mofem/html/_user_data_operators_8hpp_source.html

 /** \file UserDataOperators.hpp
   * \brief User data Operators

 */

 /* This file is part of MoFEM.
  * MoFEM is free software: you can redistribute it and/or modify it under
  * the terms of the GNU Lesser General Public License as published by the
  * Free Software Foundation, either version 3 of the License, or (at your
  * option) any later version.
  *
  * MoFEM is distributed in the hope that it will be useful, but WITHOUT
  * ANY WARRANTY; without even the implied warranty of MERCHANTABILITY or
  * FITNESS FOR A PARTICULAR PURPOSE.  See the GNU Lesser General Public
  * License for more details.
  *
  * You should have received a copy of the GNU Lesser General Public
  * License along with MoFEM. If not, see <http://www.gnu.org/licenses/>. */

 #ifndef __USER_DATA_OPERATORS_HPP__
 #define __USER_DATA_OPERATORS_HPP__

 namespace MoFEM {

 // GET VALUES AT GAUSS PTS

 // TENSOR0

 /** \brief Calculate field values for tenor field rank 0, i.e. scalar field
  *
  */
 template <class T, class A>
 struct OpCalculateScalarFieldValues_General
     : public ForcesAndSourcesCore::UserDataOperator {

   boost::shared_ptr<ublas::vector<T, A>> dataPtr;
   const EntityHandle zeroType;

   OpCalculateScalarFieldValues_General(
       const std::string field_name,
       boost::shared_ptr<ublas::vector<T, A>> &data_ptr,
       const EntityType zero_type = MBVERTEX)
       : ForcesAndSourcesCore::UserDataOperator(
             field_name, ForcesAndSourcesCore::UserDataOperator::OPROW),
         dataPtr(data_ptr), zeroType(zero_type) {
     if (!dataPtr)
       THROW_MESSAGE("Pointer is not set");
   }

   /**
    * \brief calculate values of scalar field at integration points
    * @param  side side entity number
    * @param  type side entity type
    * @param  data entity data
    * @return      error code
    */
   MoFEMErrorCode doWork(int side, EntityType type,
                         DataForcesAndSourcesCore::EntData &data);
 };

 /**
  * \brief Specialization of member function
  *
  */
 template <class T, class A>
 MoFEMErrorCode OpCalculateScalarFieldValues_General<T, A>::doWork(
     int side, EntityType type, DataForcesAndSourcesCore::EntData &data) {
   MoFEMFunctionBegin;
   SETERRQ1(PETSC_COMM_SELF, MOFEM_NOT_IMPLEMENTED, "Not implemented for T = %s",
            typeid(T).name() // boost::core::demangle(typeid(T).name()).c_str()
   );
   MoFEMFunctionReturn(0);
 }

 /**
  * \brief Get value at integration points for scalar field
  *
  * \ingroup mofem_forces_and_sources_user_data_operators
  */
 struct OpCalculateScalarFieldValues
     : public OpCalculateScalarFieldValues_General<double, DoubleAllocator> {

   OpCalculateScalarFieldValues(const std::string field_name,
                                boost::shared_ptr<VectorDouble> &data_ptr,
                                const EntityType zero_type = MBVERTEX)
       : OpCalculateScalarFieldValues_General<double, DoubleAllocator>(
             field_name, data_ptr, zero_type) {
     if (!dataPtr)
       THROW_MESSAGE("Pointer is not set");
   }

   /**
    * \brief calculate values of scalar field at integration points
    * @param  side side entity number
    * @param  type side entity type
    * @param  data entity data
    * @return      error code
    */
   MoFEMErrorCode doWork(int side, EntityType type,
                         DataForcesAndSourcesCore::EntData &data) {
     MoFEMFunctionBegin;
     VectorDouble &vec = *dataPtr;
     const int nb_gauss_pts = getGaussPts().size2();
     if (type == zeroType) {
       vec.resize(nb_gauss_pts, false);
       vec.clear();
     }
     const int nb_dofs = data.getFieldData().size();
     if (nb_dofs) {
       const int nb_gauss_pts = getGaussPts().size2();
       const int nb_base_functions = data.getN().size2();
       auto base_function = data.getFTensor0N();
       auto values_at_gauss_pts = getFTensor0FromVec(vec);
       for (int gg = 0; gg != nb_gauss_pts; ++gg) {
         auto field_data = data.getFTensor0FieldData();
         int bb = 0;
         for (; bb != nb_dofs; ++bb) {
           values_at_gauss_pts += field_data * base_function;
           ++field_data;
           ++base_function;
         }
         // It is possible to have more base functions than dofs
         for (; bb != nb_base_functions; ++bb)
           ++base_function;
         ++values_at_gauss_pts;
       }
     }
     MoFEMFunctionReturn(0);
   }
 };

 /**
  * @brief Get rate of scalar field at integration points
  *
  * \ingroup mofem_forces_and_sources_user_data_operators
  */
 struct OpCalculateScalarFieldValuesDot
     : public ForcesAndSourcesCore::UserDataOperator {

   boost::shared_ptr<VectorDouble> dataPtr;
   const EntityHandle zeroAtType;
   VectorDouble dotVector;

   OpCalculateScalarFieldValuesDot(const std::string field_name,
                                   boost::shared_ptr<VectorDouble> &data_ptr,
                                   const EntityType zero_at_type = MBVERTEX)
       : ForcesAndSourcesCore::UserDataOperator(
             field_name, ForcesAndSourcesCore::UserDataOperator::OPROW),
         dataPtr(data_ptr), zeroAtType(zero_at_type) {
     if (!dataPtr)
       THROW_MESSAGE("Pointer is not set");
   }

   MoFEMErrorCode doWork(int side, EntityType type,
                         DataForcesAndSourcesCore::EntData &data) {
     MoFEMFunctionBegin;

     const int nb_gauss_pts = getGaussPts().size2();
     VectorDouble &vec = *dataPtr;
     if (type == zeroAtType) {
       vec.resize(nb_gauss_pts, false);
       vec.clear();
     }

     auto &local_indices = data.getLocalIndices();
     const int nb_dofs = local_indices.size();
     if (nb_dofs) {

       dotVector.resize(nb_dofs, false);
       const double *array;
       CHKERR VecGetArrayRead(getFEMethod()->ts_u_t, &array);
       for (int i = 0; i != local_indices.size(); ++i)
         if (local_indices[i] != -1)
           dotVector[i] = array[local_indices[i]];
         else
           dotVector[i] = 0;
       CHKERR VecRestoreArrayRead(getFEMethod()->ts_u_t, &array);

       const int nb_base_functions = data.getN().size2();
       auto base_function = data.getFTensor0N();
       auto values_at_gauss_pts = getFTensor0FromVec(vec);

       for (int gg = 0; gg != nb_gauss_pts; ++gg) {
         auto field_data = getFTensor0FromVec(dotVector);
         int bb = 0;
         for (; bb != nb_dofs; ++bb) {
           values_at_gauss_pts += field_data * base_function;
           ++field_data;
           ++base_function;
         }
         // Number of dofs can be smaller than number of Tensor_Dim x base
         // functions
         for (; bb != nb_base_functions; ++bb)
           ++base_function;
         ++values_at_gauss_pts;
       }
     }
     MoFEMFunctionReturn(0);
   }
 };

 /**
  * \depreacted Name inconstent with other operators
  *
  */
 using OpCalculateScalarValuesDot = OpCalculateScalarFieldValuesDot;

 // TENSOR1

 /** \brief Calculate field values for tenor field rank 1, i.e. vector field
  *
  */
 template <int Tensor_Dim, class T, class L, class A>
 struct OpCalculateVectorFieldValues_General
     : public ForcesAndSourcesCore::UserDataOperator {

   boost::shared_ptr<ublas::matrix<T, L, A>> dataPtr;
   const EntityHandle zeroType;

   OpCalculateVectorFieldValues_General(
       const std::string field_name,
       boost::shared_ptr<ublas::matrix<T, L, A>> &data_ptr,
       const EntityType zero_type = MBVERTEX)
       : ForcesAndSourcesCore::UserDataOperator(
             field_name, ForcesAndSourcesCore::UserDataOperator::OPROW),
         dataPtr(data_ptr), zeroType(zero_type) {
     if (!dataPtr)
       THROW_MESSAGE("Pointer is not set");
   }

   /**
    * \brief calculate values of vector field at integration points
    * @param  side side entity number
    * @param  type side entity type
    * @param  data entity data
    * @return      error code
    */
   MoFEMErrorCode doWork(int side, EntityType type,
                         DataForcesAndSourcesCore::EntData &data);
 };

 template <int Tensor_Dim, class T, class L, class A>
 MoFEMErrorCode
 OpCalculateVectorFieldValues_General<Tensor_Dim, T, L, A>::doWork(
     int side, EntityType type, DataForcesAndSourcesCore::EntData &data) {
   MoFEMFunctionBeginHot;
   SETERRQ2(PETSC_COMM_SELF, MOFEM_NOT_IMPLEMENTED,
            "Not implemented for T = %s and dim = %d",
            typeid(T).name(), // boost::core::demangle(typeid(T).name()),
            Tensor_Dim);
   MoFEMFunctionReturnHot(0);
 }

 /** \brief Calculate field values (template specialization) for tensor field
  * rank 1, i.e. vector field
  *
  */
 template <int Tensor_Dim>
 struct OpCalculateVectorFieldValues_General<Tensor_Dim, double,
                                             ublas::row_major, DoubleAllocator>
     : public ForcesAndSourcesCore::UserDataOperator {

   boost::shared_ptr<MatrixDouble> dataPtr;
   const EntityHandle zeroType;

   OpCalculateVectorFieldValues_General(
       const std::string field_name, boost::shared_ptr<MatrixDouble> &data_ptr,
       const EntityType zero_type = MBVERTEX)
       : ForcesAndSourcesCore::UserDataOperator(
             field_name, ForcesAndSourcesCore::UserDataOperator::OPROW),
         dataPtr(data_ptr), zeroType(zero_type) {
     if (!dataPtr)
       THROW_MESSAGE("Pointer is not set");
   }

   MoFEMErrorCode doWork(int side, EntityType type,
                         DataForcesAndSourcesCore::EntData &data);
 };

 /**
  * \brief Member function specialization calculating values for tenor field rank
  *
  */
 template <int Tensor_Dim>
 MoFEMErrorCode OpCalculateVectorFieldValues_General<
     Tensor_Dim, double, ublas::row_major,
     DoubleAllocator>::doWork(int side, EntityType type,
                              DataForcesAndSourcesCore::EntData &data) {
   MoFEMFunctionBegin;
   const int nb_dofs = data.getFieldData().size();
   if (!nb_dofs && type == this->zeroType) {
     dataPtr->resize(Tensor_Dim, 0, false);
     MoFEMFunctionReturnHot(0);
   }
   if (!nb_dofs) {
     MoFEMFunctionReturnHot(0);
   }
   const int nb_gauss_pts = data.getN().size1();
   const int nb_base_functions = data.getN().size2();
   MatrixDouble &mat = *dataPtr;
   if (type == zeroType) {
     mat.resize(Tensor_Dim, nb_gauss_pts, false);
     mat.clear();
   }
   auto base_function = data.getFTensor0N();
   auto values_at_gauss_pts = getFTensor1FromMat<Tensor_Dim>(mat);
   FTensor::Index<'I', Tensor_Dim> I;
   const int size = nb_dofs / Tensor_Dim;
   if (nb_dofs % Tensor_Dim) {
     SETERRQ(PETSC_COMM_SELF, MOFEM_DATA_INCONSISTENCY, "Data inconsistency");
   }
   for (int gg = 0; gg != nb_gauss_pts; ++gg) {
     auto field_data = data.getFTensor1FieldData<Tensor_Dim>();
     int bb = 0;
     for (; bb != size; ++bb) {
       values_at_gauss_pts(I) += field_data(I) * base_function;
       ++field_data;
       ++base_function;
     }
     // Number of dofs can be smaller than number of Tensor_Dim x base functions
     for (; bb != nb_base_functions; ++bb)
       ++base_function;
     ++values_at_gauss_pts;
   }
   MoFEMFunctionReturn(0);
 }

 /** \brief Get values at integration pts for tensor filed rank 1, i.e. vector
  * field
  *
  * \ingroup mofem_forces_and_sources_user_data_operators
  */
 template <int Tensor_Dim>
 struct OpCalculateVectorFieldValues
     : public OpCalculateVectorFieldValues_General<
           Tensor_Dim, double, ublas::row_major, DoubleAllocator> {

   OpCalculateVectorFieldValues(const std::string field_name,
                                boost::shared_ptr<MatrixDouble> &data_ptr,
                                const EntityType zero_type = MBVERTEX)
       : OpCalculateVectorFieldValues_General<Tensor_Dim, double,
                                              ublas::row_major, DoubleAllocator>(
             field_name, data_ptr, zero_type) {}
 };

 /** \brief Get time direvatives of values at integration pts for tensor filed
  * rank 1, i.e. vector field
  *
  * \ingroup mofem_forces_and_sources_user_data_operators
  */
 template <int Tensor_Dim>
 struct OpCalculateVectorFieldValuesDot
     : public ForcesAndSourcesCore::UserDataOperator {

   boost::shared_ptr<MatrixDouble> dataPtr;
   const EntityHandle zeroAtType;
   VectorDouble dotVector;

   template <int Dim> inline auto getFTensorDotData() {
     static_assert(Dim || !Dim, "not implemented");
   }

   OpCalculateVectorFieldValuesDot(const std::string field_name,
                                   boost::shared_ptr<MatrixDouble> &data_ptr,
                                   const EntityType zero_at_type = MBVERTEX)
       : ForcesAndSourcesCore::UserDataOperator(
             field_name, ForcesAndSourcesCore::UserDataOperator::OPROW),
         dataPtr(data_ptr), zeroAtType(zero_at_type) {
     if (!dataPtr)
       THROW_MESSAGE("Pointer is not set");
   }

