mofem/html/_eshelbian_operators_8cpp_source.html

/**

 * \file EshelbianOperators.cpp

 * \example EshelbianOperators.cpp

 *

 * \brief Implementation of operators

 */


#include <MoFEM.hpp>

using namespace MoFEM;


#include <EshelbianPlasticity.hpp>

#include <boost/math/constants/constants.hpp>


#include <lapack_wrap.h>


#include <MatrixFunction.hpp>


namespace EshelbianPlasticity {


constexpr static auto size_symm = (3 * (3 + 1)) / 2;


inline auto diff_tensor() {

  FTensor::Index<'i', 3> i;

  FTensor::Index<'j', 3> j;

  FTensor::Index<'k', 3> k;

  FTensor::Index<'l', 3> l;

  FTensor::Ddg<double, 3, 3> t_diff;

  constexpr auto t_kd = FTensor::Kronecker_Delta_symmetric<int>();

  t_diff(i, j, k, l) = (t_kd(i, k) ^ t_kd(j, l)) / 4.;

  return t_diff;

};


inline auto symm_L_tensor() {

  FTensor::Index<'i', 3> i;

  FTensor::Index<'j', 3> j;

  FTensor::Index<'L', size_symm> L;

  FTensor::Dg<double, 3, size_symm> t_L;

  t_L(i, j, L) = 0;

  t_L(0, 0, 0) = 1;

  t_L(1, 1, 3) = 1;

  t_L(2, 2, 5) = 1;

  t_L(1, 0, 1) = 1;

  t_L(2, 0, 2) = 1;

  t_L(2, 1, 4) = 1;

  return t_L;

}


template <class T> struct TensorTypeExtractor {

  typedef typename std::remove_pointer<T>::type Type;

};

template <class T, int I> struct TensorTypeExtractor<FTensor::PackPtr<T, I>> {

  typedef typename std::remove_pointer<T>::type Type;

};


template <typename T>

auto get_rotation_form_vector(FTensor::Tensor1<T, 3> &t_omega,

                              RotSelector rotSelector = LARGE_ROT) {


  using D = typename TensorTypeExtractor<T>::Type;


  FTensor::Index<'i', 3> i;

  FTensor::Index<'j', 3> j;

  FTensor::Index<'k', 3> k;

  FTensor::Tensor2<D, 3, 3> t_R;


  constexpr auto t_kd = FTensor::Kronecker_Delta<int>();

  t_R(i, j) = t_kd(i, j);


  FTensor::Tensor2<D, 3, 3> t_Omega;

  t_Omega(i, j) = FTensor::levi_civita<double>(i, j, k) * t_omega(k);


  const auto angle =

      sqrt(t_omega(i) * t_omega(i)) + std::numeric_limits<double>::epsilon();

  if (rotSelector == SMALL_ROT) {

    t_R(i, j) += t_Omega(i, j);

    return t_R;

  }


  const auto a = sin(angle) / angle;

  t_R(i, j) += a * t_Omega(i, j);

  if (rotSelector == MODERATE_ROT)

    return t_R;


  const auto ss_2 = sin(angle / 2.);

  const auto b = 2. * ss_2 * ss_2 / (angle * angle);

  t_R(i, j) += b * t_Omega(i, k) * t_Omega(k, j);


  return t_R;

}


template <typename T>

auto get_diff_rotation_form_vector(FTensor::Tensor1<T, 3> &t_omega,

                                   RotSelector rotSelector = LARGE_ROT) {


  using D = typename TensorTypeExtractor<T>::Type;


  FTensor::Index<'i', 3> i;

  FTensor::Index<'j', 3> j;

  FTensor::Index<'k', 3> k;

  FTensor::Index<'l', 3> l;


  FTensor::Tensor3<D, 3, 3, 3> t_diff_R;


  const auto angle =

      sqrt(t_omega(i) * t_omega(i)) + std::numeric_limits<double>::epsilon();

  if (rotSelector == SMALL_ROT) {

    t_diff_R(i, j, k) = FTensor::levi_civita<double>(i, j, k);

    return t_diff_R;

  }


  const auto ss = sin(angle);

  const auto a = ss / angle;

  t_diff_R(i, j, k) = a * FTensor::levi_civita<double>(i, j, k);


  FTensor::Tensor2<D, 3, 3> t_Omega;

  t_Omega(i, j) = FTensor::levi_civita<double>(i, j, k) * t_omega(k);


  const auto angle2 = angle * angle;

  const auto cc = cos(angle);

  const auto diff_a = (angle * cc - ss) / angle2;

  t_diff_R(i, j, k) += diff_a * t_Omega(i, j) * (t_omega(k) / angle);

  if (rotSelector == MODERATE_ROT)

    return t_diff_R;


  const auto ss_2 = sin(angle / 2.);

  const auto cc_2 = cos(angle / 2.);

  const auto b = 2. * ss_2 * ss_2 / angle2;

  t_diff_R(i, j, k) +=

      b * (t_Omega(i, l) * FTensor::levi_civita<double>(l, j, k) +

           FTensor::levi_civita<double>(i, l, k) * t_Omega(l, j));

  const auto diff_b =

      (2. * angle * ss_2 * cc_2 - 4. * ss_2 * ss_2) / (angle2 * angle);

  t_diff_R(i, j, k) +=

      diff_b * t_Omega(i, l) * t_Omega(l, j) * (t_omega(k) / angle);


  return t_diff_R;

}


template <typename T>

auto get_diff2_rotation_form_vector(FTensor::Tensor1<T, 3> &t_omega,

                                    RotSelector rotSelector = LARGE_ROT) {


  using D = typename TensorTypeExtractor<T>::Type;


  FTensor::Tensor4<D, 3, 3, 3, 3> t_diff2_R;

  FTensor::Index<'i', 3> i;


  constexpr double eps = 1e-10;

  for (int l = 0; l != 3; ++l) {

    FTensor::Tensor1<std::complex<double>, 3> t_omega_c;

    t_omega_c(i) = t_omega(i);

    t_omega_c(l) += std::complex<double>(0, eps);

    auto t_diff_R_c = get_diff_rotation_form_vector(t_omega_c, rotSelector);

    for (int i = 0; i != 3; ++i) {

      for (int j = 0; j != 3; ++j) {

        for (int k = 0; k != 3; ++k) {

          t_diff2_R(i, j, k, l) = t_diff_R_c(i, j, k).imag() / eps;

        }

      }

    }

  }


  return t_diff2_R;

}


struct isEq {

  static inline auto check(const double &a, const double &b) {

    constexpr double eps = std::numeric_limits<float>::epsilon();

    return std::abs(a - b) / absMax < eps;

  }

  static double absMax;

};


double isEq::absMax = 1;


inline auto is_eq(const double &a, const double &b) {

  return isEq::check(a, b);

};


template <int DIM> inline auto get_uniq_nb(double *ptr) {

  std::array<double, DIM> tmp;

  std::copy(ptr, &ptr[DIM], tmp.begin());

  std::sort(tmp.begin(), tmp.end());

  isEq::absMax = std::max(std::abs(tmp[0]), std::abs(tmp[DIM - 1]));

  constexpr double eps = std::numeric_limits<float>::epsilon();

  isEq::absMax = std::max(isEq::absMax, static_cast<double>(eps));

  return std::distance(tmp.begin(), std::unique(tmp.begin(), tmp.end(), is_eq));

}


template <int DIM>

inline auto sort_eigen_vals(FTensor::Tensor1<double, DIM> &eig,

                            FTensor::Tensor2<double, DIM, DIM> &eigen_vec) {


  isEq::absMax =

      std::max(std::max(std::abs(eig(0)), std::abs(eig(1))), std::abs(eig(2)));


  int i = 0, j = 1, k = 2;


  if (is_eq(eig(0), eig(1))) {

    i = 0;

    j = 2;

    k = 1;

  } else if (is_eq(eig(0), eig(2))) {

    i = 0;

    j = 1;

    k = 2;

  } else if (is_eq(eig(1), eig(2))) {

    i = 1;

    j = 0;

    k = 2;

  }


  FTensor::Tensor2<double, 3, 3> eigen_vec_c{

      eigen_vec(i, 0), eigen_vec(i, 1), eigen_vec(i, 2),


      eigen_vec(j, 0), eigen_vec(j, 1), eigen_vec(j, 2),


      eigen_vec(k, 0), eigen_vec(k, 1), eigen_vec(k, 2)};


