::facePts", numPtsPerFace , spaceDim );
299 Kokkos::DynRankView<scalarType,typename DT::execution_space::array_layout,Kokkos::HostSpace> phisAtFacePoints(
"Hdiv::Tet::In::phisAtFacePoints", cardPn , numPtsPerFace );
300 Kokkos::DynRankView<scalarType,typename DT::execution_space::array_layout,Kokkos::HostSpace> faceNormal(
"Hcurl::Tet::In::faceNormal", spaceDim );
303 for (ordinal_type face=0;face<numFaces;face++) {
308 this->basisCellTopology_ );
314 this->basisCellTopology_ );
317 Impl::Basis_HGRAD_TET_Cn_FEM_ORTH::getValues<Kokkos::HostSpace::execution_space,Parameters::MaxNumPtsPerBasisEval>(phisAtFacePoints, facePts, order, OPERATOR_VALUE);
320 for (ordinal_type j=0;j<numPtsPerFace;j++) {
322 const ordinal_type i_card = numPtsPerFace*face+j;
325 for (ordinal_type k=0;k<cardPn;k++) {
327 for (ordinal_type l=0; l<spaceDim; l++)
328 V2(i_card,k+l*cardPn) = faceNormal(l) * phisAtFacePoints(k,j);
332 for(ordinal_type l=0; l<spaceDim; ++l) {
333 dofCoords(i_card,l) = facePts(j,l);
334 dofCoeffs(i_card,l) = faceNormal(l);
338 tags[i_card][1] = face;
340 tags[i_card][3] = numPtsPerFace;
353 if (numPtsPerCell > 0) {
354 Kokkos::DynRankView<scalarType,typename DT::execution_space::array_layout,Kokkos::HostSpace>
355 internalPoints(
"Hdiv::Tet::In::internalPoints", numPtsPerCell , spaceDim );
357 this->basisCellTopology_ ,
362 Kokkos::DynRankView<scalarType,typename DT::execution_space::array_layout,Kokkos::HostSpace>
363 phisAtInternalPoints(
"Hdiv::Tet::In::phisAtInternalPoints", cardPn , numPtsPerCell );
364 Impl::Basis_HGRAD_TET_Cn_FEM_ORTH::getValues<Kokkos::HostSpace::execution_space,Parameters::MaxNumPtsPerBasisEval>( phisAtInternalPoints , internalPoints , order, OPERATOR_VALUE );
367 for (ordinal_type j=0;j<numPtsPerCell;j++) {
369 const ordinal_type i_card = numFaces*numPtsPerFace+spaceDim*j;
371 for (ordinal_type k=0;k<cardPn;k++) {
372 for (ordinal_type l=0;l<spaceDim;l++) {
373 V2(i_card+l,l*cardPn+k) = phisAtInternalPoints(k,j);
378 for(ordinal_type d=0; d<spaceDim; ++d) {
379 for(ordinal_type l=0; l<spaceDim; ++l) {
380 dofCoords(i_card+d,l) = internalPoints(j,l);
381 dofCoeffs(i_card+d,l) = (l==d);
384 tags[i_card+d][0] = spaceDim;
385 tags[i_card+d][1] = 0;
386 tags[i_card+d][2] = spaceDim*j+d;
387 tags[i_card+d][3] = spaceDim*numPtsPerCell;
394 Kokkos::DynRankView<scalarType,Kokkos::LayoutLeft,Kokkos::HostSpace>
395 vmat(
"Hdiv::Tet::In::vmat", card, card),
396 work(
"Hdiv::Tet::In::work", lwork),
397 ipiv(
"Hdiv::Tet::In::ipiv", card);
400 for(ordinal_type i=0; i< card; ++i) {
401 for(ordinal_type j=0; j< card; ++j) {
403 for(ordinal_type k=0; k< cardVecPn; ++k)
404 s += V2(i,k)*V1(k,j);
409 ordinal_type info = 0;
410 Teuchos::LAPACK<ordinal_type,scalarType> lapack;
412 lapack.GETRF(card, card,
413 vmat.data(), vmat.stride_1(),
414 (ordinal_type*)ipiv.data(),
417 INTREPID2_TEST_FOR_EXCEPTION( info != 0,
419 ">>> ERROR: (Intrepid2::Basis_HDIV_TET_In_FEM) lapack.GETRF returns nonzero info." );
422 vmat.data(), vmat.stride_1(),
423 (ordinal_type*)ipiv.data(),
427 INTREPID2_TEST_FOR_EXCEPTION( info != 0,
429 ">>> ERROR: (Intrepid2::Basis_HDIV_TET_In_FEM) lapack.GETRI returns nonzero info." );
431 for (ordinal_type i=0;i<cardVecPn;++i)
432 for (ordinal_type j=0;j<card;++j){
434 for(ordinal_type k=0; k< card; ++k)
435 s += V1(i,k)*vmat(k,j);
439 this->coeffs_ = Kokkos::create_mirror_view(
typename DT::memory_space(), coeffs);
440 Kokkos::deep_copy(this->coeffs_ , coeffs);
442 this->dofCoords_ = Kokkos::create_mirror_view(
typename DT::memory_space(), dofCoords);
443 Kokkos::deep_copy(this->dofCoords_, dofCoords);
445 this->dofCoeffs_ = Kokkos::create_mirror_view(
typename DT::memory_space(), dofCoeffs);
446 Kokkos::deep_copy(this->dofCoeffs_, dofCoeffs);
452 const ordinal_type posScDim = 0;
453 const ordinal_type posScOrd = 1;
454 const ordinal_type posDfOrd = 2;
456 OrdinalTypeArray1DHost tagView(&tags[0][0], card*tagSize);
460 this->setOrdinalTagData(this->tagToOrdinal_,
463 this->basisCardinality_,
virtual void getCubature(PointViewType cubPoints, weightViewType cubWeights) const override
Returns cubature points and weights (return arrays must be pre-sized/pre-allocated).
virtual ordinal_type getNumPoints() const override
Returns the number of cubature points.
Header file for the Intrepid2::CubatureDirectTetDefault class.
EPointType
Enumeration of types of point distributions in Intrepid.
Defines direct integration rules on a tetrahedron.
Basis_HDIV_TET_In_FEM(const ordinal_type order, const EPointType pointType=POINTTYPE_EQUISPACED)
Constructor.
Header file for the Intrepid2::Basis_HGRAD_TET_Cn_FEM_ORTH class.
static constexpr ordinal_type MaxOrder
The maximum reconstruction order.