   MoFEMErrorCode doWork(int side, EntityType type,
                         DataForcesAndSourcesCore::EntData &data) {
     MoFEMFunctionBegin;
     auto &local_indices = data.getLocalIndices();
     const int nb_dofs = local_indices.size();
     if (!nb_dofs && type == zeroAtType) {
       dataPtr->resize(Tensor_Dim, 0, false);
       MoFEMFunctionReturnHot(0);
     }
     if (!nb_dofs)
       MoFEMFunctionReturnHot(0);

     dotVector.resize(nb_dofs, false);
     const double *array;
     CHKERR VecGetArrayRead(getFEMethod()->ts_u_t, &array);
     for (int i = 0; i != local_indices.size(); ++i)
       if (local_indices[i] != -1)
         dotVector[i] = array[local_indices[i]];
       else
         dotVector[i] = 0;
     CHKERR VecRestoreArrayRead(getFEMethod()->ts_u_t, &array);

     const int nb_gauss_pts = data.getN().size1();
     const int nb_base_functions = data.getN().size2();
     MatrixDouble &mat = *dataPtr;
     if (type == zeroAtType) {
       mat.resize(Tensor_Dim, nb_gauss_pts, false);
       mat.clear();
     }
     auto base_function = data.getFTensor0N();
     auto values_at_gauss_pts = getFTensor1FromMat<Tensor_Dim>(mat);
     FTensor::Index<'I', Tensor_Dim> I;
     const int size = nb_dofs / Tensor_Dim;
     if (nb_dofs % Tensor_Dim) {
       SETERRQ(PETSC_COMM_SELF, MOFEM_DATA_INCONSISTENCY, "Data inconsistency");
     }
     for (int gg = 0; gg != nb_gauss_pts; ++gg) {
       auto field_data = getFTensorDotData<3>();
       int bb = 0;
       for (; bb != size; ++bb) {
         values_at_gauss_pts(I) += field_data(I) * base_function;
         ++field_data;
         ++base_function;
       }
       // Number of dofs can be smaller than number of Tensor_Dim x base
       // functions
       for (; bb != nb_base_functions; ++bb)
         ++base_function;
       ++values_at_gauss_pts;
     }
     MoFEMFunctionReturn(0);
   }
 };

 template <>
 template <>
 inline auto OpCalculateVectorFieldValuesDot<3>::getFTensorDotData<3>() {
   return FTensor::Tensor1<FTensor::PackPtr<double *, 3>, 3>(
       &dotVector[0], &dotVector[1], &dotVector[2]);
 }

 /** \brief Calculate field values for tenor field rank 2.
  *
  */
 template <int Tensor_Dim0, int Tensor_Dim1, class T, class L, class A>
 struct OpCalculateTensor2FieldValues_General
     : public ForcesAndSourcesCore::UserDataOperator {

   boost::shared_ptr<ublas::matrix<T, L, A>> dataPtr;
   const EntityHandle zeroType;

   OpCalculateTensor2FieldValues_General(
       const std::string field_name,
       boost::shared_ptr<ublas::matrix<T, L, A>> &data_ptr,
       const EntityType zero_type = MBVERTEX)
       : ForcesAndSourcesCore::UserDataOperator(
             field_name, ForcesAndSourcesCore::UserDataOperator::OPROW),
         dataPtr(data_ptr), zeroType(zero_type) {
     if (!dataPtr)
       THROW_MESSAGE("Pointer is not set");
   }

   MoFEMErrorCode doWork(int side, EntityType type,
                         DataForcesAndSourcesCore::EntData &data);
 };

 template <int Tensor_Dim0, int Tensor_Dim1, class T, class L, class A>
 MoFEMErrorCode
 OpCalculateTensor2FieldValues_General<Tensor_Dim0, Tensor_Dim1, T, L, A>::
     doWork(int side, EntityType type, DataForcesAndSourcesCore::EntData &data) {
   MoFEMFunctionBeginHot;
   SETERRQ3(PETSC_COMM_SELF, MOFEM_NOT_IMPLEMENTED,
            "Not implemented for T = %s, dim0 = %d and dim1 = %d",
            typeid(T).name(), // boost::core::demangle(typeid(T).name()),
            Tensor_Dim0, Tensor_Dim1);
   MoFEMFunctionReturnHot(0);
 }

 template <int Tensor_Dim0, int Tensor_Dim1>
 struct OpCalculateTensor2FieldValues_General<Tensor_Dim0, Tensor_Dim1, double,
                                              ublas::row_major, DoubleAllocator>
     : public ForcesAndSourcesCore::UserDataOperator {

   boost::shared_ptr<ublas::matrix<double, ublas::row_major, DoubleAllocator>>
       dataPtr;
   const EntityHandle zeroType;

   OpCalculateTensor2FieldValues_General(
       const std::string field_name,
       boost::shared_ptr<
           ublas::matrix<double, ublas::row_major, DoubleAllocator>> &data_ptr,
       const EntityType zero_type = MBVERTEX)
       : ForcesAndSourcesCore::UserDataOperator(
             field_name, ForcesAndSourcesCore::UserDataOperator::OPROW),
         dataPtr(data_ptr), zeroType(zero_type) {
     if (!dataPtr)
       THROW_MESSAGE("Pointer is not set");
   }

   MoFEMErrorCode doWork(int side, EntityType type,
                         DataForcesAndSourcesCore::EntData &data);
 };

 template <int Tensor_Dim0, int Tensor_Dim1>
 MoFEMErrorCode OpCalculateTensor2FieldValues_General<
     Tensor_Dim0, Tensor_Dim1, double, ublas::row_major,
     DoubleAllocator>::doWork(int side, EntityType type,
                              DataForcesAndSourcesCore::EntData &data) {
   MoFEMFunctionBeginHot;
   const int nb_dofs = data.getFieldData().size();
   const int nb_gauss_pts = data.getN().size1();
   if (!nb_dofs && type == this->zeroType) {
     dataPtr->resize(Tensor_Dim0 * Tensor_Dim1, 0, false);
     MoFEMFunctionReturnHot(0);
   }
   if (!nb_dofs) {
     MoFEMFunctionReturnHot(0);
   }
   const int nb_base_functions = data.getN().size2();
   MatrixDouble &mat = *dataPtr;
   if (type == zeroType) {
     mat.resize(Tensor_Dim0 * Tensor_Dim1, nb_gauss_pts, false);
     mat.clear();
   }
   auto base_function = data.getFTensor0N();
   auto values_at_gauss_pts = getFTensor2FromMat<Tensor_Dim0, Tensor_Dim1>(mat);
   FTensor::Index<'i', Tensor_Dim0> i;
   FTensor::Index<'j', Tensor_Dim1> j;
   const int size = nb_dofs / (Tensor_Dim0 * Tensor_Dim1);
   for (int gg = 0; gg != nb_gauss_pts; ++gg) {
     auto field_data = data.getFTensor2FieldData<Tensor_Dim0, Tensor_Dim1>();
     int bb = 0;
     for (; bb != size; ++bb) {
       values_at_gauss_pts(i, j) += field_data(i, j) * base_function;
       ++field_data;
       ++base_function;
     }
     for (; bb != nb_base_functions; ++bb)
       ++base_function;
     ++values_at_gauss_pts;
   }
   MoFEMFunctionReturnHot(0);
 }

 /** \brief Get values at integration pts for tensor filed rank 2, i.e. matrix
  * field
  *
  * \ingroup mofem_forces_and_sources_user_data_operators
  */
 template <int Tensor_Dim0, int Tensor_Dim1>
 struct OpCalculateTensor2FieldValues
     : public OpCalculateTensor2FieldValues_General<
           Tensor_Dim0, Tensor_Dim1, double, ublas::row_major, DoubleAllocator> {

   OpCalculateTensor2FieldValues(const std::string field_name,
                                 boost::shared_ptr<MatrixDouble> &data_ptr,
                                 const EntityType zero_type = MBVERTEX)
       : OpCalculateTensor2FieldValues_General<Tensor_Dim0, Tensor_Dim1, double,
                                               ublas::row_major,
                                               DoubleAllocator>(
             field_name, data_ptr, zero_type) {}
 };

 /** \brief Get time direvarive values at integration pts for tensor filed rank
  * 2, i.e. matrix field
  *
  * \ingroup mofem_forces_and_sources_user_data_operators
  */
 template <int Tensor_Dim0, int Tensor_Dim1>
 struct OpCalculateTensor2FieldValuesDot
     : public ForcesAndSourcesCore::UserDataOperator {

   boost::shared_ptr<MatrixDouble> &dataPtr; ///< Data computed into this matrix
   EntityType zeroAtType;  ///< Zero values at Gauss point at this type
   VectorDouble dotVector; ///< Keeps temoorary values of time directives

   template <int Dim0, int Dim1> auto getFTensorDotData() {
     static_assert(Dim0 || !Dim0 || Dim1 || !Dim1, "not implemented");
   }

   OpCalculateTensor2FieldValuesDot(const std::string field_name,
                                    boost::shared_ptr<MatrixDouble> &data_ptr,
                                    const EntityType zero_at_type = MBVERTEX)
       : ForcesAndSourcesCore::UserDataOperator(
             field_name, ForcesAndSourcesCore::UserDataOperator::OPROW),
         dataPtr(data_ptr), zeroAtType(zero_at_type) {
     if (!dataPtr)
       THROW_MESSAGE("Pointer is not set");
   }

   MoFEMErrorCode doWork(int side, EntityType type,
                         DataForcesAndSourcesCore::EntData &data) {
     MoFEMFunctionBeginHot;
     const auto &local_indices = data.getLocalIndices();
     const int nb_dofs = local_indices.size();
     const int nb_gauss_pts = data.getN().size1();
     if (!nb_dofs && type == zeroAtType) {
       dataPtr->resize(Tensor_Dim0 * Tensor_Dim1, 0, false);
       MoFEMFunctionReturnHot(0);
     }
     if (!nb_dofs) {
       MoFEMFunctionReturnHot(0);
     }

     dotVector.resize(nb_dofs, false);
     const double *array;
     CHKERR VecGetArrayRead(getFEMethod()->ts_u_t, &array);
     for (int i = 0; i != local_indices.size(); ++i)
       if (local_indices[i] != -1)
         dotVector[i] = array[local_indices[i]];
       else
         dotVector[i] = 0;
     CHKERR VecRestoreArrayRead(getFEMethod()->ts_u_t, &array);

     const int nb_base_functions = data.getN().size2();
     MatrixDouble &mat = *dataPtr;
     if (type == zeroAtType) {
       mat.resize(Tensor_Dim0 * Tensor_Dim1, nb_gauss_pts, false);
       mat.clear();
     }
     auto base_function = data.getFTensor0N();
     auto values_at_gauss_pts =
         getFTensor2FromMat<Tensor_Dim0, Tensor_Dim1>(mat);
     FTensor::Index<'i', Tensor_Dim0> i;
     FTensor::Index<'j', Tensor_Dim1> j;
     const int size = nb_dofs / (Tensor_Dim0 * Tensor_Dim1);
     for (int gg = 0; gg != nb_gauss_pts; ++gg) {
       auto field_data = getFTensorDotData<Tensor_Dim0, Tensor_Dim1>();
       int bb = 0;
       for (; bb != size; ++bb) {
         values_at_gauss_pts(i, j) += field_data(i, j) * base_function;
         ++field_data;
         ++base_function;
       }
       for (; bb != nb_base_functions; ++bb)
         ++base_function;
       ++values_at_gauss_pts;
     }
     MoFEMFunctionReturnHot(0);
   }
 };

 template <>
 template <>
 inline auto OpCalculateTensor2FieldValuesDot<3, 3>::getFTensorDotData<3, 3>() {
   return FTensor::Tensor2<FTensor::PackPtr<double *, 9>, 3, 3>(
       &dotVector[0], &dotVector[1], &dotVector[2],

       &dotVector[3], &dotVector[4], &dotVector[5],

       &dotVector[6], &dotVector[7], &dotVector[8]);
 }

 /**
  * @brief Calculate symmetric tensor field values at integration pts.
  *
  * @tparam Tensor_Dim

  * \ingroup mofem_forces_and_sources_user_data_operators
  */
 template <int Tensor_Dim>
 struct OpCalculateTensor2SymmetricFieldValues
     : public ForcesAndSourcesCore::UserDataOperator {

   boost::shared_ptr<MatrixDouble> dataPtr;
   const EntityHandle zeroType;
   const int zeroSide;

   OpCalculateTensor2SymmetricFieldValues(
       const std::string field_name, boost::shared_ptr<MatrixDouble> &data_ptr,
       const EntityType zero_type = MBEDGE, const int zero_side = 0)
       : ForcesAndSourcesCore::UserDataOperator(
             field_name, ForcesAndSourcesCore::UserDataOperator::OPROW),
         dataPtr(data_ptr), zeroType(zero_type), zeroSide(zero_side) {
     if (!dataPtr)
       THROW_MESSAGE("Pointer is not set");
   }

   MoFEMErrorCode doWork(int side, EntityType type,
                         DataForcesAndSourcesCore::EntData &data) {
     MoFEMFunctionBegin;
     MatrixDouble &mat = *dataPtr;
     const int nb_gauss_pts = getGaussPts().size2();
     if (type == this->zeroType && side == zeroSide) {
       mat.resize((Tensor_Dim * (Tensor_Dim + 1)) / 2, nb_gauss_pts, false);
       mat.clear();
     }
     const int nb_dofs = data.getFieldData().size();
     if (!nb_dofs)
       MoFEMFunctionReturnHot(0);

     const int nb_base_functions = data.getN().size2();
     auto base_function = data.getFTensor0N();
     auto values_at_gauss_pts = getFTensor2SymmetricFromMat<Tensor_Dim>(mat);
     FTensor::Index<'i', Tensor_Dim> i;
     FTensor::Index<'j', Tensor_Dim> j;
     const int size = nb_dofs / ((Tensor_Dim * (Tensor_Dim + 1)) / 2);
     for (int gg = 0; gg != nb_gauss_pts; ++gg) {
       auto field_data = data.getFTensor2SymmetricFieldData<Tensor_Dim>();
       int bb = 0;
       for (; bb != size; ++bb) {
         values_at_gauss_pts(i, j) += field_data(i, j) * base_function;
         ++field_data;
         ++base_function;
       }
       for (; bb != nb_base_functions; ++bb)
         ++base_function;
       ++values_at_gauss_pts;
     }

     MoFEMFunctionReturn(0);
   }
 };

 /**
  * @brief Calculate symmetric tensor field rates ant integratio pts.
  *
  * @tparam Tensor_Dim
  *
  * \ingroup mofem_forces_and_sources_user_data_operators
  */
 template <int Tensor_Dim>
 struct OpCalculateTensor2SymmetricFieldValuesDot
     : public ForcesAndSourcesCore::UserDataOperator {

   boost::shared_ptr<MatrixDouble> dataPtr;
   const EntityHandle zeroType;
   const int zeroSide;
   VectorDouble dotVector;

   template <int Dim> inline auto getFTensorDotData() {
     static_assert(Dim || !Dim, "not implemented");
   }

   OpCalculateTensor2SymmetricFieldValuesDot(
       const std::string field_name, boost::shared_ptr<MatrixDouble> &data_ptr,
       const EntityType zero_type = MBEDGE, const int zero_side = 0)
       : ForcesAndSourcesCore::UserDataOperator(
             field_name, ForcesAndSourcesCore::UserDataOperator::OPROW),
         dataPtr(data_ptr), zeroType(zero_type), zeroSide(zero_side) {
     if (!dataPtr)
       THROW_MESSAGE("Pointer is not set");
   }