  FTensor::Tensor1<double, 3> eig_c{eig(i), eig(j), eig(k)};


  {

    FTensor::Index<'i', DIM> i;

    FTensor::Index<'j', DIM> j;

    eig(i) = eig_c(i);

    eigen_vec(i, j) = eigen_vec_c(i, j);

  }

}


MoFEMErrorCode OpCalculateRotationAndSpatialGradient::doWork(int side,

                                                             EntityType type,

                                                             EntData &data) {

  MoFEMFunctionBegin;


  FTensor::Index<'L', size_symm> L;

  auto t_L = symm_L_tensor();


  int nb_integration_pts = getGaussPts().size2();

  FTensor::Index<'i', 3> i;

  FTensor::Index<'j', 3> j;

  FTensor::Index<'k', 3> k;

  FTensor::Index<'l', 3> l;

  FTensor::Index<'m', 3> m;

  FTensor::Index<'l', 3> n;


  dataAtPts->hAtPts.resize(9, nb_integration_pts, false);

  dataAtPts->hdOmegaAtPts.resize(9 * 3, nb_integration_pts, false);

  dataAtPts->hdLogStretchAtPts.resize(9 * 6, nb_integration_pts, false);

  dataAtPts->leviKirchoffAtPts.resize(3, nb_integration_pts, false);

  dataAtPts->leviKirchoffdPAtPts.resize(9 * 3, nb_integration_pts, false);

  dataAtPts->leviKirchoffdOmegaAtPts.resize(9, nb_integration_pts, false);


  dataAtPts->adjontPdstretchAtPts.resize(9, nb_integration_pts, false);

  dataAtPts->adjontPdUAtPts.resize(size_symm, nb_integration_pts, false);

  dataAtPts->adjontPdUdPAtPts.resize(9 * size_symm, nb_integration_pts, false);

  dataAtPts->adjontPdUdOmegaAtPts.resize(3 * size_symm, nb_integration_pts,

                                         false);

  dataAtPts->rotMatAtPts.resize(9, nb_integration_pts, false);

  dataAtPts->diffRotMatAtPts.resize(27, nb_integration_pts, false);

  dataAtPts->stretchTensorAtPts.resize(6, nb_integration_pts, false);

  dataAtPts->diffStretchTensorAtPts.resize(36, nb_integration_pts, false);

  dataAtPts->eigenVals.resize(3, nb_integration_pts, false);

  dataAtPts->eigenVecs.resize(9, nb_integration_pts, false);

  dataAtPts->nbUniq.resize(nb_integration_pts, false);


  dataAtPts->logStretchTotalTensorAtPts.resize(6, nb_integration_pts, false);


  auto t_h = getFTensor2FromMat<3, 3>(dataAtPts->hAtPts);

  auto t_h_domega = getFTensor3FromMat<3, 3, 3>(dataAtPts->hdOmegaAtPts);

  auto t_h_dlog_u = getFTensor3FromMat<3, 3, size_symm>(dataAtPts->hdLogStretchAtPts);

  auto t_levi_kirchoff = getFTensor1FromMat<3>(dataAtPts->leviKirchoffAtPts);

  auto t_levi_kirchoff_dP =

      getFTensor3FromMat<3, 3, 3>(dataAtPts->leviKirchoffdPAtPts);

  auto t_levi_kirchoff_domega =

      getFTensor2FromMat<3, 3>(dataAtPts->leviKirchoffdOmegaAtPts);

  auto t_approx_P_adjont_dstretch =

      getFTensor2FromMat<3, 3>(dataAtPts->adjontPdstretchAtPts);

  auto t_approx_P_adjont_log_du =

      getFTensor1FromMat<size_symm>(dataAtPts->adjontPdUAtPts);

  auto t_approx_P_adjont_log_du_dP =

      getFTensor3FromMat<3, 3, size_symm>(dataAtPts->adjontPdUdPAtPts);

  auto t_approx_P_adjont_log_du_domega =

      getFTensor2FromMat<3, size_symm>(dataAtPts->adjontPdUdOmegaAtPts);

  auto t_omega = getFTensor1FromMat<3>(dataAtPts->rotAxisAtPts);

  auto t_R = getFTensor2FromMat<3, 3>(dataAtPts->rotMatAtPts);

  auto t_diff_R = getFTensor3FromMat<3, 3, 3>(dataAtPts->diffRotMatAtPts);

  auto t_log_u =

      getFTensor2SymmetricFromMat<3>(dataAtPts->logStretchTensorAtPts);

  auto t_u = getFTensor2SymmetricFromMat<3>(dataAtPts->stretchTensorAtPts);

  auto t_approx_P = getFTensor2FromMat<3, 3>(dataAtPts->approxPAtPts);

  auto t_diff_u =

      getFTensor4DdgFromMat<3, 3, 1>(dataAtPts->diffStretchTensorAtPts);

  auto t_eigen_vals = getFTensor1FromMat<3>(dataAtPts->eigenVals);

  auto t_eigen_vecs = getFTensor2FromMat<3, 3>(dataAtPts->eigenVecs);


  auto &nbUniq = dataAtPts->nbUniq;

  auto t_grad_h1 = getFTensor2FromMat<3, 3>(dataAtPts->wGradH1AtPts);

  auto t_log_stretch_total =

      getFTensor2SymmetricFromMat<3>(dataAtPts->logStretchTotalTensorAtPts);

  auto t_kd = FTensor::Kronecker_Delta<int>();


  for (int gg = 0; gg != nb_integration_pts; ++gg) {


    FTensor::Tensor1<double, 3> eig;

    FTensor::Tensor2<double, 3, 3> eigen_vec;

    FTensor::Tensor3<double, 3, 3, size_symm> t_Ldiff_u;

    FTensor::Tensor2<double, 3, 3> t_h1;

    FTensor::Tensor2<double, 3, 3> t_Ru;

    FTensor::Tensor2<double, 3, 3> t_approx_P_intermidiata;


    t_h1(i, j) = t_grad_h1(i, j) + t_kd(i, j);


    auto calulate_rotation = [&]() {

      auto t0_diff =

          get_diff_rotation_form_vector(t_omega, EshelbianCore::rotSelector);

      auto t0 = get_rotation_form_vector(t_omega, EshelbianCore::rotSelector);

      t_diff_R(i, j, k) = t0_diff(i, j, k);

      t_R(i, j) = t0(i, j);

    };


    auto calulate_streach = [&]() {

      eigen_vec(i, j) = t_log_u(i, j);

      CHKERR computeEigenValuesSymmetric(eigen_vec, eig);

      // rare case when two eigen values are equal

      nbUniq[gg] = get_uniq_nb<3>(&eig(0));

      if (nbUniq[gg] < 3) {

        sort_eigen_vals<3>(eig, eigen_vec);

      }

      t_eigen_vals(i) = eig(i);

      t_eigen_vecs(i, j) = eigen_vec(i, j);

      auto t_u_tmp =

          EigenMatrix::getMat(t_eigen_vals, t_eigen_vecs, EshelbianCore::f);

      t_u(i, j) = t_u_tmp(i, j);

      auto t_diff_u_tmp =

          EigenMatrix::getDiffMat(t_eigen_vals, t_eigen_vecs, EshelbianCore::f,

                                  EshelbianCore::d_f, nbUniq[gg]);

      t_diff_u(i, j, k, l) = t_diff_u_tmp(i, j, k, l);

      t_Ldiff_u(i, j, L) = t_diff_u(i, j, m, n) * t_L(m, n, L);