   MoFEMErrorCode doWork(int side, EntityType type,
                         DataForcesAndSourcesCore::EntData &data) {
     MoFEMFunctionBegin;
     const int nb_gauss_pts = getGaussPts().size2();
     MatrixDouble &mat = *dataPtr;
     if (type == zeroType && side == zeroSide) {
       mat.resize((Tensor_Dim * (Tensor_Dim + 1)) / 2, nb_gauss_pts, false);
       mat.clear();
     }
     auto &local_indices = data.getLocalIndices();
     const int nb_dofs = local_indices.size();
     if (!nb_dofs)
       MoFEMFunctionReturnHot(0);

     dotVector.resize(nb_dofs, false);
     const double *array;
     CHKERR VecGetArrayRead(getFEMethod()->ts_u_t, &array);
     for (int i = 0; i != local_indices.size(); ++i)
       if (local_indices[i] != -1)
         dotVector[i] = array[local_indices[i]];
       else
         dotVector[i] = 0;
     CHKERR VecRestoreArrayRead(getFEMethod()->ts_u_t, &array);

     const int nb_base_functions = data.getN().size2();

     auto base_function = data.getFTensor0N();
     auto values_at_gauss_pts = getFTensor2SymmetricFromMat<Tensor_Dim>(mat);
     FTensor::Index<'i', Tensor_Dim> i;
     FTensor::Index<'j', Tensor_Dim> j;
     const int size = nb_dofs / ((Tensor_Dim * (Tensor_Dim + 1)) / 2);
     for (int gg = 0; gg != nb_gauss_pts; ++gg) {
       auto field_data = getFTensorDotData<Tensor_Dim>();
       int bb = 0;
       for (; bb != size; ++bb) {
         values_at_gauss_pts(i, j) += field_data(i, j) * base_function;
         ++field_data;
         ++base_function;
       }
       for (; bb != nb_base_functions; ++bb)
         ++base_function;
       ++values_at_gauss_pts;
     }

     MoFEMFunctionReturn(0);
   }
 };

 template <>
 template <>
 inline auto
 OpCalculateTensor2SymmetricFieldValuesDot<3>::getFTensorDotData<3>() {
   return FTensor::Tensor2_symmetric<FTensor::PackPtr<double *, 6>, 3>(
       &dotVector[0], &dotVector[1], &dotVector[2], &dotVector[3], &dotVector[4],
       &dotVector[5]);
 }

 template <>
 template <>
 inline auto
 OpCalculateTensor2SymmetricFieldValuesDot<2>::getFTensorDotData<2>() {
   return FTensor::Tensor2_symmetric<FTensor::PackPtr<double *, 3>, 2>(
       &dotVector[0], &dotVector[1], &dotVector[2]);
 }

 // GET GRADIENTS AT GAUSS POINTS

 /**
  * \brief Evaluate field gradient values for scalar field, i.e. gradient is
  * tensor rank 1 (vector)
  *
  */
 template <int Tensor_Dim, class T, class L, class A>
 struct OpCalculateScalarFieldGradient_General
     : public OpCalculateVectorFieldValues_General<Tensor_Dim, T, L, A> {

   OpCalculateScalarFieldGradient_General(
       const std::string field_name, boost::shared_ptr<MatrixDouble> &data_ptr,
       const EntityType zero_type = MBVERTEX)
       : OpCalculateVectorFieldValues_General<Tensor_Dim, T, L, A>(
             field_name, data_ptr, zero_type) {}
 };

 /** \brief Evaluate field gradient values for scalar field, i.e. gradient is
  * tensor rank 1 (vector), specialization
  *
  */
 template <int Tensor_Dim>
 struct OpCalculateScalarFieldGradient_General<Tensor_Dim, double,
                                               ublas::row_major, DoubleAllocator>
     : public OpCalculateVectorFieldValues_General<
           Tensor_Dim, double, ublas::row_major, DoubleAllocator> {

   OpCalculateScalarFieldGradient_General(
       const std::string field_name, boost::shared_ptr<MatrixDouble> &data_ptr,
       const EntityType zero_type = MBVERTEX)
       : OpCalculateVectorFieldValues_General<Tensor_Dim, double,
                                              ublas::row_major, DoubleAllocator>(
             field_name, data_ptr, zero_type) {}

   /**
    * \brief calculate gradient values of scalar field at integration points
    * @param  side side entity number
    * @param  type side entity type
    * @param  data entity data
    * @return      error code
    */
   MoFEMErrorCode doWork(int side, EntityType type,
                         DataForcesAndSourcesCore::EntData &data);
 };

 /**
  * \brief Member function specialization calculating scalar field gradients for
  * tenor field rank 1
  *
  */
 template <int Tensor_Dim>
 MoFEMErrorCode OpCalculateScalarFieldGradient_General<
     Tensor_Dim, double, ublas::row_major,
     DoubleAllocator>::doWork(int side, EntityType type,
                              DataForcesAndSourcesCore::EntData &data) {
   MoFEMFunctionBegin;
   const int nb_dofs = data.getFieldData().size();
   if (!this->dataPtr) {
     SETERRQ(PETSC_COMM_SELF, MOFEM_DATA_INCONSISTENCY,
             "Data pointer not allocated");
   }
   if (!nb_dofs && type == this->zeroType) {
     this->dataPtr->resize(Tensor_Dim, 0, false);
     MoFEMFunctionReturnHot(0);
   }
   if (!nb_dofs) {
     MoFEMFunctionReturnHot(0);
   }
   const int nb_gauss_pts = data.getN().size1();
   const int nb_base_functions = data.getN().size2();
   ublas::matrix<double, ublas::row_major, DoubleAllocator> &mat =
       *this->dataPtr;
   if (type == this->zeroType) {
     mat.resize(Tensor_Dim, nb_gauss_pts, false);
     mat.clear();
   }
   auto diff_base_function = data.getFTensor1DiffN<Tensor_Dim>();
   auto gradients_at_gauss_pts = getFTensor1FromMat<Tensor_Dim>(mat);
   FTensor::Index<'I', Tensor_Dim> I;
   for (int gg = 0; gg < nb_gauss_pts; ++gg) {
     auto field_data = data.getFTensor0FieldData();
     int bb = 0;
     for (; bb < nb_dofs; ++bb) {
       gradients_at_gauss_pts(I) += field_data * diff_base_function(I);
       ++field_data;
       ++diff_base_function;
     }
     // Number of dofs can be smaller than number of base functions
     for (; bb != nb_base_functions; ++bb)
       ++diff_base_function;
     ++gradients_at_gauss_pts;
   }
   MoFEMFunctionReturn(0);
 }

 /** \brief Get field gradients at integration pts for scalar filed rank 0, i.e.
  * vector field
  *
  * \ingroup mofem_forces_and_sources_user_data_operators
  */
 template <int Tensor_Dim>
 struct OpCalculateScalarFieldGradient
     : public OpCalculateScalarFieldGradient_General<
           Tensor_Dim, double, ublas::row_major, DoubleAllocator> {

   OpCalculateScalarFieldGradient(const std::string field_name,
                                  boost::shared_ptr<MatrixDouble> &data_ptr,
                                  const EntityType zero_type = MBVERTEX)
       : OpCalculateScalarFieldGradient_General<
             Tensor_Dim, double, ublas::row_major, DoubleAllocator>(
             field_name, data_ptr, zero_type) {}
 };

 /**
  * \brief Evaluate field gradient values for vector field, i.e. gradient is
  * tensor rank 2
  *
  */
 template <int Tensor_Dim0, int Tensor_Dim1, class T, class L, class A>
 struct OpCalculateVectorFieldGradient_General
     : public OpCalculateTensor2FieldValues_General<Tensor_Dim0, Tensor_Dim1, T,
                                                    L, A> {

   OpCalculateVectorFieldGradient_General(
       const std::string field_name, boost::shared_ptr<MatrixDouble> &data_ptr,
       const EntityType zero_type = MBVERTEX)
       : OpCalculateTensor2FieldValues_General<Tensor_Dim0, Tensor_Dim1, T, L,
                                               A>(field_name, data_ptr,
                                                  zero_type) {}
 };

 template <int Tensor_Dim0, int Tensor_Dim1>
 struct OpCalculateVectorFieldGradient_General<Tensor_Dim0, Tensor_Dim1, double,
                                               ublas::row_major, DoubleAllocator>
     : public OpCalculateTensor2FieldValues_General<
           Tensor_Dim0, Tensor_Dim1, double, ublas::row_major, DoubleAllocator> {

   OpCalculateVectorFieldGradient_General(
       const std::string field_name, boost::shared_ptr<MatrixDouble> &data_ptr,
       const EntityType zero_type = MBVERTEX)
       : OpCalculateTensor2FieldValues_General<Tensor_Dim0, Tensor_Dim1, double,
                                               ublas::row_major,
                                               DoubleAllocator>(
             field_name, data_ptr, zero_type) {}

   /**
    * \brief calculate values of vector field at integration points
    * @param  side side entity number
    * @param  type side entity type
    * @param  data entity data
    * @return      error code
    */
   MoFEMErrorCode doWork(int side, EntityType type,
                         DataForcesAndSourcesCore::EntData &data);
 };

 /**
  * \brief Member function specialization calculating vector field gradients for
  * tenor field rank 2
  *
  */
 template <int Tensor_Dim0, int Tensor_Dim1>
 MoFEMErrorCode OpCalculateVectorFieldGradient_General<
     Tensor_Dim0, Tensor_Dim1, double, ublas::row_major,
     DoubleAllocator>::doWork(int side, EntityType type,
                              DataForcesAndSourcesCore::EntData &data) {
   MoFEMFunctionBegin;
   const int nb_dofs = data.getFieldData().size();
   if (!nb_dofs && type == this->zeroType) {
     this->dataPtr->resize(Tensor_Dim0 * Tensor_Dim1, 0, false);
     MoFEMFunctionReturnHot(0);
   }
   if (!nb_dofs) {
     MoFEMFunctionReturnHot(0);
   }
   const int nb_gauss_pts = data.getN().size1();
   const int nb_base_functions = data.getN().size2();
   ublas::matrix<double, ublas::row_major, DoubleAllocator> &mat =
       *this->dataPtr;
   if (type == this->zeroType) {
     mat.resize(Tensor_Dim0 * Tensor_Dim1, nb_gauss_pts, false);
     mat.clear();
   }
   auto diff_base_function = data.getFTensor1DiffN<Tensor_Dim1>();
   auto gradients_at_gauss_pts =
       getFTensor2FromMat<Tensor_Dim0, Tensor_Dim1>(mat);
   FTensor::Index<'I', Tensor_Dim0> I;
   FTensor::Index<'J', Tensor_Dim1> J;
   int size = nb_dofs / Tensor_Dim0;
   if (nb_dofs % Tensor_Dim0) {
     SETERRQ(PETSC_COMM_SELF, MOFEM_DATA_INCONSISTENCY, "Data inconsistency");
   }
   for (int gg = 0; gg < nb_gauss_pts; ++gg) {
     auto field_data = data.getFTensor1FieldData<Tensor_Dim0>();
     int bb = 0;
     for (; bb < size; ++bb) {
       gradients_at_gauss_pts(I, J) += field_data(I) * diff_base_function(J);
       ++field_data;
       ++diff_base_function;
     }
     // Number of dofs can be smaller than number of Tensor_Dim0 x base functions
     for (; bb != nb_base_functions; ++bb)
       ++diff_base_function;
     ++gradients_at_gauss_pts;
   }
   MoFEMFunctionReturn(0);
 }

 /** \brief Get field gradients at integration pts for scalar filed rank 0, i.e.
  * vector field
  *
  * \ingroup mofem_forces_and_sources_user_data_operators
  */
 template <int Tensor_Dim0, int Tensor_Dim1>
 struct OpCalculateVectorFieldGradient
     : public OpCalculateVectorFieldGradient_General<
           Tensor_Dim0, Tensor_Dim1, double, ublas::row_major, DoubleAllocator> {

   OpCalculateVectorFieldGradient(const std::string field_name,
                                  boost::shared_ptr<MatrixDouble> &data_ptr,
                                  const EntityType zero_type = MBVERTEX)
       : OpCalculateVectorFieldGradient_General<Tensor_Dim0, Tensor_Dim1, double,
                                                ublas::row_major,
                                                DoubleAllocator>(
             field_name, data_ptr, zero_type) {}
 };

 /** \brief Get field gradients time derivative at integration pts for scalar
  * filed rank 0, i.e. vector field
  *
  * \ingroup mofem_forces_and_sources_user_data_operators
  */
 template <int Tensor_Dim0, int Tensor_Dim1>
 struct OpCalculateVectorFieldGradientDot
     : public ForcesAndSourcesCore::UserDataOperator {

   boost::shared_ptr<MatrixDouble> &dataPtr; ///< Data computed into this matrix
   EntityType zeroAtType;  ///< Zero values at Gauss point at this type
   VectorDouble dotVector; ///< Keeps temoorary values of time directives

   template <int Dim> inline auto getFTensorDotData() {
     static_assert(Dim || !Dim, "not implemented");
   }

   OpCalculateVectorFieldGradientDot(const std::string field_name,
                                     boost::shared_ptr<MatrixDouble> &data_ptr,
                                     const EntityType zero_at_type = MBVERTEX)
       : ForcesAndSourcesCore::UserDataOperator(
             field_name, ForcesAndSourcesCore::UserDataOperator::OPROW),
         dataPtr(data_ptr), zeroAtType(zero_at_type) {
     if (!dataPtr)
       THROW_MESSAGE("Pointer is not set");
   }

   MoFEMErrorCode doWork(int side, EntityType type,
                         DataForcesAndSourcesCore::EntData &data) {
     MoFEMFunctionBegin;

     const auto &local_indices = data.getLocalIndices();
     const int nb_dofs = local_indices.size();
     if (!nb_dofs && type == zeroAtType) {
       dataPtr->resize(Tensor_Dim0 * Tensor_Dim1, 0, false);
       MoFEMFunctionReturnHot(0);
     }
     if (!nb_dofs)
       MoFEMFunctionReturnHot(0);

     dotVector.resize(nb_dofs, false);
     const double *array;
     CHKERR VecGetArrayRead(getFEMethod()->ts_u_t, &array);
     for (int i = 0; i != local_indices.size(); ++i)
       if (local_indices[i] != -1)
         dotVector[i] = array[local_indices[i]];
       else
         dotVector[i] = 0;
     CHKERR VecRestoreArrayRead(getFEMethod()->ts_u_t, &array);

     const int nb_gauss_pts = data.getN().size1();
     const int nb_base_functions = data.getN().size2();
     ublas::matrix<double, ublas::row_major, DoubleAllocator> &mat = *dataPtr;
     if (type == zeroAtType) {
       mat.resize(Tensor_Dim0 * Tensor_Dim1, nb_gauss_pts, false);
       mat.clear();
     }
     auto diff_base_function = data.getFTensor1DiffN<Tensor_Dim1>();
     auto gradients_at_gauss_pts =
         getFTensor2FromMat<Tensor_Dim0, Tensor_Dim1>(mat);
     FTensor::Index<'I', Tensor_Dim0> I;
     FTensor::Index<'J', Tensor_Dim1> J;
     int size = nb_dofs / Tensor_Dim0;
     if (nb_dofs % Tensor_Dim0) {
       SETERRQ(PETSC_COMM_SELF, MOFEM_DATA_INCONSISTENCY, "Data inconsistency");
     }
     for (int gg = 0; gg < nb_gauss_pts; ++gg) {
       auto field_data = getFTensorDotData<Tensor_Dim0>();
       int bb = 0;
       for (; bb < size; ++bb) {
         gradients_at_gauss_pts(I, J) += field_data(I) * diff_base_function(J);
         ++field_data;
         ++diff_base_function;
       }
       // Number of dofs can be smaller than number of Tensor_Dim0 x base
       // functions
       for (; bb != nb_base_functions; ++bb)
         ++diff_base_function;
       ++gradients_at_gauss_pts;
     }
     MoFEMFunctionReturn(0);
   }
 };

 template <>
 template <>
 inline auto OpCalculateVectorFieldGradientDot<3, 3>::getFTensorDotData<3>() {
   return FTensor::Tensor1<FTensor::PackPtr<double *, 3>, 3>(
       &dotVector[0], &dotVector[1], &dotVector[2]);
 }

 template <>
 template <>
 inline auto OpCalculateVectorFieldGradientDot<2, 2>::getFTensorDotData<2>() {
   return FTensor::Tensor1<FTensor::PackPtr<double *, 2>, 2>(&dotVector[0],
                                                             &dotVector[1]);
 }