    };


    calulate_rotation();

    calulate_streach();


    switch (EshelbianCore::gradApperoximator) {

    case LARGE_ROT:


      t_Ru(i, m) = t_R(i, l) * t_u(l, m);

      t_h(i, j) = t_Ru(i, m) * t_h1(m, j);

      t_h_domega(i, j, k) = (t_diff_R(i, l, k) * t_u(l, m)) * t_h1(m, j);

      t_h_dlog_u(i, j, L) = (t_R(i, l) * t_Ldiff_u(l, m, L)) * t_h1(m, j);


      t_approx_P_intermidiata(i, m) = t_approx_P(i, j) * t_h1(m, j);

      t_approx_P_adjont_dstretch(l, m) =

          t_approx_P_intermidiata(i, m) * t_R(i, l);


      t_levi_kirchoff(k) =

          levi_civita(l, m, k) * (t_approx_P_adjont_dstretch(l, m));

      t_levi_kirchoff_dP(i, j, k) =

          (levi_civita(l, m, k) * t_R(i, l)) * t_h1(m, j);

      t_levi_kirchoff_domega(k, n) =

          levi_civita(l, m, k) *

          (t_approx_P_intermidiata(i, m) * t_diff_R(i, l, n));


      t_approx_P_adjont_log_du(L) =

          t_Ldiff_u(l, m, L) * t_approx_P_adjont_dstretch(l, m);

      t_approx_P_adjont_log_du_dP(i, j, L) = t_h_dlog_u(i, j, L);

      t_approx_P_adjont_log_du_domega(n, L) =

          t_Ldiff_u(l, m, L) *

          (t_approx_P_intermidiata(i, m) * t_diff_R(i, l, n));


      break;

    case MODERATE_ROT:


      t_Ru(i, m) =

          t_kd(i, m) + (t_R(i, m) - t_kd(i, m)) + (t_u(i, m) - t_kd(i, m));

      t_h(i, j) = t_Ru(i, m) * t_h1(m, j);

      t_h_domega(i, j, k) = t_diff_R(i, m, k) * t_h1(m, j);

      t_h_dlog_u(i, j, L) = t_Ldiff_u(i, m, L) * t_h1(m, j);


      t_approx_P_intermidiata(i, m) = t_approx_P(i, j) * t_h1(m, j);

      t_approx_P_adjont_dstretch(i, m) = t_approx_P_intermidiata(i, m);


      t_levi_kirchoff(k) =

          levi_civita(i, m, k) * (t_approx_P_adjont_dstretch(i, m));

      t_levi_kirchoff_dP(i, j, k) = levi_civita(i, m, k) * t_h1(m, j);

      t_levi_kirchoff_domega(k, n) = 0;


      t_approx_P_adjont_log_du(L) =

          t_Ldiff_u(i, m, L) * t_approx_P_adjont_dstretch(i, m);

      t_approx_P_adjont_log_du_dP(i, j, L) = t_h_dlog_u(i, j, L);

      t_approx_P_adjont_log_du_domega(n, L) = 0;


      break;


    case SMALL_ROT:


      t_h(i, j) =

          t_kd(i, j) + (t_R(i, j) - t_kd(i, j)) + (t_u(i, j) - t_kd(i, j));

      t_h_domega(i, j, k) = t_diff_R(i, j, k);

      t_h_dlog_u(i, j, L) = t_Ldiff_u(i, j, L);


      t_levi_kirchoff(k) = levi_civita(i, j, k) * t_approx_P(i, j);

      t_levi_kirchoff_dP(i, j, k) = levi_civita(i, j, k);

      t_levi_kirchoff_domega(k, l) = 0;


      t_approx_P_adjont_dstretch(i, j) = t_approx_P(i, j);

      t_approx_P_adjont_log_du(L) =

          t_Ldiff_u(i, j, L) * t_approx_P_adjont_dstretch(i, j);

      t_approx_P_adjont_log_du_dP(i, j, L) = t_h_dlog_u(i, j, L);

      t_approx_P_adjont_log_du_domega(m, L) = 0;


      break;

    }


    FTensor::Tensor2<double, 3, 3> t_C_h1;

    t_C_h1(i, j) = t_h1(k, i) * t_h1(k, j);

    eigen_vec(i, j) = t_C_h1(i, j);

    CHKERR computeEigenValuesSymmetric(eigen_vec, eig);

    switch (EshelbianCore::stretchSelector) {

    case StretchSelector::LINEAR:

      break;

    case StretchSelector::LOG:

      for (int ii = 0; ii != 3; ++ii) {

        eig(ii) = std::max(eig(ii),

                           2 * EshelbianCore::inv_f(EshelbianCore::f(

                                   std::numeric_limits<double>::min_exponent)));

      }

      break;

    }


    auto t_log_u2_h1_tmp =

        EigenMatrix::getMat(eig, eigen_vec, EshelbianCore::inv_f);


    switch (EshelbianCore::gradApperoximator) {

    case LARGE_ROT:

    case MODERATE_ROT:

      t_log_stretch_total(i, j) = t_log_u2_h1_tmp(i, j) / 2 + t_log_u(i, j);

      break;

    case SMALL_ROT:

      t_log_stretch_total(i, j) = t_log_u(i, j);

      break;

    };


    ++t_h;

    ++t_h_domega;

    ++t_h_dlog_u;

    ++t_levi_kirchoff;

    ++t_levi_kirchoff_dP;

    ++t_levi_kirchoff_domega;

    ++t_approx_P_adjont_dstretch;

    ++t_approx_P_adjont_log_du;

    ++t_approx_P_adjont_log_du_dP;

    ++t_approx_P_adjont_log_du_domega;

    ++t_approx_P;

    ++t_R;

    ++t_diff_R;

    ++t_log_u;

    ++t_u;

    ++t_diff_u;

    ++t_eigen_vals;

    ++t_eigen_vecs;

    ++t_omega;

    ++t_grad_h1;

    ++t_log_stretch_total;

  }


  MoFEMFunctionReturn(0);

}


MoFEMErrorCode OpSpatialEquilibrium::integrate(EntData &data) {

  MoFEMFunctionBegin;

  int nb_dofs = data.getIndices().size();

  int nb_integration_pts = data.getN().size1();

  auto v = getVolume();

  auto t_w = getFTensor0IntegrationWeight();

  auto t_div_P = getFTensor1FromMat<3>(dataAtPts->divPAtPts);

  auto t_s_dot_w = getFTensor1FromMat<3>(dataAtPts->wL2DotAtPts);

  if (dataAtPts->wL2DotDotAtPts.size1() == 0 &&

      dataAtPts->wL2DotDotAtPts.size2() != nb_integration_pts) {

    dataAtPts->wL2DotDotAtPts.resize(3, nb_integration_pts);

    dataAtPts->wL2DotDotAtPts.clear();

  }

  auto t_s_dot_dot_w = getFTensor1FromMat<3>(dataAtPts->wL2DotDotAtPts);


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

  auto t_row_base_fun = data.getFTensor0N();


  FTensor::Index<'i', 3> i;

  auto get_ftensor1 = [](auto &v) {

    return FTensor::Tensor1<FTensor::PackPtr<double *, 3>, 3>(&v[0], &v[1],

                                                              &v[2]);

  };


  for (int gg = 0; gg != nb_integration_pts; ++gg) {

    double a = v * t_w;

    auto t_nf = get_ftensor1(nF);

    int bb = 0;

    for (; bb != nb_dofs / 3; ++bb) {

      t_nf(i) += a * t_row_base_fun * t_div_P(i);

      t_nf(i) -= a * t_row_base_fun * alphaW * t_s_dot_w(i);

      t_nf(i) -= a * t_row_base_fun * alphaRho * t_s_dot_dot_w(i);

      ++t_nf;

      ++t_row_base_fun;

    }

    for (; bb != nb_base_functions; ++bb)

      ++t_row_base_fun;

    ++t_w;

    ++t_div_P;

    ++t_s_dot_w;

    ++t_s_dot_dot_w;

  }


  MoFEMFunctionReturn(0);

}


MoFEMErrorCode OpSpatialRotation::integrate(EntData &data) {

  MoFEMFunctionBegin;

  int nb_dofs = data.getIndices().size();

  int nb_integration_pts = getGaussPts().size2();

  auto v = getVolume();

  auto t_w = getFTensor0IntegrationWeight();

  auto t_levi_kirchoff = getFTensor1FromMat<3>(dataAtPts->leviKirchoffAtPts);

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

  auto t_row_base_fun = data.getFTensor0N();

  FTensor::Index<'i', 3> i;

  FTensor::Index<'j', 3> j;

  FTensor::Index<'k', 3> k;

  auto get_ftensor1 = [](auto &v) {

    return FTensor::Tensor1<FTensor::PackPtr<double *, 3>, 3>(&v[0], &v[1],

                                                              &v[2]);

  };

  for (int gg = 0; gg != nb_integration_pts; ++gg) {

    double a = v * t_w;

    auto t_nf = get_ftensor1(nF);

    int bb = 0;

    for (; bb != nb_dofs / 3; ++bb) {

      t_nf(k) += (a * t_row_base_fun) * t_levi_kirchoff(k);

      ++t_nf;

      ++t_row_base_fun;

    }

    for (; bb != nb_base_functions; ++bb) {

      ++t_row_base_fun;

    }

    ++t_w;

    ++t_levi_kirchoff;

  }

  MoFEMFunctionReturn(0);

}


MoFEMErrorCode OpSpatialPhysical::integrate(EntData &data) {

  MoFEMFunctionBegin;


  if (dataAtPts->physicsPtr->dependentVariablesPiola.size()) {

    CHKERR integratePiola(data);

  } else {

    CHKERR integrateHencky(data);

  }


  MoFEMFunctionReturn(0);

}


MoFEMErrorCode OpSpatialPhysical::integrateHencky(EntData &data) {

  MoFEMFunctionBegin;


  FTensor::Index<'L', size_symm> L;

  auto t_L = symm_L_tensor();


  int nb_dofs = data.getIndices().size();

  int nb_integration_pts = data.getN().size1();

  auto v = getVolume();

  auto t_w = getFTensor0IntegrationWeight();

  auto t_approx_P_adjont_log_du =

      getFTensor1FromMat<size_symm>(dataAtPts->adjontPdUAtPts);

  auto t_log_streach_h1 =

      getFTensor2SymmetricFromMat<3>(dataAtPts->logStretchTotalTensorAtPts);

  auto t_dot_log_u =

      getFTensor2SymmetricFromMat<3>(dataAtPts->logStretchDotTensorAtPts);


  auto t_D = getFTensor4DdgFromMat<3, 3, 0>(dataAtPts->matD);


  FTensor::Index<'i', 3> i;

  FTensor::Index<'j', 3> j;

  FTensor::Index<'k', 3> k;

  FTensor::Index<'l', 3> l;

  auto get_ftensor2 = [](auto &v) {

    return FTensor::Tensor1<FTensor::PackPtr<double *, 6>, 6>(

        &v[0], &v[1], &v[2], &v[3], &v[4], &v[5]);

  };


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

  auto t_row_base_fun = data.getFTensor0N();

  for (int gg = 0; gg != nb_integration_pts; ++gg) {

    double a = v * t_w;

    auto t_nf = get_ftensor2(nF);


    FTensor::Tensor2_symmetric<double, 3> t_T;

    t_T(i, j) =

        t_D(i, j, k, l) * (t_log_streach_h1(k, l) + alphaU * t_dot_log_u(k, l));

    FTensor::Tensor1<double, size_symm> t_residual;

    t_residual(L) = a * (t_approx_P_adjont_log_du(L) - t_L(i, j, L) * t_T(i, j));


    int bb = 0;

    for (; bb != nb_dofs / 6; ++bb) {

      t_nf(L) += t_row_base_fun * t_residual(L);

      ++t_nf;

      ++t_row_base_fun;

    }

    for (; bb != nb_base_functions; ++bb)

      ++t_row_base_fun;


    ++t_w;

    ++t_approx_P_adjont_log_du;

    ++t_dot_log_u;

    ++t_log_streach_h1;

  }

  MoFEMFunctionReturn(0);

}


MoFEMErrorCode OpSpatialPhysical::integratePiola(EntData &data) {

  MoFEMFunctionBegin;


  FTensor::Index<'L', size_symm> L;

  auto t_L = symm_L_tensor();


  int nb_dofs = data.getIndices().size();

  int nb_integration_pts = data.getN().size1();

  auto v = getVolume();

  auto t_w = getFTensor0IntegrationWeight();

  auto t_approx_P_adjont_log_du =

      getFTensor1FromMat<size_symm>(dataAtPts->adjontPdUAtPts);

  auto t_P = getFTensor2FromMat<3, 3>(dataAtPts->PAtPts);

  auto t_dot_log_u =

      getFTensor2SymmetricFromMat<3>(dataAtPts->logStretchDotTensorAtPts);

  auto t_diff_u =

      getFTensor4DdgFromMat<3, 3, 1>(dataAtPts->diffStretchTensorAtPts);


  FTensor::Index<'i', 3> i;

  FTensor::Index<'j', 3> j;

  FTensor::Index<'k', 3> k;

  FTensor::Index<'l', 3> l;

  auto get_ftensor2 = [](auto &v) {

    return FTensor::Tensor1<FTensor::PackPtr<double *, 6>, 6>(

        &v[0], &v[1], &v[2], &v[3], &v[4], &v[5]);

  };


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

  auto t_row_base_fun = data.getFTensor0N();

  for (int gg = 0; gg != nb_integration_pts; ++gg) {

    double a = v * t_w;

    auto t_nf = get_ftensor2(nF);


    FTensor::Tensor3<double, 3, 3, size_symm> t_Ldiff_u;

    t_Ldiff_u(i, j, L) = t_diff_u(i, j, k, l) * t_L(k, l, L);


    FTensor::Tensor2_symmetric<double, 3> t_viscous_P;

    t_viscous_P(i, j) =

        alphaU *

        t_dot_log_u(i,

                    j); // That is chit, should be split on axiator and deviator


    FTensor::Tensor1<double, size_symm> t_residual;

    t_residual(L) =

        a * (t_approx_P_adjont_log_du(L) - t_Ldiff_u(i, j, L) * t_P(i, j) -

             t_L(i, j, L) * t_viscous_P(i, j));


    int bb = 0;

    for (; bb != nb_dofs / 6; ++bb) {

      t_nf(L) += t_row_base_fun * t_residual(L);

      ++t_nf;

      ++t_row_base_fun;

    }

    for (; bb != nb_base_functions; ++bb)

      ++t_row_base_fun;


    ++t_w;

    ++t_approx_P_adjont_log_du;

    ++t_P;

    ++t_dot_log_u;

    ++t_diff_u;

  }

  MoFEMFunctionReturn(0);

}


MoFEMErrorCode OpSpatialConsistencyP::integrate(EntData &data) {

  MoFEMFunctionBegin;

  int nb_dofs = data.getIndices().size();

  int nb_integration_pts = data.getN().size1();

  auto v = getVolume();

  auto t_w = getFTensor0IntegrationWeight();

  auto t_h = getFTensor2FromMat<3, 3>(dataAtPts->hAtPts);

  auto t_omega_dot = getFTensor1FromMat<3>(dataAtPts->rotAxisDotAtPts);


  int nb_base_functions = data.getN().size2() / 3;

  auto t_row_base_fun = data.getFTensor1N<3>();

  FTensor::Index<'i', 3> i;

  FTensor::Index<'j', 3> j;

  FTensor::Index<'k', 3> k;

  FTensor::Index<'m', 3> m;


  auto get_ftensor1 = [](auto &v) {

    return FTensor::Tensor1<FTensor::PackPtr<double *, 3>, 3>(&v[0], &v[1],

                                                              &v[2]);

  };


  for (int gg = 0; gg != nb_integration_pts; ++gg) {

    double a = v * t_w;

    auto t_nf = get_ftensor1(nF);


    constexpr auto t_kd = FTensor::Kronecker_Delta<int>();

    FTensor::Tensor2<double, 3, 3> t_residuum;

    t_residuum(i, j) = t_h(i, j) - t_kd(i, j);


    int bb = 0;

    for (; bb != nb_dofs / 3; ++bb) {

      t_nf(i) += a * t_row_base_fun(j) * t_residuum(i, j);

      ++t_nf;

      ++t_row_base_fun;

    }


    for (; bb != nb_base_functions; ++bb)

      ++t_row_base_fun;


    ++t_w;

    ++t_h;

    ++t_omega_dot;

  }


  MoFEMFunctionReturn(0);

}


MoFEMErrorCode OpSpatialConsistencyBubble::integrate(EntData &data) {

  MoFEMFunctionBegin;

  int nb_dofs = data.getIndices().size();

  int nb_integration_pts = data.getN().size1();

  auto v = getVolume();

  auto t_w = getFTensor0IntegrationWeight();

  auto t_h = getFTensor2FromMat<3, 3>(dataAtPts->hAtPts);

  auto t_omega_dot = getFTensor1FromMat<3>(dataAtPts->rotAxisDotAtPts);


  int nb_base_functions = data.getN().size2() / 9;

  auto t_row_base_fun = data.getFTensor2N<3, 3>();

  FTensor::Index<'i', 3> i;

  FTensor::Index<'j', 3> j;

  FTensor::Index<'k', 3> k;

  FTensor::Index<'m', 3> m;


  auto get_ftensor0 = [](auto &v) {

    return FTensor::Tensor0<FTensor::PackPtr<double *, 1>>(&v[0]);

  };


  for (int gg = 0; gg != nb_integration_pts; ++gg) {

    double a = v * t_w;

    auto t_nf = get_ftensor0(nF);


    constexpr auto t_kd = FTensor::Kronecker_Delta<int>();