 /** \brief Get vector field for H-div approximation
  *
  */
 template <int Tensor_Dim0, class T, class L, class A>
 struct OpCalculateHdivVectorField_General
     : public ForcesAndSourcesCore::UserDataOperator {

   boost::shared_ptr<ublas::matrix<T, L, A>> dataPtr;
   const EntityHandle zeroType;
   const int zeroSide;

   OpCalculateHdivVectorField_General(
       const std::string field_name,
       boost::shared_ptr<ublas::matrix<T, L, A>> &data_ptr,
       const EntityType zero_type = MBEDGE, const int zero_side = 0)
       : ForcesAndSourcesCore::UserDataOperator(
             field_name, ForcesAndSourcesCore::UserDataOperator::OPROW),
         dataPtr(data_ptr), zeroType(zero_type), zeroSide(0) {
     if (!dataPtr)
       THROW_MESSAGE("Pointer is not set");
   }

   /**
    * \brief calculate values of vector field at integration points
    * @param  side side entity number
    * @param  type side entity type
    * @param  data entity data
    * @return      error code
    */
   MoFEMErrorCode doWork(int side, EntityType type,
                         DataForcesAndSourcesCore::EntData &data);
 };

 template <int Tensor_Dim, class T, class L, class A>
 MoFEMErrorCode OpCalculateHdivVectorField_General<Tensor_Dim, T, L, A>::doWork(
     int side, EntityType type, DataForcesAndSourcesCore::EntData &data) {
   MoFEMFunctionBeginHot;
   SETERRQ2(PETSC_COMM_SELF, MOFEM_NOT_IMPLEMENTED,
            "Not implemented for T = %s and dim = %d",
            typeid(T).name(), // boost::core::demangle(typeid(T).name()),
            Tensor_Dim);
   MoFEMFunctionReturnHot(0);
 }

 /** \brief Get vector field for H-div approximation
  *
  */
 template <int Tensor_Dim>
 struct OpCalculateHdivVectorField_General<Tensor_Dim, double, ublas::row_major,
                                           DoubleAllocator>
     : public ForcesAndSourcesCore::UserDataOperator {

   boost::shared_ptr<MatrixDouble> dataPtr;
   const EntityHandle zeroType;
   const int zeroSide;

   OpCalculateHdivVectorField_General(const std::string field_name,
                                      boost::shared_ptr<MatrixDouble> &data_ptr,
                                      const EntityType zero_type = MBEDGE,
                                      const int zero_side = 0)
       : ForcesAndSourcesCore::UserDataOperator(
             field_name, ForcesAndSourcesCore::UserDataOperator::OPROW),
         dataPtr(data_ptr), zeroType(zero_type), zeroSide(zero_side) {
     if (!dataPtr)
       THROW_MESSAGE("Pointer is not set");
   }

   /**
    * \brief Calculate values of vector field at integration points
    * @param  side side entity number
    * @param  type side entity type
    * @param  data entity data
    * @return      error code
    */
   MoFEMErrorCode doWork(int side, EntityType type,
                         DataForcesAndSourcesCore::EntData &data);
 };

 template <int Tensor_Dim>
 MoFEMErrorCode OpCalculateHdivVectorField_General<
     Tensor_Dim, double, ublas::row_major,
     DoubleAllocator>::doWork(int side, EntityType type,
                              DataForcesAndSourcesCore::EntData &data) {
   MoFEMFunctionBegin;
   const int nb_integration_points = getGaussPts().size2();
   if (type == zeroType && side == zeroSide) {
     dataPtr->resize(Tensor_Dim, nb_integration_points, false);
     dataPtr->clear();
   }
   const int nb_dofs = data.getFieldData().size();
   if (!nb_dofs)
     MoFEMFunctionReturnHot(0);
   const int nb_base_functions = data.getN().size2() / Tensor_Dim;
   FTensor::Index<'i', Tensor_Dim> i;
   auto t_n_hdiv = data.getFTensor1N<Tensor_Dim>();
   auto t_data = getFTensor1FromMat<Tensor_Dim>(*dataPtr);
   for (int gg = 0; gg != nb_integration_points; ++gg) {
     auto t_dof = data.getFTensor0FieldData();
     int bb = 0;
     for (; bb != nb_dofs; ++bb) {
       t_data(i) += t_n_hdiv(i) * t_dof;
       ++t_n_hdiv;
       ++t_dof;
     }
     for (; bb != nb_base_functions; ++bb)
       ++t_n_hdiv;
     ++t_data;
   }
   MoFEMFunctionReturn(0);
 }

 /** \brief Get vector field for H-div approximation
  *
  * \ingroup mofem_forces_and_sources_user_data_operators
  */
 template <int Tensor_Dim>
 struct OpCalculateHdivVectorField
     : public OpCalculateHdivVectorField_General<
           Tensor_Dim, double, ublas::row_major, DoubleAllocator> {

   OpCalculateHdivVectorField(const std::string field_name,
                              boost::shared_ptr<MatrixDouble> &data_ptr,
                              const EntityType zero_type = MBEDGE,
                              const int zero_side = 0)
       : OpCalculateHdivVectorField_General<Tensor_Dim, double, ublas::row_major,
                                            DoubleAllocator>(
             field_name, data_ptr, zero_type, zero_side) {}
 };

 /**
  * @brief Calculate divergence of vector field
  * @ingroup mofem_forces_and_sources_user_data_operators
  *
  * @tparam Tensor_Dim dimension of space
  */
 template <int Tensor_Dim1, int Tensor_Dim2>
 struct OpCalculateHdivVectorDivergence
     : public ForcesAndSourcesCore::UserDataOperator {

   boost::shared_ptr<VectorDouble> dataPtr;
   const EntityHandle zeroType;
   const int zeroSide;

   OpCalculateHdivVectorDivergence(const std::string field_name,
                                   boost::shared_ptr<VectorDouble> &data_ptr,
                                   const EntityType zero_type = MBEDGE,
                                   const int zero_side = 0)
       : ForcesAndSourcesCore::UserDataOperator(
             field_name, ForcesAndSourcesCore::UserDataOperator::OPROW),
         dataPtr(data_ptr), zeroType(zero_type), zeroSide(zero_side) {
     if (!dataPtr)
       THROW_MESSAGE("Pointer is not set");
   }

   MoFEMErrorCode doWork(int side, EntityType type,
                         DataForcesAndSourcesCore::EntData &data) {
     MoFEMFunctionBegin;
     const int nb_integration_points = getGaussPts().size2();
     if (type == zeroType && side == zeroSide) {
       dataPtr->resize(nb_integration_points, false);
       dataPtr->clear();
     }
     const int nb_dofs = data.getFieldData().size();
     if (!nb_dofs)
       MoFEMFunctionReturnHot(0);
     const int nb_base_functions = data.getN().size2() / Tensor_Dim1;
     FTensor::Index<'i', Tensor_Dim1> i;
     auto t_n_diff_hdiv = data.getFTensor2DiffN<Tensor_Dim1, Tensor_Dim2>();
     auto t_data = getFTensor0FromVec(*dataPtr);
     for (int gg = 0; gg != nb_integration_points; ++gg) {
       auto t_dof = data.getFTensor0FieldData();
       int bb = 0;
       for (; bb != nb_dofs; ++bb) {
         double div = 0;
         for (auto ii = 0; ii != Tensor_Dim2; ++ii)
           div += t_n_diff_hdiv(ii, ii);
         t_data += t_dof * div;
         ++t_n_diff_hdiv;
         ++t_dof;
       }
       for (; bb != nb_base_functions; ++bb)
         ++t_n_diff_hdiv;
       ++t_data;
     }
     MoFEMFunctionReturn(0);
   }
 };

 /**
  * @brief Calculate curl   of vector field
  * @ingroup mofem_forces_and_sources_user_data_operators
  *
  * @tparam Tensor_Dim dimension of space
  */
 template <int Tensor_Dim>
 struct OpCalculateHcurlVectorCurl
     : public ForcesAndSourcesCore::UserDataOperator {

   boost::shared_ptr<MatrixDouble> dataPtr;
   const EntityHandle zeroType;
   const int zeroSide;

   OpCalculateHcurlVectorCurl(const std::string field_name,
                              boost::shared_ptr<MatrixDouble> &data_ptr,
                              const EntityType zero_type = MBEDGE,
                              const int zero_side = 0)
       : ForcesAndSourcesCore::UserDataOperator(
             field_name, ForcesAndSourcesCore::UserDataOperator::OPROW),
         dataPtr(data_ptr), zeroType(zero_type), zeroSide(zero_side) {
     if (!dataPtr)
       THROW_MESSAGE("Pointer is not set");
   }

   MoFEMErrorCode doWork(int side, EntityType type,
                         DataForcesAndSourcesCore::EntData &data) {
     MoFEMFunctionBegin;
     const int nb_integration_points = getGaussPts().size2();
     if (type == zeroType && side == zeroSide) {
       dataPtr->resize(Tensor_Dim, nb_integration_points, false);
       dataPtr->clear();
     }
     const int nb_dofs = data.getFieldData().size();
     if (!nb_dofs)
       MoFEMFunctionReturnHot(0);

     MatrixDouble curl_mat;

     const int nb_base_functions = data.getN().size2() / Tensor_Dim;
     FTensor::Index<'i', Tensor_Dim> i;
     FTensor::Index<'j', Tensor_Dim> j;
     FTensor::Index<'k', Tensor_Dim> k;
     auto t_n_diff_hcurl = data.getFTensor2DiffN<Tensor_Dim, Tensor_Dim>();
     auto t_data = getFTensor1FromMat<Tensor_Dim>(*dataPtr);
     for (int gg = 0; gg != nb_integration_points; ++gg) {

       // // get curl of base functions
       // CHKERR getCurlOfHCurlBaseFunctions(side, type, data, gg, curl_mat);
       // FTensor::Tensor1<double *, 3> t_base_curl(
       //     &curl_mat(0, HVEC0), &curl_mat(0, HVEC1), &curl_mat(0, HVEC2), 3);

       auto t_dof = data.getFTensor0FieldData();
       int bb = 0;
       for (; bb != nb_dofs; ++bb) {

         // FTensor::Tensor1<double, 3> t_test;
         // t_test(k) = levi_civita(j, i, k) * t_n_diff_hcurl(i, j);
         // t_base_curl(k) -= t_test(k);
         // std::cerr << "error: " << t_base_curl(0) << " " << t_base_curl(1) <<
         // " "
         //           << t_base_curl(2) << std::endl;
         // ++t_base_curl;

         t_data(k) += t_dof * (levi_civita(j, i, k) * t_n_diff_hcurl(i, j));
         ++t_n_diff_hcurl;
         ++t_dof;
       }

       for (; bb != nb_base_functions; ++bb)
         ++t_n_diff_hcurl;
       ++t_data;
     }

     MoFEMFunctionReturn(0);
   }
 };

 /**
  * @brief Calculate tenor field using vectorial base, i.e. Hdiv/Hcurl
  * \ingroup mofem_forces_and_sources_user_data_operators
  *
  * @tparam Tensor_Dim0 rank of the filed
  * @tparam Tensor_Dim1 dimension of space
  */
 template <int Tensor_Dim0, int Tensor_Dim1>
 struct OpCalculateHVecTensorField
     : public ForcesAndSourcesCore::UserDataOperator {

   boost::shared_ptr<MatrixDouble> dataPtr;
   const EntityHandle zeroType;
   const int zeroSide;

   OpCalculateHVecTensorField(const std::string field_name,
                              boost::shared_ptr<MatrixDouble> &data_ptr,
                              const EntityType zero_type = MBEDGE,
                              const int zero_side = 0)
       : ForcesAndSourcesCore::UserDataOperator(
             field_name, ForcesAndSourcesCore::UserDataOperator::OPROW),
         dataPtr(data_ptr), zeroType(zero_type), zeroSide(zero_side) {
     if (!dataPtr)
       THROW_MESSAGE("Pointer is not set");
   }

   MoFEMErrorCode doWork(int side, EntityType type,
                         DataForcesAndSourcesCore::EntData &data) {
     MoFEMFunctionBegin;
     const int nb_integration_points = getGaussPts().size2();
     if (type == zeroType && side == zeroSide) {
       dataPtr->resize(Tensor_Dim0 * Tensor_Dim1, nb_integration_points, false);
       dataPtr->clear();
     }
     const int nb_dofs = data.getFieldData().size();
     if (!nb_dofs)
       MoFEMFunctionReturnHot(0);
     const int nb_base_functions = data.getN().size2() / Tensor_Dim1;
     FTensor::Index<'i', Tensor_Dim0> i;
     FTensor::Index<'j', Tensor_Dim1> j;
     auto t_n_hvec = data.getFTensor1N<Tensor_Dim1>();
     auto t_data = getFTensor2FromMat<Tensor_Dim0, Tensor_Dim1>(*dataPtr);
     for (int gg = 0; gg != nb_integration_points; ++gg) {
       auto t_dof = data.getFTensor1FieldData<Tensor_Dim0>();
       int bb = 0;
       for (; bb != nb_dofs / Tensor_Dim0; ++bb) {
         t_data(i, j) += t_dof(i) * t_n_hvec(j);
         ++t_n_hvec;
         ++t_dof;
       }
       for (; bb != nb_base_functions; ++bb)
         ++t_n_hvec;
       ++t_data;
     }
     MoFEMFunctionReturn(0);
   }
 };

 /**
  * @brief Calculate tenor field using vectorial base, i.e. Hdiv/Hcurl
  * \ingroup mofem_forces_and_sources_user_data_operators
  *
  * @tparam Tensor_Dim0 rank of the filed
  * @tparam Tensor_Dim1 dimension of space
  */
 template <int Tensor_Dim0, int Tensor_Dim1>
 struct OpCalculateHTensorTensorField
     : public ForcesAndSourcesCore::UserDataOperator {

   boost::shared_ptr<MatrixDouble> dataPtr;
   const EntityHandle zeroType;
   const int zeroSide;

   OpCalculateHTensorTensorField(const std::string field_name,
                                 boost::shared_ptr<MatrixDouble> &data_ptr,
                                 const EntityType zero_type = MBEDGE,
                                 const int zero_side = 0)
       : ForcesAndSourcesCore::UserDataOperator(
             field_name, ForcesAndSourcesCore::UserDataOperator::OPROW),
         dataPtr(data_ptr), zeroType(zero_type), zeroSide(zero_side) {
     if (!dataPtr)
       THROW_MESSAGE("Pointer is not set");
   }

   MoFEMErrorCode doWork(int side, EntityType type,
                         DataForcesAndSourcesCore::EntData &data) {
     MoFEMFunctionBegin;
     const int nb_integration_points = getGaussPts().size2();
     if (type == zeroType && side == zeroSide) {
       dataPtr->resize(Tensor_Dim0 * Tensor_Dim1, nb_integration_points, false);
       dataPtr->clear();
     }
     const int nb_dofs = data.getFieldData().size();
     if (!nb_dofs)
       MoFEMFunctionReturnHot(0);
     const int nb_base_functions =
         data.getN().size2() / (Tensor_Dim0 * Tensor_Dim1);
     FTensor::Index<'i', Tensor_Dim0> i;
     FTensor::Index<'j', Tensor_Dim1> j;
     auto t_n_hten = data.getFTensor2N<Tensor_Dim0, Tensor_Dim1>();
     auto t_data = getFTensor2FromMat<Tensor_Dim0, Tensor_Dim1>(*dataPtr);
     for (int gg = 0; gg != nb_integration_points; ++gg) {
       auto t_dof = data.getFTensor0FieldData();
       int bb = 0;
       for (; bb != nb_dofs; ++bb) {
         t_data(i, j) += t_dof * t_n_hten(i, j);
         ++t_n_hten;
         ++t_dof;
       }
       for (; bb != nb_base_functions; ++bb)
         ++t_n_hten;
       ++t_data;
     }
     MoFEMFunctionReturn(0);
   }
 };

 /**
  * @brief Calculate divergence of tonsorial field using vectorial base
  * \ingroup mofem_forces_and_sources_user_data_operators
  *
  * @tparam Tensor_Dim0 rank of the field
  * @tparam Tensor_Dim1 dimension of space
  */
 template <int Tensor_Dim0, int Tensor_Dim1>
 struct OpCalculateHVecTensorDivergence
     : public ForcesAndSourcesCore::UserDataOperator {

   boost::shared_ptr<MatrixDouble> dataPtr;
   const EntityHandle zeroType;
   const int zeroSide;

   OpCalculateHVecTensorDivergence(const std::string field_name,
                                   boost::shared_ptr<MatrixDouble> &data_ptr,
                                   const EntityType zero_type = MBEDGE,
                                   const int zero_side = 0)
       : ForcesAndSourcesCore::UserDataOperator(
             field_name, ForcesAndSourcesCore::UserDataOperator::OPROW),
         dataPtr(data_ptr), zeroType(zero_type), zeroSide(zero_side) {
     if (!dataPtr)
       THROW_MESSAGE("Pointer is not set");
   }

   MoFEMErrorCode doWork(int side, EntityType type,
                         DataForcesAndSourcesCore::EntData &data) {
     MoFEMFunctionBegin;
     const int nb_integration_points = getGaussPts().size2();
     if (type == zeroType && side == 0) {
       dataPtr->resize(Tensor_Dim0, nb_integration_points, false);
       dataPtr->clear();
     }
     const int nb_dofs = data.getFieldData().size();
     if (!nb_dofs)
       MoFEMFunctionReturnHot(0);
     const int nb_base_functions = data.getN().size2() / Tensor_Dim1;
     FTensor::Index<'i', Tensor_Dim0> i;
     FTensor::Index<'j', Tensor_Dim1> j;
     auto t_n_diff_hvec = data.getFTensor2DiffN<Tensor_Dim1, Tensor_Dim1>();
     auto t_data = getFTensor1FromMat<Tensor_Dim0>(*dataPtr);
     for (int gg = 0; gg != nb_integration_points; ++gg) {
       auto t_dof = data.getFTensor1FieldData<Tensor_Dim0>();
       int bb = 0;
       for (; bb != nb_dofs / Tensor_Dim0; ++bb) {
         double div = t_n_diff_hvec(j, j);
         t_data(i) += t_dof(i) * div;
         ++t_n_diff_hvec;
         ++t_dof;
       }
       for (; bb != nb_base_functions; ++bb)
         ++t_n_diff_hvec;
       ++t_data;
     }
     MoFEMFunctionReturn(0);
   }
 };

 // Face opeartors

 /** \brief Calculate jacobian for face element

   It is assumed that face element is XY plane. Applied
   only for 2d problems.

   \todo Generalize function for arbitrary face orientation in 3d space

   \ingroup mofem_forces_and_sources_tri_element

 */
 struct OpCalculateJacForFace
     : public FaceElementForcesAndSourcesCoreBase::UserDataOperator {
   MatrixDouble &jac;

   OpCalculateJacForFace(MatrixDouble &jac)
       : FaceElementForcesAndSourcesCoreBase::UserDataOperator(H1), jac(jac) {}

   MoFEMErrorCode doWork(int side, EntityType type,
                         DataForcesAndSourcesCore::EntData &data);
 };

 /** \brief Calculate inverse of jacobian for face element

   It is assumed that face element is XY plane. Applied
   only for 2d problems.

   \todo Generalize function for arbitrary face orientation in 3d space

   \ingroup mofem_forces_and_sources_tri_element

 */
 struct OpCalculateInvJacForFace
     : public FaceElementForcesAndSourcesCoreBase::UserDataOperator {
   MatrixDouble &invJac;

   OpCalculateInvJacForFace(MatrixDouble &inv_jac)
       : FaceElementForcesAndSourcesCoreBase::UserDataOperator(H1),
         invJac(inv_jac) {}

   MoFEMErrorCode doWork(int side, EntityType type,
                         DataForcesAndSourcesCore::EntData &data);
 };

 /** \brief Transform local reference derivatives of shape functions to global
 derivatives

 \ingroup mofem_forces_and_sources_tri_element

 */
 struct OpSetInvJacH1ForFace
     : public FaceElementForcesAndSourcesCoreBase::UserDataOperator {

   OpSetInvJacH1ForFace(MatrixDouble &inv_jac)
       : FaceElementForcesAndSourcesCoreBase::UserDataOperator(H1),
         invJac(inv_jac) {}

   MoFEMErrorCode doWork(int side, EntityType type,
                         DataForcesAndSourcesCore::EntData &data);

 private:
   MatrixDouble &invJac;
   MatrixDouble diffNinvJac;
 };

 /**
  * \brief brief Transform local reference derivatives of shape function to
  global derivatives for face

  * \ingroup mofem_forces_and_sources_tri_element
  */
 struct OpSetInvJacHcurlFace
     : public FaceElementForcesAndSourcesCoreBase::UserDataOperator {

   OpSetInvJacHcurlFace(MatrixDouble &inv_jac)
       : FaceElementForcesAndSourcesCoreBase::UserDataOperator(HCURL),
         invJac(inv_jac) {}

   MoFEMErrorCode doWork(int side, EntityType type,
                         DataForcesAndSourcesCore::EntData &data);

 private:
   MatrixDouble &invJac;
   MatrixDouble diffHcurlInvJac;
 };

 /**
  * @brief Make Hdiv space from Hcurl space in 2d
  * @ingroup mofem_forces_and_sources_tri_element
  */
 struct OpMakeHdivFromHcurl
     : public FaceElementForcesAndSourcesCoreBase::UserDataOperator {

   OpMakeHdivFromHcurl()
       : FaceElementForcesAndSourcesCoreBase::UserDataOperator(HCURL) {}

   MoFEMErrorCode doWork(int side, EntityType type,
                         DataForcesAndSourcesCore::EntData &data);
 };

 /** \brief Apply contravariant (Piola) transfer to Hdiv space on face
  *
  * \note Hdiv space is generated by Hcurl space in 2d.
  *
  * Contravariant Piola transformation
  * \f[
  * \psi_i|_t = \frac{1}{\textrm{det}(J)}J_{ij}\hat{\psi}_j\\
  * \left.\frac{\partial \psi_i}{\partial \xi_j}\right|_t
  * =
  * \frac{1}{\textrm{det}(J)}J_{ik}\frac{\partial \hat{\psi}_k}{\partial \xi_j}
  * \f]
  *
  * \ingroup mofem_forces_and_sources
  *
   */
 struct OpSetContravariantPiolaTransformFace
     : public FaceElementForcesAndSourcesCoreBase::UserDataOperator {

   OpSetContravariantPiolaTransformFace(MatrixDouble &jac)
       : FaceElementForcesAndSourcesCoreBase::UserDataOperator(HCURL), jAc(jac) {
   }

   MatrixDouble piolaN;
   MatrixDouble piolaDiffN;

   MoFEMErrorCode doWork(int side, EntityType type,
                         DataForcesAndSourcesCore::EntData &data);

   private:
     MatrixDouble &jAc;
 };

 // Edge

 struct OpSetContrariantPiolaTransformOnEdge
     : public EdgeElementForcesAndSourcesCoreBase::UserDataOperator {

   OpSetContrariantPiolaTransformOnEdge()
       : EdgeElementForcesAndSourcesCoreBase::UserDataOperator(HCURL) {}

   MoFEMErrorCode doWork(int side, EntityType type,
                         DataForcesAndSourcesCore::EntData &data);
 };

 // Fat prims

 /** \brief Calculate inverse of jacobian for face element

   It is assumed that face element is XY plane. Applied
   only for 2d problems.

   FIXME Generalize function for arbitrary face orientation in 3d space
   FIXME Calculate to Jacobins for two faces

   \ingroup mofem_forces_and_sources_prism_element

 */
 struct OpCalculateInvJacForFatPrism
     : public FatPrismElementForcesAndSourcesCore::UserDataOperator {

   OpCalculateInvJacForFatPrism(boost::shared_ptr<MatrixDouble> inv_jac_ptr)
       : FatPrismElementForcesAndSourcesCore::UserDataOperator(H1),
         invJacPtr(inv_jac_ptr), invJac(*invJacPtr) {}

   OpCalculateInvJacForFatPrism(MatrixDouble &inv_jac)
       : FatPrismElementForcesAndSourcesCore::UserDataOperator(H1),
         invJac(inv_jac) {}
   MoFEMErrorCode doWork(int side, EntityType type,
                         DataForcesAndSourcesCore::EntData &data);

   private:
     const boost::shared_ptr<MatrixDouble> invJacPtr;
     MatrixDouble &invJac;
 };

 /** \brief Transform local reference derivatives of shape functions to global
 derivatives

 FIXME Generalize to curved shapes
 FIXME Generalize to case that top and bottom face has different shape

 \ingroup mofem_forces_and_sources_prism_element

 */
 struct OpSetInvJacH1ForFatPrism
     : public FatPrismElementForcesAndSourcesCore::UserDataOperator {

   OpSetInvJacH1ForFatPrism(boost::shared_ptr<MatrixDouble> inv_jac_ptr)
       : FatPrismElementForcesAndSourcesCore::UserDataOperator(H1),
         invJacPtr(inv_jac_ptr), invJac(*invJacPtr) {}

   OpSetInvJacH1ForFatPrism(MatrixDouble &inv_jac)
       : FatPrismElementForcesAndSourcesCore::UserDataOperator(H1),
         invJac(inv_jac) {}

   MoFEMErrorCode doWork(int side, EntityType type,
                         DataForcesAndSourcesCore::EntData &data);

   private:
     const boost::shared_ptr<MatrixDouble> invJacPtr;
     MatrixDouble &invJac;
     MatrixDouble diffNinvJac;

 };

 // Flat prism

 /** \brief Calculate inverse of jacobian for face element

   It is assumed that face element is XY plane. Applied
   only for 2d problems.

   FIXME Generalize function for arbitrary face orientation in 3d space
   FIXME Calculate to Jacobins for two faces

   \ingroup mofem_forces_and_sources_prism_element

 */
 struct OpCalculateInvJacForFlatPrism
     : public FlatPrismElementForcesAndSourcesCore::UserDataOperator {

   MatrixDouble &invJacF3;
   OpCalculateInvJacForFlatPrism(MatrixDouble &inv_jac_f3)
       : FlatPrismElementForcesAndSourcesCore::UserDataOperator(H1),
         invJacF3(inv_jac_f3) {}
   MoFEMErrorCode doWork(int side, EntityType type,
                         DataForcesAndSourcesCore::EntData &data);
 };

 /** \brief Transform local reference derivatives of shape functions to global
 derivatives

 FIXME Generalize to curved shapes
 FIXME Generalize to case that top and bottom face has different shape

 \ingroup mofem_forces_and_sources_prism_element

 */
 struct OpSetInvJacH1ForFlatPrism
     : public FlatPrismElementForcesAndSourcesCore::UserDataOperator {
   MatrixDouble &invJacF3;
   OpSetInvJacH1ForFlatPrism(MatrixDouble &inv_jac_f3)
       : FlatPrismElementForcesAndSourcesCore::UserDataOperator(H1),
         invJacF3(inv_jac_f3) {}

   MatrixDouble diffNinvJac;
   MoFEMErrorCode doWork(int side, EntityType type,
                         DataForcesAndSourcesCore::EntData &data);
 };

 } // namespace MoFEM

 #endif // __USER_DATA_OPERATORS_HPP__

 /**
  * \defgroup mofem_forces_and_sources_user_data_operators Users Operators
  *
  * \brief Classes and functions used to evaluate fields at integration pts,
  *jacobians, etc..
  *
  * \ingroup mofem_forces_and_sources
  **/
MoFEM::OpCalculateScalarFieldValues::OpCalculateScalarFieldValues
OpCalculateScalarFieldValues(const std::string field_name, boost::shared_ptr< VectorDouble > &data_ptr, const EntityType zero_type=MBVERTEX)
Definition: UserDataOperators.hpp:83

MoFEM::OpCalculateScalarFieldValuesDot::OpCalculateScalarFieldValuesDot
OpCalculateScalarFieldValuesDot(const std::string field_name, boost::shared_ptr< VectorDouble > &data_ptr, const EntityType zero_at_type=MBVERTEX)
Definition: UserDataOperators.hpp:144

MoFEM::OpCalculateTensor2FieldValuesDot::getFTensorDotData
auto getFTensorDotData()
Definition: UserDataOperators.hpp:569

MoFEM::OpCalculateTensor2SymmetricFieldValuesDot::zeroSide
const int zeroSide
Definition: UserDataOperators.hpp:720

MoFEM::OpCalculateScalarFieldGradient_General< Tensor_Dim, double, ublas::row_major, DoubleAllocator >::OpCalculateScalarFieldGradient_General
OpCalculateScalarFieldGradient_General(const std::string field_name, boost::shared_ptr< MatrixDouble > &data_ptr, const EntityType zero_type=MBVERTEX)
Definition: UserDataOperators.hpp:830

MoFEM::OpCalculateHdivVectorDivergence
Calculate divergence of vector field.
Definition: UserDataOperators.hpp:1264

MoFEM::OpCalculateVectorFieldGradientDot
Get field gradients time derivative at integration pts for scalar filed rank 0, i....
Definition: UserDataOperators.hpp:1036