    FTensor::Tensor2<double, 3, 3> t_residuum;

    t_residuum(i, j) = t_h(i, j) - t_kd(i, j);


    int bb = 0;

    for (; bb != nb_dofs; ++bb) {

      t_nf += a * t_row_base_fun(i, j) * t_residuum(i, j);

      ++t_nf;

      ++t_row_base_fun;

    }

    for (; bb != nb_base_functions; ++bb) {

      ++t_row_base_fun;

    }

    ++t_w;

    ++t_h;

    ++t_omega_dot;

  }


  MoFEMFunctionReturn(0);

}


MoFEMErrorCode OpSpatialConsistencyDivTerm::integrate(EntData &data) {

  MoFEMFunctionBegin;

  int nb_dofs = data.getIndices().size();

  int nb_integration_pts = data.getN().size1();

  auto v = getVolume();

  auto t_w = getFTensor0IntegrationWeight();

  auto t_w_l2 = getFTensor1FromMat<3>(dataAtPts->wL2AtPts);

  int nb_base_functions = data.getN().size2() / 3;

  auto t_row_diff_base_fun = data.getFTensor2DiffN<3, 3>();

  FTensor::Index<'i', 3> i;

  auto get_ftensor1 = [](auto &v) {

    return FTensor::Tensor1<FTensor::PackPtr<double *, 3>, 3>(&v[0], &v[1],

                                                              &v[2]);

  };


  for (int gg = 0; gg != nb_integration_pts; ++gg) {

    double a = v * t_w;

    auto t_nf = get_ftensor1(nF);

    int bb = 0;

    for (; bb != nb_dofs / 3; ++bb) {

      double div_row_base = t_row_diff_base_fun(i, i);

      t_nf(i) += a * div_row_base * t_w_l2(i);

      ++t_nf;

      ++t_row_diff_base_fun;

    }

    for (; bb != nb_base_functions; ++bb) {

      ++t_row_diff_base_fun;

    }

    ++t_w;

    ++t_w_l2;

  }


  MoFEMFunctionReturn(0);

}


MoFEMErrorCode OpDispBc::integrate(EntData &data) {

  MoFEMFunctionBegin;

  // get entity of face

  EntityHandle fe_ent = getFEEntityHandle();

  // interate over all boundary data

  for (auto &bc : (*bcDispPtr)) {

    // check if finite element entity is part of boundary condition

    if (bc.faces.find(fe_ent) != bc.faces.end()) {

      int nb_dofs = data.getIndices().size();

      int nb_integration_pts = data.getN().size1();

      auto t_normal = getFTensor1Normal();

      auto t_w = getFTensor0IntegrationWeight();

      int nb_base_functions = data.getN().size2() / 3;

      auto t_row_base_fun = data.getFTensor1N<3>();


      FTensor::Index<'i', 3> i;

      FTensor::Index<'j', 3> j;

      auto get_ftensor1 = [](auto &v) {

        return FTensor::Tensor1<FTensor::PackPtr<double *, 3>, 3>(&v[0], &v[1],

                                                                  &v[2]);

      };


      // get bc data

      FTensor::Tensor1<double, 3> t_bc_disp(bc.vals[0], bc.vals[1], bc.vals[2]);

      t_bc_disp(i) *= getFEMethod()->ts_t;


      for (int gg = 0; gg != nb_integration_pts; ++gg) {

        FTensor::Tensor1<double, 3> t_bc_res;

        t_bc_res(i) = t_bc_disp(i);

        auto t_nf = get_ftensor1(nF);

        int bb = 0;

        for (; bb != nb_dofs / 3; ++bb) {

          t_nf(i) -=

              t_w * (t_row_base_fun(j) * t_normal(j)) * t_bc_res(i) * 0.5;

          ++t_nf;

          ++t_row_base_fun;

        }

        for (; bb != nb_base_functions; ++bb)

          ++t_row_base_fun;


        ++t_w;

      }

    }

  }

  MoFEMFunctionReturn(0);

}


MoFEMErrorCode OpRotationBc::integrate(EntData &data) {

  MoFEMFunctionBegin;

  // get entity of face

  EntityHandle fe_ent = getFEEntityHandle();

  // interate over all boundary data

  for (auto &bc : (*bcRotPtr)) {

    // check if finite element entity is part of boundary condition

    if (bc.faces.find(fe_ent) != bc.faces.end()) {

      int nb_dofs = data.getIndices().size();

      int nb_integration_pts = data.getN().size1();

      auto t_normal = getFTensor1Normal();

      auto t_w = getFTensor0IntegrationWeight();


      int nb_base_functions = data.getN().size2() / 3;

      auto t_row_base_fun = data.getFTensor1N<3>();

      FTensor::Index<'i', 3> i;

      FTensor::Index<'j', 3> j;

      FTensor::Index<'k', 3> k;

      auto get_ftensor1 = [](auto &v) {

        return FTensor::Tensor1<FTensor::PackPtr<double *, 3>, 3>(&v[0], &v[1],

                                                                  &v[2]);

      };


      // get bc data

      FTensor::Tensor1<double, 3> t_center(bc.vals[0], bc.vals[1], bc.vals[2]);


      double theta = bc.theta;

      theta *= getFEMethod()->ts_t;


      FTensor::Tensor1<double, 3> t_omega;

      const double a = sqrt(t_normal(i) * t_normal(i));

      t_omega(i) = t_normal(i) * (theta / a);

      auto t_R = get_rotation_form_vector(t_omega, LARGE_ROT);

      auto t_coords = getFTensor1CoordsAtGaussPts();


      for (int gg = 0; gg != nb_integration_pts; ++gg) {

        FTensor::Tensor1<double, 3> t_delta;

        t_delta(i) = t_center(i) - t_coords(i);

        FTensor::Tensor1<double, 3> t_disp;

        t_disp(i) = t_delta(i) - t_R(i, j) * t_delta(j);


        auto t_nf = get_ftensor1(nF);

        int bb = 0;

        for (; bb != nb_dofs / 3; ++bb) {

          t_nf(i) -= t_w * (t_row_base_fun(j) * t_normal(j)) * t_disp(i) * 0.5;

          ++t_nf;

          ++t_row_base_fun;

        }

        for (; bb != nb_base_functions; ++bb)

          ++t_row_base_fun;


        ++t_w;

        ++t_coords;

      }

    }

  }

  MoFEMFunctionReturn(0);

}


MoFEMErrorCode FeTractionBc::preProcess() {

  MoFEMFunctionBegin;


  struct FaceRule {

    int operator()(int p_row, int p_col, int p_data) const {

      return 2 * (p_data + 1);

    }

  };


  if (ts_ctx == CTX_TSSETIFUNCTION) {


    // Loop boundary elements with traction boundary conditions

    FaceElementForcesAndSourcesCore fe(mField);

    AddHOOps<SPACE_DIM - 1, SPACE_DIM, SPACE_DIM>::add(fe.getOpPtrVector(),

                                                       {HDIV});

    fe.getOpPtrVector().push_back(

        new OpTractionBc(std::string("P") /* + "_RT"*/, *this));

    fe.getRuleHook = FaceRule();

    fe.ts_t = ts_t;

    CHKERR mField.loop_finite_elements(problemPtr->getName(), "ESSENTIAL_BC",

                                       fe, nullptr, MF_ZERO,

                                       this->getCacheWeakPtr());

  }


  MoFEMFunctionReturn(0);

}


MoFEMErrorCode OpTractionBc::doWork(int side, EntityType type, EntData &data) {

  MoFEMFunctionBegin;


  FTensor::Index<'i', 3> i;

  FTensor::Index<'j', 3> j;


  auto t_normal = getFTensor1Normal();

  const double nrm2 = sqrt(t_normal(i) * t_normal(i));

  FTensor::Tensor1<double, 3> t_unit_normal;

  t_unit_normal(i) = t_normal(i) / nrm2;

  int nb_dofs = data.getFieldData().size();

  int nb_integration_pts = data.getN().size1();

  int nb_base_functions = data.getN().size2() / 3;

  double ts_t = getFEMethod()->ts_t;


  auto integrate_matrix = [&]() {

    MoFEMFunctionBegin;


    auto t_w = getFTensor0IntegrationWeight();

    matPP.resize(nb_dofs / 3, nb_dofs / 3, false);

    matPP.clear();


    auto t_row_base_fun = data.getFTensor1N<3>();

    for (int gg = 0; gg != nb_integration_pts; ++gg) {


      int rr = 0;

      for (; rr != nb_dofs / 3; ++rr) {

        const double a = t_row_base_fun(i) * t_unit_normal(i);

        auto t_col_base_fun = data.getFTensor1N<3>(gg, 0);

        for (int cc = 0; cc != nb_dofs / 3; ++cc) {

          const double b = t_col_base_fun(i) * t_unit_normal(i);

          matPP(rr, cc) += t_w * a * b;