MoFEM::ForcesAndSourcesCore::UserDataOperator::getGaussPts
MatrixDouble & getGaussPts()
matrix of integration (Gauss) points for Volume Element
Definition: ForcesAndSourcesCore.hpp:1021

MoFEM::OpCalculateHTensorTensorField::dataPtr
boost::shared_ptr< MatrixDouble > dataPtr
Definition: UserDataOperators.hpp:1463

MoFEM::OpCalculateVectorFieldValuesDot
Get time direvatives of values at integration pts for tensor filed rank 1, i.e. vector field.
Definition: UserDataOperators.hpp:352

MoFEM::getFTensor0FromVec
static FTensor::Tensor0< FTensor::PackPtr< double *, 1 > > getFTensor0FromVec(ublas::vector< T, A > &data)
Get tensor rank 0 (scalar) form data vector.
Definition: Templates.hpp:141

MoFEM::OpCalculateVectorFieldValues_General::zeroType
const EntityHandle zeroType
Definition: UserDataOperators.hpp:218

MoFEM::OpCalculateHdivVectorDivergence::zeroType
const EntityHandle zeroType
Definition: UserDataOperators.hpp:1268

MoFEM::OpSetInvJacH1ForFatPrism::doWork
MoFEMErrorCode doWork(int side, EntityType type, DataForcesAndSourcesCore::EntData &data)
Operator for linear form, usually to calculate values on right hand side.
Definition: UserDataOperators.cpp:578

FTensor::Index
Definition: Index.hpp:23

MoFEM::OpCalculateHdivVectorDivergence::zeroSide
const int zeroSide
Definition: UserDataOperators.hpp:1269

MoFEM::DataForcesAndSourcesCore::EntData::getFTensor2SymmetricFieldData
FTensor::Tensor2_symmetric< FTensor::PackPtr< double *,(Tensor_Dim *(Tensor_Dim+1))/2 >, Tensor_Dim > getFTensor2SymmetricFieldData()
Return symmetric FTensor rank 2, i.e. matrix from filed data coeffinects.
Definition: DataStructures.hpp:1234

FTensor::Tensor1
Definition: Tensor1_value.hpp:8

MoFEM::OpSetInvJacH1ForFlatPrism::invJacF3
MatrixDouble & invJacF3
Definition: UserDataOperators.hpp:1811

MoFEM::OpCalculateHVecTensorDivergence::doWork
MoFEMErrorCode doWork(int side, EntityType type, DataForcesAndSourcesCore::EntData &data)
Operator for linear form, usually to calculate values on right hand side.
Definition: UserDataOperators.hpp:1537

MoFEM::OpSetContrariantPiolaTransformOnEdge::doWork
MoFEMErrorCode doWork(int side, EntityType type, DataForcesAndSourcesCore::EntData &data)
Operator for linear form, usually to calculate values on right hand side.
Definition: UserDataOperators.cpp:447

MoFEM::OpMakeHdivFromHcurl::OpMakeHdivFromHcurl
OpMakeHdivFromHcurl()
Definition: UserDataOperators.hpp:1664

MoFEM::OpCalculateTensor2SymmetricFieldValuesDot::getFTensorDotData
auto getFTensorDotData()
Definition: UserDataOperators.hpp:723

MOFEM_NOT_IMPLEMENTED
Definition: definitions.h:123

MoFEM::OpCalculateVectorFieldValues_General
Calculate field values for tenor field rank 1, i.e. vector field.
Definition: UserDataOperators.hpp:214

MoFEM::OpCalculateTensor2FieldValuesDot::OpCalculateTensor2FieldValuesDot
OpCalculateTensor2FieldValuesDot(const std::string field_name, boost::shared_ptr< MatrixDouble > &data_ptr, const EntityType zero_at_type=MBVERTEX)
Definition: UserDataOperators.hpp:573

MoFEM::OpCalculateVectorFieldValues::OpCalculateVectorFieldValues
OpCalculateVectorFieldValues(const std::string field_name, boost::shared_ptr< MatrixDouble > &data_ptr, const EntityType zero_type=MBVERTEX)
Definition: UserDataOperators.hpp:338

MoFEM::OpCalculateHVecTensorDivergence::zeroSide
const int zeroSide
Definition: UserDataOperators.hpp:1524

MoFEM::OpCalculateTensor2FieldValues::OpCalculateTensor2FieldValues
OpCalculateTensor2FieldValues(const std::string field_name, boost::shared_ptr< MatrixDouble > &data_ptr, const EntityType zero_type=MBVERTEX)
Definition: UserDataOperators.hpp:547

MoFEM::OpCalculateTensor2FieldValues_General< Tensor_Dim0, Tensor_Dim1, double, ublas::row_major, DoubleAllocator >::dataPtr
boost::shared_ptr< ublas::matrix< double, ublas::row_major, DoubleAllocator > > dataPtr
Definition: UserDataOperators.hpp:477

MoFEMFunctionBeginHot
#define MoFEMFunctionBeginHot
First executable line of each MoFEM function, used for error handling. Final line of MoFEM functions ...
Definition: definitions.h:506

MoFEM::OpSetContravariantPiolaTransformFace::piolaN
MatrixDouble piolaN
Definition: UserDataOperators.hpp:1693

MoFEM::OpSetInvJacH1ForFatPrism::invJacPtr
const boost::shared_ptr< MatrixDouble > invJacPtr
Definition: UserDataOperators.hpp:1770

MoFEM::OpCalculateInvJacForFlatPrism::OpCalculateInvJacForFlatPrism
OpCalculateInvJacForFlatPrism(MatrixDouble &inv_jac_f3)
Definition: UserDataOperators.hpp:1793

MoFEM::OpCalculateVectorFieldValues_General::dataPtr
boost::shared_ptr< ublas::matrix< T, L, A > > dataPtr
Definition: UserDataOperators.hpp:217

MoFEM::OpCalculateHVecTensorField
Calculate tenor field using vectorial base, i.e. Hdiv/Hcurl.
Definition: UserDataOperators.hpp:1402

MoFEM::OpCalculateVectorFieldGradient
Get field gradients at integration pts for scalar filed rank 0, i.e. vector field.
Definition: UserDataOperators.hpp:1017

MoFEM::OpCalculateScalarFieldGradient_General
Evaluate field gradient values for scalar field, i.e. gradient is tensor rank 1 (vector)
Definition: UserDataOperators.hpp:810

T

MoFEM::Types::MatrixDouble
ublas::matrix< double, ublas::row_major, DoubleAllocator > MatrixDouble
Definition: Types.hpp:74

MoFEMFunctionReturn
#define MoFEMFunctionReturn(a)
Last executable line of each PETSc function used for error handling. Replaces return()
Definition: definitions.h:482

MoFEM::OpCalculateTensor2SymmetricFieldValuesDot::dataPtr
boost::shared_ptr< MatrixDouble > dataPtr
Definition: UserDataOperators.hpp:718

MoFEM::OpSetContravariantPiolaTransformFace::OpSetContravariantPiolaTransformFace
OpSetContravariantPiolaTransformFace(MatrixDouble &jac)
Definition: UserDataOperators.hpp:1689

double

MoFEM::OpCalculateTensor2FieldValuesDot::zeroAtType
EntityType zeroAtType
Zero values at Gauss point at this type.
Definition: UserDataOperators.hpp:566

MoFEM::OpCalculateTensor2FieldValues_General::dataPtr
boost::shared_ptr< ublas::matrix< T, L, A > > dataPtr
Definition: UserDataOperators.hpp:441

MoFEM::OpCalculateHdivVectorDivergence::doWork
MoFEMErrorCode doWork(int side, EntityType type, DataForcesAndSourcesCore::EntData &data)
Operator for linear form, usually to calculate values on right hand side.
Definition: UserDataOperators.hpp:1282

OpPlasticTools::I
FTensor::Index< 'I', 3 > I
Definition: PlasticOps.hpp:35

MoFEM::OpCalculateHVecTensorField::OpCalculateHVecTensorField
OpCalculateHVecTensorField(const std::string field_name, boost::shared_ptr< MatrixDouble > &data_ptr, const EntityType zero_type=MBEDGE, const int zero_side=0)
Definition: UserDataOperators.hpp:1409

MoFEM::DataForcesAndSourcesCore::EntData::getFTensor1DiffN
FTensor::Tensor1< double *, Tensor_Dim > getFTensor1DiffN(const FieldApproximationBase base)
Get derivatives of base functions.
Definition: DataStructures.cpp:415

MoFEM::OpSetInvJacH1ForFatPrism::OpSetInvJacH1ForFatPrism
OpSetInvJacH1ForFatPrism(boost::shared_ptr< MatrixDouble > inv_jac_ptr)
Definition: UserDataOperators.hpp:1758

MoFEM::DataForcesAndSourcesCore::EntData::getLocalIndices
const VectorInt & getLocalIndices() const
get local indices of dofs on entity
Definition: DataStructures.hpp:1163

MoFEM::OpCalculateHVecTensorDivergence::OpCalculateHVecTensorDivergence
OpCalculateHVecTensorDivergence(const std::string field_name, boost::shared_ptr< MatrixDouble > &data_ptr, const EntityType zero_type=MBEDGE, const int zero_side=0)
Definition: UserDataOperators.hpp:1526

MoFEM::OpCalculateVectorFieldGradientDot::dataPtr
boost::shared_ptr< MatrixDouble > & dataPtr
Data computed into this matrix.
Definition: UserDataOperators.hpp:1039

THROW_MESSAGE
#define THROW_MESSAGE(a)
Throw MoFEM exception.
Definition: definitions.h:625

MoFEM::OpCalculateTensor2SymmetricFieldValuesDot::dotVector
VectorDouble dotVector
Definition: UserDataOperators.hpp:721

MoFEM::OpCalculateHcurlVectorCurl::OpCalculateHcurlVectorCurl
OpCalculateHcurlVectorCurl(const std::string field_name, boost::shared_ptr< MatrixDouble > &data_ptr, const EntityType zero_type=MBEDGE, const int zero_side=0)
Definition: UserDataOperators.hpp:1330

MoFEM::OpCalculateHTensorTensorField::zeroType
const EntityHandle zeroType
Definition: UserDataOperators.hpp:1464

MoFEMFunctionReturnHot
#define MoFEMFunctionReturnHot(a)
Last executable line of each PETSc function used for error handling. Replaces return()
Definition: definitions.h:513

MoFEM::OpSetInvJacH1ForFatPrism::invJac
MatrixDouble & invJac
Definition: UserDataOperators.hpp:1771

MoFEM::ForcesAndSourcesCore::UserDataOperator::UserDataOperator
UserDataOperator(const FieldSpace space, const char type=OPLAST, const bool symm=true)
Definition: ForcesAndSourcesCore.cpp:1405

MoFEM::OpCalculateInvJacForFatPrism::invJac
MatrixDouble & invJac
Definition: UserDataOperators.hpp:1743

MoFEM::OpCalculateTensor2FieldValues_General< Tensor_Dim0, Tensor_Dim1, double, ublas::row_major, DoubleAllocator >::OpCalculateTensor2FieldValues_General
OpCalculateTensor2FieldValues_General(const std::string field_name, boost::shared_ptr< ublas::matrix< double, ublas::row_major, DoubleAllocator >> &data_ptr, const EntityType zero_type=MBVERTEX)
Definition: UserDataOperators.hpp:480

MoFEM::OpCalculateVectorFieldValues
Get values at integration pts for tensor filed rank 1, i.e. vector field.
Definition: UserDataOperators.hpp:334

MoFEM::OpCalculateHTensorTensorField::doWork
MoFEMErrorCode doWork(int side, EntityType type, DataForcesAndSourcesCore::EntData &data)
Operator for linear form, usually to calculate values on right hand side.
Definition: UserDataOperators.hpp:1478

MoFEM::OpCalculateHVecTensorDivergence::zeroType
const EntityHandle zeroType
Definition: UserDataOperators.hpp:1523

MoFEM
implementation of Data Operators for Forces and Sources
Definition: Common.hpp:21

MoFEM::DataForcesAndSourcesCore::EntData::getFTensor0FieldData
FTensor::Tensor0< FTensor::PackPtr< double *, 1 > > getFTensor0FieldData()
Resturn scalar files as a FTensor of rank 0.
Definition: DataStructures.cpp:402

OpPlasticTools::J
FTensor::Index< 'J', 3 > J
Definition: PlasticOps.hpp:36

MoFEM::OpCalculateVectorFieldValuesDot::OpCalculateVectorFieldValuesDot
OpCalculateVectorFieldValuesDot(const std::string field_name, boost::shared_ptr< MatrixDouble > &data_ptr, const EntityType zero_at_type=MBVERTEX)
Definition: UserDataOperators.hpp:363

MoFEM::OpCalculateVectorFieldValuesDot::dataPtr
boost::shared_ptr< MatrixDouble > dataPtr
Definition: UserDataOperators.hpp:355

MoFEM::OpCalculateVectorFieldGradientDot::getFTensorDotData
auto getFTensorDotData()
Definition: UserDataOperators.hpp:1043

EntityHandle

MoFEM::OpSetInvJacH1ForFlatPrism::doWork
MoFEMErrorCode doWork(int side, EntityType type, DataForcesAndSourcesCore::EntData &data)
Operator for linear form, usually to calculate values on right hand side.
Definition: UserDataOperators.cpp:652

MoFEM::OpCalculateScalarFieldValuesDot::dotVector
VectorDouble dotVector
Definition: UserDataOperators.hpp:142

MoFEM::OpCalculateVectorFieldGradient_General
Evaluate field gradient values for vector field, i.e. gradient is tensor rank 2.
Definition: UserDataOperators.hpp:922

MoFEM::OpCalculateHdivVectorField_General::doWork
MoFEMErrorCode doWork(int side, EntityType type, DataForcesAndSourcesCore::EntData &data)
calculate values of vector field at integration points
Definition: UserDataOperators.hpp:1162

MoFEM::OpCalculateVectorFieldGradientDot::zeroAtType
EntityType zeroAtType
Zero values at Gauss point at this type.
Definition: UserDataOperators.hpp:1040

MoFEM::OpCalculateHVecTensorField::dataPtr
boost::shared_ptr< MatrixDouble > dataPtr
Definition: UserDataOperators.hpp:1405

MoFEM::FlatPrismElementForcesAndSourcesCore::UserDataOperator
default operator for Flat Prism element
Definition: FlatPrismElementForcesAndSourcesCore.hpp:46

MoFEM::OpCalculateHcurlVectorCurl
Calculate curl of vector field.
Definition: UserDataOperators.hpp:1323

MoFEM::OpCalculateVectorFieldValues_General::doWork
MoFEMErrorCode doWork(int side, EntityType type, DataForcesAndSourcesCore::EntData &data)
calculate values of vector field at integration points
Definition: UserDataOperators.hpp:244

MoFEM::EdgeElementForcesAndSourcesCoreBase
Edge finite elementUser is implementing own operator at Gauss points level, by own object derived fro...
Definition: EdgeElementForcesAndSourcesCore.hpp:44

MoFEM::OpCalculateHdivVectorField::OpCalculateHdivVectorField
OpCalculateHdivVectorField(const std::string field_name, boost::shared_ptr< MatrixDouble > &data_ptr, const EntityType zero_type=MBEDGE, const int zero_side=0)
Definition: UserDataOperators.hpp:1248