          ++t_col_base_fun;

        }

        ++t_row_base_fun;

      }


      for (; rr != nb_base_functions; ++rr)

        ++t_row_base_fun;


      ++t_w;

    }


    MoFEMFunctionReturn(0);

  };


  auto integrate_rhs = [&](auto &bc) {

    MoFEMFunctionBegin;


    auto t_w = getFTensor0IntegrationWeight();

    vecPv.resize(3, nb_dofs / 3, false);

    vecPv.clear();


    auto t_row_base_fun = data.getFTensor1N<3>();

    double ts_t = getFEMethod()->ts_t;


    for (int gg = 0; gg != nb_integration_pts; ++gg) {

      int rr = 0;

      for (; rr != nb_dofs / 3; ++rr) {

        const double t = ts_t * t_w * t_row_base_fun(i) * t_unit_normal(i);

        for (int dd = 0; dd != 3; ++dd)

          if (bc.flags[dd])

            vecPv(dd, rr) += t * bc.vals[dd];

        ++t_row_base_fun;

      }

      for (; rr != nb_base_functions; ++rr)

        ++t_row_base_fun;

      ++t_w;

    }

    MoFEMFunctionReturn(0);

  };


  auto integrate_rhs_cook = [&](auto &bc) {

    MoFEMFunctionBegin;


    vecPv.resize(3, nb_dofs / 3, false);

    vecPv.clear();


    auto t_w = getFTensor0IntegrationWeight();

    auto t_row_base_fun = data.getFTensor1N<3>();

    auto t_coords = getFTensor1CoordsAtGaussPts();


    for (int gg = 0; gg != nb_integration_pts; ++gg) {


      auto calc_tau = [](double y) {

        y -= 44;

        y /= (60 - 44);

        return -y * (y - 1) / 0.25;

      };


      const double tau = calc_tau(t_coords(1));


      int rr = 0;

      for (; rr != nb_dofs / 3; ++rr) {

        const double t = ts_t * t_w * t_row_base_fun(i) * t_unit_normal(i);

        for (int dd = 0; dd != 3; ++dd)

          if (bc.flags[dd])

            vecPv(dd, rr) += t * tau * bc.vals[dd];

        ++t_row_base_fun;

      }


      for (; rr != nb_base_functions; ++rr)

        ++t_row_base_fun;

      ++t_w;

      ++t_coords;

    }

    MoFEMFunctionReturn(0);

  };


  // get entity of face

  EntityHandle fe_ent = getFEEntityHandle();

  for (auto &bc : *(bcFe.bcData)) {

    if (bc.faces.find(fe_ent) != bc.faces.end()) {


      int nb_dofs = data.getFieldData().size();

      if (nb_dofs) {


        CHKERR integrate_matrix();

        if (std::regex_match(bc.blockName, std::regex(".*COOK.*")))

          CHKERR integrate_rhs_cook(bc);

        else

          CHKERR integrate_rhs(bc);


        const auto info =

            lapack_dposv('L', nb_dofs / 3, 3, &*matPP.data().begin(),

                         nb_dofs / 3, &*vecPv.data().begin(), nb_dofs / 3);

        if (info > 0)

          SETERRQ1(PETSC_COMM_SELF, MOFEM_OPERATION_UNSUCCESSFUL,

                   "The leading minor of order %i is "

                   "not positive; definite;\nthe "

                   "solution could not be computed",

                   info);


        for (int dd = 0; dd != 3; ++dd)

          if (bc.flags[dd])

            for (int rr = 0; rr != nb_dofs / 3; ++rr)

              data.getFieldDofs()[3 * rr + dd]->getFieldData() = vecPv(dd, rr);

      }

    }

  }


  MoFEMFunctionReturn(0);

}


MoFEMErrorCode OpSpatialEquilibrium_dw_dP::integrate(EntData &row_data,

                                                     EntData &col_data) {

  MoFEMFunctionBegin;

  int nb_integration_pts = row_data.getN().size1();

  int row_nb_dofs = row_data.getIndices().size();

  int col_nb_dofs = col_data.getIndices().size();

  auto get_ftensor1 = [](MatrixDouble &m, const int r, const int c) {

    return FTensor::Tensor1<FTensor::PackPtr<double *, 3>, 3>(

        &m(r + 0, c + 0), &m(r + 1, c + 1), &m(r + 2, c + 2));

  };

  FTensor::Index<'i', 3> i;

  auto v = getVolume();

  auto t_w = getFTensor0IntegrationWeight();

  int row_nb_base_functions = row_data.getN().size2();

  auto t_row_base_fun = row_data.getFTensor0N();

  for (int gg = 0; gg != nb_integration_pts; ++gg) {

    double a = v * t_w;

    int rr = 0;

    for (; rr != row_nb_dofs / 3; ++rr) {

      auto t_col_diff_base_fun = col_data.getFTensor2DiffN<3, 3>(gg, 0);

      auto t_m = get_ftensor1(K, 3 * rr, 0);

      for (int cc = 0; cc != col_nb_dofs / 3; ++cc) {

        double div_col_base = t_col_diff_base_fun(i, i);

        t_m(i) += a * t_row_base_fun * div_col_base;

        ++t_m;

        ++t_col_diff_base_fun;

      }

      ++t_row_base_fun;

    }

    for (; rr != row_nb_base_functions; ++rr)

      ++t_row_base_fun;

    ++t_w;

  }

  MoFEMFunctionReturn(0);

}


MoFEMErrorCode OpSpatialEquilibrium_dw_dw::integrate(EntData &row_data,

                                                     EntData &col_data) {

  MoFEMFunctionBegin;


  if (alphaW < std::numeric_limits<double>::epsilon() &&

      alphaRho < std::numeric_limits<double>::epsilon())

    MoFEMFunctionReturnHot(0);


  const int nb_integration_pts = row_data.getN().size1();

  const int row_nb_dofs = row_data.getIndices().size();

  auto get_ftensor1 = [](MatrixDouble &m, const int r, const int c) {

    return FTensor::Tensor1<FTensor::PackPtr<double *, 3>, 3>(

        &m(r + 0, c + 0), &m(r + 1, c + 1), &m(r + 2, c + 2)


    );

  };

  FTensor::Index<'i', 3> i;


  auto v = getVolume();

  auto t_w = getFTensor0IntegrationWeight();


  int row_nb_base_functions = row_data.getN().size2();

  auto t_row_base_fun = row_data.getFTensor0N();


  double ts_scale = alphaW * getTSa();

  if (std::abs(alphaRho) > std::numeric_limits<double>::epsilon())

    ts_scale += alphaRho * getTSaa();


  for (int gg = 0; gg != nb_integration_pts; ++gg) {

    double a = v * t_w * ts_scale;


    int rr = 0;

    for (; rr != row_nb_dofs / 3; ++rr) {


      auto t_col_base_fun = row_data.getFTensor0N(gg, 0);

      auto t_m = get_ftensor1(K, 3 * rr, 0);

      for (int cc = 0; cc != row_nb_dofs / 3; ++cc) {

        const double b = a * t_row_base_fun * t_col_base_fun;

        t_m(i) -= b;

        ++t_m;

        ++t_col_base_fun;

      }


      ++t_row_base_fun;

    }


    for (; rr != row_nb_base_functions; ++rr)

      ++t_row_base_fun;


    ++t_w;

  }


  MoFEMFunctionReturn(0);

}


MoFEMErrorCode OpSpatialPhysical_du_dP::integrate(EntData &row_data,

                                                  EntData &col_data) {

  MoFEMFunctionBegin;


  FTensor::Index<'L', size_symm> L;


  int nb_integration_pts = row_data.getN().size1();

  int row_nb_dofs = row_data.getIndices().size();

  int col_nb_dofs = col_data.getIndices().size();

  auto get_ftensor3 = [](MatrixDouble &m, const int r, const int c) {

    return FTensor::Tensor2<FTensor::PackPtr<double *, 3>, size_symm, 3>(


        &m(r + 0, c + 0), &m(r + 0, c + 1), &m(r + 0, c + 2),


        &m(r + 1, c + 0), &m(r + 1, c + 1), &m(r + 1, c + 2),


        &m(r + 2, c + 0), &m(r + 2, c + 1), &m(r + 2, c + 2),


        &m(r + 3, c + 0), &m(r + 3, c + 1), &m(r + 3, c + 2),


        &m(r + 4, c + 0), &m(r + 4, c + 1), &m(r + 4, c + 2),


        &m(r + 5, c + 0), &m(r + 5, c + 1), &m(r + 5, c + 2));

  };


  FTensor::Index<'i', 3> i;

  FTensor::Index<'j', 3> j;


  auto v = getVolume();

  auto t_w = getFTensor0IntegrationWeight();

  auto t_approx_P_adjont_log_du_dP =

      getFTensor3FromMat<3, 3, size_symm>(dataAtPts->adjontPdUdPAtPts);

  int row_nb_base_functions = row_data.getN().size2();

  auto t_row_base_fun = row_data.getFTensor0N();

  for (int gg = 0; gg != nb_integration_pts; ++gg) {

    double a = v * t_w;

    int rr = 0;

    for (; rr != row_nb_dofs / 6; ++rr) {


      auto t_col_base_fun = col_data.getFTensor1N<3>(gg, 0);

      auto t_m = get_ftensor3(K, 6 * rr, 0);


      for (int cc = 0; cc != col_nb_dofs / 3; ++cc) {

        t_m(L, i) += a *

                     (t_approx_P_adjont_log_du_dP(i, j, L) * t_col_base_fun(j)) *

                     t_row_base_fun;

        ++t_col_base_fun;

        ++t_m;

      }


      ++t_row_base_fun;

    }

    for (; rr != row_nb_base_functions; ++rr)

      ++t_row_base_fun;

    ++t_w;

    ++t_approx_P_adjont_log_du_dP;

  }

  MoFEMFunctionReturn(0);

}


MoFEMErrorCode OpSpatialPhysical_du_dBubble::integrate(EntData &row_data,

                                                       EntData &col_data) {

  MoFEMFunctionBegin;


  FTensor::Index<'L', size_symm> L;


  int nb_integration_pts = row_data.getN().size1();

  int row_nb_dofs = row_data.getIndices().size();

  int col_nb_dofs = col_data.getIndices().size();

  auto get_ftensor2 = [](MatrixDouble &m, const int r, const int c) {

    return FTensor::Tensor1<FTensor::PackPtr<double *, 1>, size_symm>(

        &m(r + 0, c), &m(r + 1, c), &m(r + 2, c), &m(r + 3, c), &m(r + 4, c),

        &m(r + 5, c));

  };


  FTensor::Index<'i', 3> i;

  FTensor::Index<'j', 3> j;


  auto v = getVolume();

  auto t_w = getFTensor0IntegrationWeight();

  auto t_approx_P_adjont_log_du_dP =

      getFTensor3FromMat<3, 3, size_symm>(dataAtPts->adjontPdUdPAtPts);


  int row_nb_base_functions = row_data.getN().size2();

  auto t_row_base_fun = row_data.getFTensor0N();

  for (int gg = 0; gg != nb_integration_pts; ++gg) {

    double a = v * t_w;

    int rr = 0;

    for (; rr != row_nb_dofs / 6; ++rr) {

      auto t_m = get_ftensor2(K, 6 * rr, 0);

      auto t_col_base_fun = col_data.getFTensor2N<3, 3>(gg, 0);

      for (int cc = 0; cc != col_nb_dofs; ++cc) {

        t_m(L) += a *

                  (t_approx_P_adjont_log_du_dP(i, j, L) * t_col_base_fun(i, j)) *

                  t_row_base_fun;

        ++t_m;

        ++t_col_base_fun;

      }

      ++t_row_base_fun;

    }

    for (; rr != row_nb_base_functions; ++rr)

      ++t_row_base_fun;

    ++t_w;

    ++t_approx_P_adjont_log_du_dP;

  }

  MoFEMFunctionReturn(0);

}


MoFEMErrorCode OpSpatialPhysical_du_du::integrate(EntData &row_data,

                                                  EntData &col_data) {

  MoFEMFunctionBegin;

  if (dataAtPts->physicsPtr->dependentVariablesPiola.size()) {

    CHKERR integratePiola(row_data, col_data);

  } else {

    CHKERR integrateHencky(row_data, col_data);

  }

  MoFEMFunctionReturn(0);

}


MoFEMErrorCode OpSpatialPhysical_du_du::integrateHencky(EntData &row_data,

                                                        EntData &col_data) {

  MoFEMFunctionBegin;


  FTensor::Index<'L', size_symm> L;

  FTensor::Index<'J', size_symm> J;

  auto t_L = symm_L_tensor();

  auto t_diff = diff_tensor();


  int nb_integration_pts = row_data.getN().size1();

  int row_nb_dofs = row_data.getIndices().size();

  int col_nb_dofs = col_data.getIndices().size();


  auto get_ftensor2 = [](MatrixDouble &m, const int r, const int c) {

    return FTensor::Tensor2<FTensor::PackPtr<double *, 6>, size_symm,

                            size_symm>(


        &m(r + 0, c + 0), &m(r + 0, c + 1), &m(r + 0, c + 2), &m(r + 0, c + 3),

        &m(r + 0, c + 4), &m(r + 0, c + 5),


        &m(r + 1, c + 0), &m(r + 1, c + 1), &m(r + 1, c + 2), &m(r + 1, c + 3),

        &m(r + 1, c + 4), &m(r + 1, c + 5),


        &m(r + 2, c + 0), &m(r + 2, c + 1), &m(r + 2, c + 2), &m(r + 2, c + 3),

        &m(r + 2, c + 4), &m(r + 2, c + 5),


        &m(r + 3, c + 0), &m(r + 3, c + 1), &m(r + 3, c + 2), &m(r + 3, c + 3),

        &m(r + 3, c + 4), &m(r + 3, c + 5),


        &m(r + 4, c + 0), &m(r + 4, c + 1), &m(r + 4, c + 2), &m(r + 4, c + 3),

        &m(r + 4, c + 4), &m(r + 4, c + 5),


        &m(r + 5, c + 0), &m(r + 5, c + 1), &m(r + 5, c + 2), &m(r + 5, c + 3),

        &m(r + 5, c + 4), &m(r + 5, c + 5)


    );

  };

  FTensor::Index<'i', 3> i;

  FTensor::Index<'j', 3> j;

  FTensor::Index<'k', 3> k;

  FTensor::Index<'l', 3> l;

  FTensor::Index<'m', 3> m;

  FTensor::Index<'n', 3> n;


  FTensor::Number<0> N0;

  FTensor::Number<1> N1;

  FTensor::Number<2> N2;


  auto v = getVolume();

  auto t_w = getFTensor0IntegrationWeight();


  auto t_approx_P_adjont_dstretch =

      getFTensor2FromMat<3, 3>(dataAtPts->adjontPdstretchAtPts);

  auto t_dot_log_u =

      getFTensor2SymmetricFromMat<3>(dataAtPts->logStretchDotTensorAtPts);

  auto t_u = getFTensor2SymmetricFromMat<3>(dataAtPts->stretchTensorAtPts);

  auto t_diff_u =

      getFTensor4DdgFromMat<3, 3, 1>(dataAtPts->diffStretchTensorAtPts);

  auto t_eigen_vals = getFTensor1FromMat<3>(dataAtPts->eigenVals);

  auto t_eigen_vecs = getFTensor2FromMat<3, 3>(dataAtPts->eigenVecs);

  auto &nbUniq = dataAtPts->nbUniq;


  int row_nb_base_functions = row_data.getN().size2();

  auto t_row_base_fun = row_data.getFTensor0N();


  auto t_D = getFTensor4DdgFromMat<3, 3, 0>(dataAtPts->matD);


  const double ts_a = getTSa();

  for (int gg = 0; gg != nb_integration_pts; ++gg) {

    double a = v * t_w;