MoFEM::ForcesAndSourcesCore::UserDataOperator::getFEMethod
const FEMethod * getFEMethod() const
Return raw pointer to Finite Element Method object.
Definition: ForcesAndSourcesCore.hpp:911

convert.type
type
Definition: convert.py:53

MoFEM::OpSetInvJacHcurlFace::OpSetInvJacHcurlFace
OpSetInvJacHcurlFace(MatrixDouble &inv_jac)
Definition: UserDataOperators.hpp:1645

MoFEM::OpCalculateHcurlVectorCurl::doWork
MoFEMErrorCode doWork(int side, EntityType type, DataForcesAndSourcesCore::EntData &data)
Operator for linear form, usually to calculate values on right hand side.
Definition: UserDataOperators.hpp:1341

MoFEM::OpSetInvJacH1ForFace::doWork
MoFEMErrorCode doWork(int side, EntityType type, DataForcesAndSourcesCore::EntData &data)
Operator for linear form, usually to calculate values on right hand side.
Definition: UserDataOperators.cpp:208

MoFEM::OpCalculateTensor2FieldValues_General< Tensor_Dim0, Tensor_Dim1, double, ublas::row_major, DoubleAllocator >::zeroType
const EntityHandle zeroType
Definition: UserDataOperators.hpp:478

MoFEM::OpCalculateHcurlVectorCurl::dataPtr
boost::shared_ptr< MatrixDouble > dataPtr
Definition: UserDataOperators.hpp:1326

MoFEM::OpSetInvJacH1ForFace::diffNinvJac
MatrixDouble diffNinvJac
Definition: UserDataOperators.hpp:1633

MoFEM::OpSetInvJacH1ForFatPrism::diffNinvJac
MatrixDouble diffNinvJac
Definition: UserDataOperators.hpp:1772

MoFEM::OpSetInvJacH1ForFlatPrism::diffNinvJac
MatrixDouble diffNinvJac
Definition: UserDataOperators.hpp:1816

MoFEM::OpCalculateVectorFieldGradient::OpCalculateVectorFieldGradient
OpCalculateVectorFieldGradient(const std::string field_name, boost::shared_ptr< MatrixDouble > &data_ptr, const EntityType zero_type=MBVERTEX)
Definition: UserDataOperators.hpp:1021

MoFEM::OpCalculateHdivVectorField_General
Get vector field for H-div approximation.
Definition: UserDataOperators.hpp:1132

MoFEM::OpSetInvJacH1ForFatPrism::OpSetInvJacH1ForFatPrism
OpSetInvJacH1ForFatPrism(MatrixDouble &inv_jac)
Definition: UserDataOperators.hpp:1762

MoFEM::DataForcesAndSourcesCore::EntData::getFTensor1FieldData
FTensor::Tensor1< FTensor::PackPtr< double *, Tensor_Dim >, Tensor_Dim > getFTensor1FieldData()
Return FTensor of rank 1, i.e. vector from filed data coeffinects.
Definition: DataStructures.hpp:1215

MoFEM::OpCalculateScalarFieldValuesDot::zeroAtType
const EntityHandle zeroAtType
Definition: UserDataOperators.hpp:141

MoFEM::OpSetContravariantPiolaTransformFace::jAc
MatrixDouble & jAc
Definition: UserDataOperators.hpp:1700

MoFEM::OpCalculateHVecTensorField::zeroSide
const int zeroSide
Definition: UserDataOperators.hpp:1407

MoFEM::OpCalculateJacForFace::OpCalculateJacForFace
OpCalculateJacForFace(MatrixDouble &jac)
Definition: UserDataOperators.hpp:1586

MoFEM::OpCalculateInvJacForFace
Calculate inverse of jacobian for face element.
Definition: UserDataOperators.hpp:1603

MoFEM::DataForcesAndSourcesCore::EntData::getFTensor2N
FTensor::Tensor2< FTensor::PackPtr< double *, Tensor_Dim0 *Tensor_Dim1 >, Tensor_Dim0, Tensor_Dim1 > getFTensor2N(FieldApproximationBase base)
Get base functions for Hdiv/Hcurl spaces.
Definition: DataStructures.cpp:694

MoFEM::OpCalculateVectorFieldValuesDot::dotVector
VectorDouble dotVector
Definition: UserDataOperators.hpp:357

MoFEM::OpCalculateHdivVectorField_General::zeroSide
const int zeroSide
Definition: UserDataOperators.hpp:1137

MoFEM::OpCalculateInvJacForFatPrism::OpCalculateInvJacForFatPrism
OpCalculateInvJacForFatPrism(boost::shared_ptr< MatrixDouble > inv_jac_ptr)
Definition: UserDataOperators.hpp:1731

MoFEM::FatPrismElementForcesAndSourcesCore::UserDataOperator
default operator for Flat Prism element
Definition: FatPrismElementForcesAndSourcesCore.hpp:66

MoFEM::OpCalculateTensor2SymmetricFieldValues::zeroSide
const int zeroSide
Definition: UserDataOperators.hpp:659

MoFEM::OpSetContravariantPiolaTransformFace::piolaDiffN
MatrixDouble piolaDiffN
Definition: UserDataOperators.hpp:1694

MoFEM::OpCalculateHdivVectorField_General< Tensor_Dim, double, ublas::row_major, DoubleAllocator >::zeroType
const EntityHandle zeroType
Definition: UserDataOperators.hpp:1181

MoFEM::OpCalculateVectorFieldValues_General< Tensor_Dim, double, ublas::row_major, DoubleAllocator >::OpCalculateVectorFieldValues_General
OpCalculateVectorFieldValues_General(const std::string field_name, boost::shared_ptr< MatrixDouble > &data_ptr, const EntityType zero_type=MBVERTEX)
Definition: UserDataOperators.hpp:266

MoFEM::OpCalculateVectorFieldGradient_General< Tensor_Dim0, Tensor_Dim1, double, ublas::row_major, DoubleAllocator >::OpCalculateVectorFieldGradient_General
OpCalculateVectorFieldGradient_General(const std::string field_name, boost::shared_ptr< MatrixDouble > &data_ptr, const EntityType zero_type=MBVERTEX)
Definition: UserDataOperators.hpp:940

MoFEM::OpCalculateHTensorTensorField::OpCalculateHTensorTensorField
OpCalculateHTensorTensorField(const std::string field_name, boost::shared_ptr< MatrixDouble > &data_ptr, const EntityType zero_type=MBEDGE, const int zero_side=0)
Definition: UserDataOperators.hpp:1467

OpElasticTools::k
FTensor::Index< 'k', 2 > k
Definition: ElasticOps.hpp:28

MoFEM::OpCalculateTensor2SymmetricFieldValues::dataPtr
boost::shared_ptr< MatrixDouble > dataPtr
Definition: UserDataOperators.hpp:657

MoFEM::Exceptions::MoFEMErrorCode
PetscErrorCode MoFEMErrorCode
MoFEM/PETSc error code.
Definition: Exceptions.hpp:66

MoFEM::EdgeElementForcesAndSourcesCoreBase::UserDataOperator
default operator for EDGE element
Definition: EdgeElementForcesAndSourcesCore.hpp:52

MoFEM::OpCalculateScalarFieldValuesDot::dataPtr
boost::shared_ptr< VectorDouble > dataPtr
Definition: UserDataOperators.hpp:140

MoFEM::DataForcesAndSourcesCore::EntData::getFTensor2FieldData
FTensor::Tensor2< FTensor::PackPtr< double *, Tensor_Dim0 *Tensor_Dim1 >, Tensor_Dim0, Tensor_Dim1 > getFTensor2FieldData()
Return FTensor rank 2, i.e. matrix from filed data coeffinects.
Definition: DataStructures.hpp:1224

MoFEM::OpCalculateVectorFieldGradientDot::dotVector
VectorDouble dotVector
Keeps temoorary values of time directives.
Definition: UserDataOperators.hpp:1041

MoFEM::OpCalculateVectorFieldValuesDot::zeroAtType
const EntityHandle zeroAtType
Definition: UserDataOperators.hpp:356

MoFEM::OpCalculateInvJacForFatPrism
Calculate inverse of jacobian for face element.
Definition: UserDataOperators.hpp:1728

MoFEM::OpCalculateInvJacForFlatPrism
Calculate inverse of jacobian for face element.
Definition: UserDataOperators.hpp:1789

MoFEM::OpCalculateTensor2FieldValues_General::OpCalculateTensor2FieldValues_General
OpCalculateTensor2FieldValues_General(const std::string field_name, boost::shared_ptr< ublas::matrix< T, L, A >> &data_ptr, const EntityType zero_type=MBVERTEX)
Definition: UserDataOperators.hpp:444

MoFEM::OpCalculateTensor2FieldValues_General::zeroType
const EntityHandle zeroType
Definition: UserDataOperators.hpp:442

MoFEM::OpSetInvJacH1ForFlatPrism::OpSetInvJacH1ForFlatPrism
OpSetInvJacH1ForFlatPrism(MatrixDouble &inv_jac_f3)
Definition: UserDataOperators.hpp:1812

MoFEM::OpCalculateVectorFieldValuesDot::getFTensorDotData
auto getFTensorDotData()
Definition: UserDataOperators.hpp:359

MoFEM::FlatPrismElementForcesAndSourcesCore
FlatPrism finite elementUser is implementing own operator at Gauss points level, by own object derive...
Definition: FlatPrismElementForcesAndSourcesCore.hpp:39

MoFEM::OpSetInvJacHcurlFace::doWork
MoFEMErrorCode doWork(int side, EntityType type, DataForcesAndSourcesCore::EntData &data)
Operator for linear form, usually to calculate values on right hand side.
Definition: UserDataOperators.cpp:276

HCURL
field with continuous tangents
Definition: definitions.h:177

MOFEM_DATA_INCONSISTENCY
Definition: definitions.h:122

MoFEM::OpCalculateHdivVectorField
Get vector field for H-div approximation.
Definition: UserDataOperators.hpp:1244

MoFEM::OpCalculateHVecTensorDivergence
Calculate divergence of tonsorial field using vectorial base.
Definition: UserDataOperators.hpp:1519

MoFEM::OpCalculateHdivVectorField_General::zeroType
const EntityHandle zeroType
Definition: UserDataOperators.hpp:1136

MoFEM::OpCalculateScalarFieldGradient::OpCalculateScalarFieldGradient
OpCalculateScalarFieldGradient(const std::string field_name, boost::shared_ptr< MatrixDouble > &data_ptr, const EntityType zero_type=MBVERTEX)
Definition: UserDataOperators.hpp:908

MoFEM::OpCalculateScalarFieldGradient_General::OpCalculateScalarFieldGradient_General
OpCalculateScalarFieldGradient_General(const std::string field_name, boost::shared_ptr< MatrixDouble > &data_ptr, const EntityType zero_type=MBVERTEX)
Definition: UserDataOperators.hpp:813

MoFEM::OpCalculateTensor2FieldValues_General
Calculate field values for tenor field rank 2.
Definition: UserDataOperators.hpp:438

MoFEM::OpCalculateScalarFieldValues_General::OpCalculateScalarFieldValues_General
OpCalculateScalarFieldValues_General(const std::string field_name, boost::shared_ptr< ublas::vector< T, A >> &data_ptr, const EntityType zero_type=MBVERTEX)
Definition: UserDataOperators.hpp:39

MoFEM::OpCalculateHdivVectorField_General< Tensor_Dim, double, ublas::row_major, DoubleAllocator >::OpCalculateHdivVectorField_General
OpCalculateHdivVectorField_General(const std::string field_name, boost::shared_ptr< MatrixDouble > &data_ptr, const EntityType zero_type=MBEDGE, const int zero_side=0)
Definition: UserDataOperators.hpp:1184

MoFEM::OpCalculateHTensorTensorField::zeroSide
const int zeroSide
Definition: UserDataOperators.hpp:1465

MoFEM::OpSetInvJacH1ForFlatPrism
Transform local reference derivatives of shape functions to global derivatives.
Definition: UserDataOperators.hpp:1809

MoFEM::OpCalculateHTensorTensorField
Calculate tenor field using vectorial base, i.e. Hdiv/Hcurl.
Definition: UserDataOperators.hpp:1460

MoFEM::OpCalculateJacForFace::doWork
MoFEMErrorCode doWork(int side, EntityType type, DataForcesAndSourcesCore::EntData &data)
Operator for linear form, usually to calculate values on right hand side.
Definition: UserDataOperators.cpp:24

CHKERR
#define CHKERR
Inline error check.
Definition: definitions.h:601

MoFEM::OpCalculateScalarFieldValuesDot::doWork
MoFEMErrorCode doWork(int side, EntityType type, DataForcesAndSourcesCore::EntData &data)
Operator for linear form, usually to calculate values on right hand side.
Definition: UserDataOperators.hpp:154

MoFEM::OpCalculateTensor2FieldValuesDot::doWork
MoFEMErrorCode doWork(int side, EntityType type, DataForcesAndSourcesCore::EntData &data)
Operator for linear form, usually to calculate values on right hand side.
Definition: UserDataOperators.hpp:583

MoFEM::OpSetInvJacH1ForFatPrism
Transform local reference derivatives of shape functions to global derivatives.
Definition: UserDataOperators.hpp:1755

MoFEM::OpSetInvJacH1ForFace
Transform local reference derivatives of shape functions to global derivatives.
Definition: UserDataOperators.hpp:1621

MoFEM::OpCalculateHdivVectorField_General< Tensor_Dim, double, ublas::row_major, DoubleAllocator >::dataPtr
boost::shared_ptr< MatrixDouble > dataPtr
Definition: UserDataOperators.hpp:1180

FTensor::Tensor2_symmetric
Definition: Tensor2_symmetric_value.hpp:13

MoFEM::OpCalculateTensor2SymmetricFieldValuesDot::zeroType
const EntityHandle zeroType
Definition: UserDataOperators.hpp:719

OpContactTools::i
FTensor::Index< 'i', 2 > i
[Common data]
Definition: ContactOps.hpp:24

MoFEM::OpCalculateVectorFieldGradient_General::OpCalculateVectorFieldGradient_General
OpCalculateVectorFieldGradient_General(const std::string field_name, boost::shared_ptr< MatrixDouble > &data_ptr, const EntityType zero_type=MBVERTEX)
Definition: UserDataOperators.hpp:926

MoFEM::OpSetContravariantPiolaTransformFace::doWork
MoFEMErrorCode doWork(int side, EntityType type, DataForcesAndSourcesCore::EntData &data)
Operator for linear form, usually to calculate values on right hand side.
Definition: UserDataOperators.cpp:374

MoFEM::OpCalculateInvJacForFatPrism::OpCalculateInvJacForFatPrism
OpCalculateInvJacForFatPrism(MatrixDouble &inv_jac)
Definition: UserDataOperators.hpp:1735

MoFEM::DataForcesAndSourcesCore::EntData::getFTensor2DiffN
FTensor::Tensor2< FTensor::PackPtr< double *, Tensor_Dim0 *Tensor_Dim1 >, Tensor_Dim0, Tensor_Dim1 > getFTensor2DiffN(FieldApproximationBase base)
Get derivatives of base functions for Hdiv space.
Definition: DataStructures.cpp:607

MoFEM::OpSetContrariantPiolaTransformOnEdge::OpSetContrariantPiolaTransformOnEdge
OpSetContrariantPiolaTransformOnEdge()
Definition: UserDataOperators.hpp:1708

MoFEM::FaceElementForcesAndSourcesCoreBase::UserDataOperator
default operator for TRI element
Definition: FaceElementForcesAndSourcesCore.hpp:45

MoFEM::OpSetInvJacH1ForFace::OpSetInvJacH1ForFace
OpSetInvJacH1ForFace(MatrixDouble &inv_jac)
Definition: UserDataOperators.hpp:1624

MoFEM::OpCalculateJacForFace::jac
MatrixDouble & jac
Definition: UserDataOperators.hpp:1584

MoFEM::OpSetInvJacHcurlFace
brief Transform local reference derivatives of shape function to global derivatives for face
Definition: UserDataOperators.hpp:1642

MoFEM::OpCalculateTensor2FieldValues_General::doWork
MoFEMErrorCode doWork(int side, EntityType type, DataForcesAndSourcesCore::EntData &data)
Operator for linear form, usually to calculate values on right hand side.
Definition: UserDataOperators.hpp:462

MoFEM::OpCalculateHdivVectorDivergence::dataPtr
boost::shared_ptr< VectorDouble > dataPtr
Definition: UserDataOperators.hpp:1267

MoFEM::OpCalculateInvJacForFace::OpCalculateInvJacForFace
OpCalculateInvJacForFace(MatrixDouble &inv_jac)
Definition: UserDataOperators.hpp:1607

MoFEM::OpSetInvJacHcurlFace::diffHcurlInvJac
MatrixDouble diffHcurlInvJac
Definition: UserDataOperators.hpp:1654

MoFEM::OpCalculateTensor2SymmetricFieldValues::doWork
MoFEMErrorCode doWork(int side, EntityType type, DataForcesAndSourcesCore::EntData &data)
Operator for linear form, usually to calculate values on right hand side.
Definition: UserDataOperators.hpp:671

MoFEM::OpCalculateScalarFieldGradient
Get field gradients at integration pts for scalar filed rank 0, i.e. vector field.
Definition: UserDataOperators.hpp:904

MoFEM::OpCalculateHdivVectorField_General::dataPtr
boost::shared_ptr< ublas::matrix< T, L, A > > dataPtr
Definition: UserDataOperators.hpp:1135

MoFEM::OpCalculateScalarFieldValues_General
Calculate field values for tenor field rank 0, i.e. scalar field.
Definition: UserDataOperators.hpp:33

MoFEM::OpCalculateScalarFieldValues_General::zeroType
const EntityHandle zeroType
Definition: UserDataOperators.hpp:37

MoFEM::DataForcesAndSourcesCore::EntData
Data on single entity (This is passed as argument to DataOperator::doWork)
Definition: DataStructures.hpp:51

MoFEM::OpSetContravariantPiolaTransformFace
Apply contravariant (Piola) transfer to Hdiv space on face.
Definition: UserDataOperators.hpp:1686

MoFEM::OpSetInvJacHcurlFace::invJac
MatrixDouble & invJac
Definition: UserDataOperators.hpp:1653

MoFEM::ForcesAndSourcesCore
structure to get information form mofem into DataForcesAndSourcesCore
Definition: ForcesAndSourcesCore.hpp:34

MoFEM::OpCalculateVectorFieldValuesDot::doWork
MoFEMErrorCode doWork(int side, EntityType type, DataForcesAndSourcesCore::EntData &data)
Operator for linear form, usually to calculate values on right hand side.
Definition: UserDataOperators.hpp:373

MoFEM::OpCalculateTensor2FieldValuesDot::dataPtr
boost::shared_ptr< MatrixDouble > & dataPtr
Data computed into this matrix.
Definition: UserDataOperators.hpp:565

MoFEM::OpCalculateScalarFieldValuesDot
Get rate of scalar field at integration points.
Definition: UserDataOperators.hpp:137

MoFEM::FatPrismElementForcesAndSourcesCore
FatPrism finite elementUser is implementing own operator at Gauss points level, by own object derived...
Definition: FatPrismElementForcesAndSourcesCore.hpp:43

MoFEMFunctionBegin
#define MoFEMFunctionBegin
First executable line of each MoFEM function, used for error handling. Final line of MoFEM functions ...
Definition: definitions.h:412

MoFEM::OpCalculateTensor2SymmetricFieldValuesDot::doWork
MoFEMErrorCode doWork(int side, EntityType type, DataForcesAndSourcesCore::EntData &data)
Operator for linear form, usually to calculate values on right hand side.
Definition: UserDataOperators.hpp:737

MoFEM::OpCalculateHVecTensorField::doWork
MoFEMErrorCode doWork(int side, EntityType type, DataForcesAndSourcesCore::EntData &data)
Operator for linear form, usually to calculate values on right hand side.
Definition: UserDataOperators.hpp:1420

MoFEM::OpCalculateJacForFace
Calculate jacobian for face element.
Definition: UserDataOperators.hpp:1582

FTensor::Tensor2
Definition: Tensor2_value.hpp:16

H1
continuous field
Definition: definitions.h:176

MoFEM::OpCalculateVectorFieldValues_General< Tensor_Dim, double, ublas::row_major, DoubleAllocator >::dataPtr
boost::shared_ptr< MatrixDouble > dataPtr
Definition: UserDataOperators.hpp:263

MoFEM::OpCalculateVectorFieldValues_General::OpCalculateVectorFieldValues_General
OpCalculateVectorFieldValues_General(const std::string field_name, boost::shared_ptr< ublas::matrix< T, L, A >> &data_ptr, const EntityType zero_type=MBVERTEX)
Definition: UserDataOperators.hpp:220

MoFEM::ForcesAndSourcesCore::UserDataOperator::OPROW
Definition: ForcesAndSourcesCore.hpp:99

MoFEM::OpCalculateHVecTensorDivergence::dataPtr
boost::shared_ptr< MatrixDouble > dataPtr
Definition: UserDataOperators.hpp:1522

MoFEM::OpCalculateVectorFieldValues_General< Tensor_Dim, double, ublas::row_major, DoubleAllocator >::zeroType
const EntityHandle zeroType
Definition: UserDataOperators.hpp:264

MoFEM::OpCalculateHdivVectorDivergence::OpCalculateHdivVectorDivergence
OpCalculateHdivVectorDivergence(const std::string field_name, boost::shared_ptr< VectorDouble > &data_ptr, const EntityType zero_type=MBEDGE, const int zero_side=0)
Definition: UserDataOperators.hpp:1271

MoFEM::Types::VectorDouble
ublas::vector< double, DoubleAllocator > VectorDouble
Definition: Types.hpp:72

MoFEM::OpCalculateTensor2SymmetricFieldValuesDot
Calculate symmetric tensor field rates ant integratio pts.
Definition: UserDataOperators.hpp:715

MoFEM::DataForcesAndSourcesCore::EntData::getN
MatrixDouble & getN(const FieldApproximationBase base)
get base functions this return matrix (nb. of rows is equal to nb. of Gauss pts, nb....
Definition: DataStructures.hpp:1249

MoFEM::OpCalculateTensor2FieldValuesDot
Get time direvarive values at integration pts for tensor filed rank 2, i.e. matrix field.
Definition: UserDataOperators.hpp:562

MoFEM::OpCalculateHVecTensorField::zeroType
const EntityHandle zeroType
Definition: UserDataOperators.hpp:1406

MoFEM::OpCalculateInvJacForFace::invJac
MatrixDouble & invJac
Definition: UserDataOperators.hpp:1605

MoFEM::DataForcesAndSourcesCore::EntData::getFieldData
const VectorDouble & getFieldData() const
get dofs values
Definition: DataStructures.hpp:1190

MoFEM::OpCalculateHcurlVectorCurl::zeroType
const EntityHandle zeroType
Definition: UserDataOperators.hpp:1327

MoFEM::OpCalculateVectorFieldGradientDot::OpCalculateVectorFieldGradientDot
OpCalculateVectorFieldGradientDot(const std::string field_name, boost::shared_ptr< MatrixDouble > &data_ptr, const EntityType zero_at_type=MBVERTEX)
Definition: UserDataOperators.hpp:1047

MoFEM::OpCalculateInvJacForFatPrism::doWork
MoFEMErrorCode doWork(int side, EntityType type, DataForcesAndSourcesCore::EntData &data)
Operator for linear form, usually to calculate values on right hand side.
Definition: UserDataOperators.cpp:529

MoFEM::ForcesAndSourcesCore::UserDataOperator
Data operator to do calculations at integration points.Is inherited and implemented by user to do cal...
Definition: ForcesAndSourcesCore.hpp:84

MoFEM::OpCalculateInvJacForFace::doWork
MoFEMErrorCode doWork(int side, EntityType type, DataForcesAndSourcesCore::EntData &data)
Operator for linear form, usually to calculate values on right hand side.
Definition: UserDataOperators.cpp:112

MoFEM::OpSetInvJacH1ForFace::invJac
MatrixDouble & invJac
Definition: UserDataOperators.hpp:1632

MoFEM::Types::DoubleAllocator
std::vector< double, std::allocator< double > > DoubleAllocator
Definition: Types.hpp:70

MoFEM::OpCalculateTensor2SymmetricFieldValues
Calculate symmetric tensor field values at integration pts.
Definition: UserDataOperators.hpp:654

MoFEM::OpCalculateHdivVectorField_General< Tensor_Dim, double, ublas::row_major, DoubleAllocator >::zeroSide
const int zeroSide
Definition: UserDataOperators.hpp:1182

MoFEM::OpCalculateScalarFieldValues_General::doWork
MoFEMErrorCode doWork(int side, EntityType type, DataForcesAndSourcesCore::EntData &data)
calculate values of scalar field at integration points
Definition: UserDataOperators.hpp:66

MoFEM::OpCalculateScalarFieldValues_General::dataPtr
boost::shared_ptr< ublas::vector< T, A > > dataPtr
Definition: UserDataOperators.hpp:36

MoFEM::OpCalculateHcurlVectorCurl::zeroSide
const int zeroSide
Definition: UserDataOperators.hpp:1328

MoFEM::OpCalculateScalarFieldValues
Get value at integration points for scalar field.
Definition: UserDataOperators.hpp:80

MoFEM::OpCalculateInvJacForFlatPrism::doWork
MoFEMErrorCode doWork(int side, EntityType type, DataForcesAndSourcesCore::EntData &data)
Operator for linear form, usually to calculate values on right hand side.
Definition: UserDataOperators.cpp:617

MoFEM::OpCalculateTensor2SymmetricFieldValues::zeroType
const EntityHandle zeroType
Definition: UserDataOperators.hpp:658

MoFEM::OpMakeHdivFromHcurl::doWork
MoFEMErrorCode doWork(int side, EntityType type, DataForcesAndSourcesCore::EntData &data)
Operator for linear form, usually to calculate values on right hand side.
Definition: UserDataOperators.cpp:329

MoFEM::OpCalculateInvJacForFlatPrism::invJacF3
MatrixDouble & invJacF3
Definition: UserDataOperators.hpp:1792

MoFEM::DataForcesAndSourcesCore::EntData::getFTensor1N
FTensor::Tensor1< FTensor::PackPtr< double *, Tensor_Dim >, Tensor_Dim > getFTensor1N(FieldApproximationBase base)
Get base functions for Hdiv/Hcurl spaces.
Definition: DataStructures.cpp:587

OpContactTools::j
FTensor::Index< 'j', 2 > j
Definition: ContactOps.hpp:25

MoFEM::OpCalculateTensor2FieldValues
Get values at integration pts for tensor filed rank 2, i.e. matrix field.
Definition: UserDataOperators.hpp:543

MoFEM::OpCalculateTensor2SymmetricFieldValues::OpCalculateTensor2SymmetricFieldValues
OpCalculateTensor2SymmetricFieldValues(const std::string field_name, boost::shared_ptr< MatrixDouble > &data_ptr, const EntityType zero_type=MBEDGE, const int zero_side=0)
Definition: UserDataOperators.hpp:661

MoFEM::OpCalculateTensor2FieldValuesDot::dotVector
VectorDouble dotVector
Keeps temoorary values of time directives.
Definition: UserDataOperators.hpp:567

MoFEM::DataForcesAndSourcesCore::EntData::getFTensor0N
FTensor::Tensor0< FTensor::PackPtr< double *, 1 > > getFTensor0N(const FieldApproximationBase base)
Get base function as Tensor0.
Definition: DataStructures.hpp:1420

MoFEM::OpCalculateInvJacForFatPrism::invJacPtr
const boost::shared_ptr< MatrixDouble > invJacPtr
Definition: UserDataOperators.hpp:1742

MoFEM::OpCalculateHdivVectorField_General::OpCalculateHdivVectorField_General
OpCalculateHdivVectorField_General(const std::string field_name, boost::shared_ptr< ublas::matrix< T, L, A >> &data_ptr, const EntityType zero_type=MBEDGE, const int zero_side=0)
Definition: UserDataOperators.hpp:1139

MoFEM::OpSetContrariantPiolaTransformOnEdge
Definition: UserDataOperators.hpp:1705

MoFEM::OpCalculateScalarFieldValues::doWork
MoFEMErrorCode doWork(int side, EntityType type, DataForcesAndSourcesCore::EntData &data)
calculate values of scalar field at integration points
Definition: UserDataOperators.hpp:99

MoFEM::FaceElementForcesAndSourcesCoreBase
Face finite elementUser is implementing own operator at Gauss point level, by own object derived from...
Definition: FaceElementForcesAndSourcesCore.hpp:37

FTensor::row_major
Definition: Layout.hpp:13

MoFEM::OpMakeHdivFromHcurl
Make Hdiv space from Hcurl space in 2d.
Definition: UserDataOperators.hpp:1661

MoFEM::OpCalculateTensor2SymmetricFieldValuesDot::OpCalculateTensor2SymmetricFieldValuesDot
OpCalculateTensor2SymmetricFieldValuesDot(const std::string field_name, boost::shared_ptr< MatrixDouble > &data_ptr, const EntityType zero_type=MBEDGE, const int zero_side=0)
Definition: UserDataOperators.hpp:727

FTensor::levi_civita
constexpr std::enable_if<(Dim0<=2 &&Dim1<=2), Tensor2_Expr< Levi_Civita< T >, T, Dim0, Dim1, i, j > >::type levi_civita(const Index< i, Dim0 > &, const Index< j, Dim1 > &)
levi_civita functions to make for easy adhoc use
Definition: Levi_Civita.hpp:617

MoFEM::OpCalculateVectorFieldGradientDot::doWork
MoFEMErrorCode doWork(int side, EntityType type, DataForcesAndSourcesCore::EntData &data)
Operator for linear form, usually to calculate values on right hand side.
Definition: UserDataOperators.hpp:1057