    FTensor::Tensor2<double, size_symm, size_symm> t_dP;


    if (EshelbianCore::stretchSelector > LINEAR) {

      // Work of symmetric tensor on undefined tensor is equal to the work of

      // the symmetric part of it

      FTensor::Tensor2_symmetric<double, 3> t_sym;

      t_sym(i, j) = (t_approx_P_adjont_dstretch(i, j) ||

                     t_approx_P_adjont_dstretch(j, i));

      t_sym(i, j) /= 2.0;

      auto t_diff2_uP2 = EigenMatrix::getDiffDiffMat(

          t_eigen_vals, t_eigen_vecs, EshelbianCore::f, EshelbianCore::d_f,

          EshelbianCore::dd_f, t_sym, nbUniq[gg]);

      t_dP(L, J) =

          t_L(i, j, L) *

          ((t_diff2_uP2(i, j, k, l) + t_diff2_uP2(k, l, i, j)) * t_L(k, l, J)) /

          2.;

    } else {

      t_dP(L, J) = 0;

    }


    t_dP(L, J) -= (1 + alphaU * ts_a) *

                  (t_L(i, j, L) *

                   ((t_D(i, j, m, n) * t_diff(m, n, k, l)) * t_L(k, l, J)));


    int rr = 0;

    for (; rr != row_nb_dofs / 6; ++rr) {

      auto t_col_base_fun = col_data.getFTensor0N(gg, 0);

      auto t_m = get_ftensor2(K, 6 * rr, 0);

      for (int cc = 0; cc != col_nb_dofs / 6; ++cc) {

        const double b = a * t_row_base_fun * t_col_base_fun;

        t_m(L, J) += b * t_dP(L, J);

        ++t_m;

        ++t_col_base_fun;

      }

      ++t_row_base_fun;

    }


    for (; rr != row_nb_base_functions; ++rr) {

      ++t_row_base_fun;

    }


    ++t_w;

    ++t_approx_P_adjont_dstretch;

    ++t_dot_log_u;

    ++t_u;

    ++t_diff_u;

    ++t_eigen_vals;

    ++t_eigen_vecs;

  }

  MoFEMFunctionReturn(0);

}


MoFEMErrorCode OpSpatialPhysical_du_du::integratePiola(EntData &row_data,

                                                       EntData &col_data) {

  MoFEMFunctionBegin;


  FTensor::Index<'L', size_symm> L;

  FTensor::Index<'J', size_symm> J;

  auto t_L = symm_L_tensor();

  auto t_diff = diff_tensor();


  int nb_integration_pts = row_data.getN().size1();

  int row_nb_dofs = row_data.getIndices().size();

  int col_nb_dofs = col_data.getIndices().size();


  auto get_ftensor2 = [](MatrixDouble &m, const int r, const int c) {

    return FTensor::Tensor2<FTensor::PackPtr<double *, 6>, size_symm,

                            size_symm>(


        &m(r + 0, c + 0), &m(r + 0, c + 1), &m(r + 0, c + 2), &m(r + 0, c + 3),

        &m(r + 0, c + 4), &m(r + 0, c + 5),


        &m(r + 1, c + 0), &m(r + 1, c + 1), &m(r + 1, c + 2), &m(r + 1, c + 3),

        &m(r + 1, c + 4), &m(r + 1, c + 5),


        &m(r + 2, c + 0), &m(r + 2, c + 1), &m(r + 2, c + 2), &m(r + 2, c + 3),

        &m(r + 2, c + 4), &m(r + 2, c + 5),


        &m(r + 3, c + 0), &m(r + 3, c + 1), &m(r + 3, c + 2), &m(r + 3, c + 3),

        &m(r + 3, c + 4), &m(r + 3, c + 5),


        &m(r + 4, c + 0), &m(r + 4, c + 1), &m(r + 4, c + 2), &m(r + 4, c + 3),

        &m(r + 4, c + 4), &m(r + 4, c + 5),


        &m(r + 5, c + 0), &m(r + 5, c + 1), &m(r + 5, c + 2), &m(r + 5, c + 3),

        &m(r + 5, c + 4), &m(r + 5, c + 5)


    );

  };

  FTensor::Index<'i', 3> i;

  FTensor::Index<'j', 3> j;

  FTensor::Index<'k', 3> k;

  FTensor::Index<'l', 3> l;

  FTensor::Index<'m', 3> m;

  FTensor::Index<'n', 3> n;


  auto v = getVolume();

  auto t_w = getFTensor0IntegrationWeight();

  auto r_P_du = getFTensor4FromMat<3, 3, 3, 3>(dataAtPts->P_du);


  auto t_approx_P_adjont_dstretch =

      getFTensor2FromMat<3, 3>(dataAtPts->adjontPdstretchAtPts);

  auto t_P = getFTensor2FromMat<3, 3>(dataAtPts->PAtPts);

  auto t_dot_log_u =

      getFTensor2SymmetricFromMat<3>(dataAtPts->logStretchDotTensorAtPts);

  auto t_u = getFTensor2SymmetricFromMat<3>(dataAtPts->stretchTensorAtPts);

  auto t_diff_u =

      getFTensor4DdgFromMat<3, 3, 1>(dataAtPts->diffStretchTensorAtPts);

  auto t_eigen_vals = getFTensor1FromMat<3>(dataAtPts->eigenVals);

  auto t_eigen_vecs = getFTensor2FromMat<3, 3>(dataAtPts->eigenVecs);

  auto &nbUniq = dataAtPts->nbUniq;


  int row_nb_base_functions = row_data.getN().size2();

  auto t_row_base_fun = row_data.getFTensor0N();


  const double ts_a = getTSa();

  for (int gg = 0; gg != nb_integration_pts; ++gg) {

    double a = v * t_w;


    FTensor::Tensor2<double, 3, 3> t_deltaP;

    t_deltaP(i, j) = t_approx_P_adjont_dstretch(i, j) - t_P(i, j);


    // Work of symmetric tensor on undefined tensor is equal to the work of the

    // symmetric part of it

    FTensor::Tensor2<double, size_symm, size_symm> t_dP;


    if (EshelbianCore::stretchSelector > LINEAR) {

      FTensor::Tensor2_symmetric<double, 3> t_deltaP_sym;

      t_deltaP_sym(i, j) = (t_deltaP(i, j) || t_deltaP(j, i));

      t_deltaP_sym(i, j) /= 2.0;

      auto t_diff2_uP2 = EigenMatrix::getDiffDiffMat(

          t_eigen_vals, t_eigen_vecs, EshelbianCore::f, EshelbianCore::d_f,

          EshelbianCore::dd_f, t_deltaP_sym, nbUniq[gg]);

      t_dP(L, J) = t_L(i, j, L) * (t_diff2_uP2(i, j, k, l) * t_L(k, l, J));

    } else {

      t_dP(L, J) = 0;

    }


    FTensor::Tensor3<double, 3, 3, size_symm> t_Ldiff_u;

    t_Ldiff_u(i, j, L) = t_diff_u(i, j, m, n) * t_L(m, n, L);

    t_dP(L, J) -=

        t_Ldiff_u(i, j, L) * (r_P_du(i, j, k, l) * t_Ldiff_u(k, l, J));

    // viscous stress derivative

    t_dP(L, J) -=

        (alphaU * ts_a) * (t_L(i, j, L) * (t_diff(i, j, k, l) * t_L(k, l, J)));


    int rr = 0;

    for (; rr != row_nb_dofs / 6; ++rr) {

      auto t_col_base_fun = col_data.getFTensor0N(gg, 0);

      auto t_m = get_ftensor2(K, 6 * rr, 0);

      for (int cc = 0; cc != col_nb_dofs / 6; ++cc) {

        const double b = a * t_row_base_fun * t_col_base_fun;

        t_m(L, J) += b * t_dP(L, J);

        ++t_m;

        ++t_col_base_fun;

      }

      ++t_row_base_fun;

    }


    for (; rr != row_nb_base_functions; ++rr) {

      ++t_row_base_fun;

    }


    ++t_w;

    ++r_P_du;

    ++t_P;

    ++t_approx_P_adjont_dstretch;

    ++t_dot_log_u;

    ++t_u;

    ++t_diff_u;

    ++t_eigen_vals;

    ++t_eigen_vecs;

  }

  MoFEMFunctionReturn(0);

}


MoFEMErrorCode OpSpatialPhysical_du_domega::integrate(EntData &row_data,

                                                      EntData &col_data) {

  MoFEMFunctionBegin;


  FTensor::Index<'L', size_symm> L;

  auto t_L = symm_L_tensor();


  int row_nb_dofs = row_data.getIndices().size();

  int col_nb_dofs = col_data.getIndices().size();

  auto get_ftensor3 = [](MatrixDouble &m, const int r, const int c) {

    return FTensor::Tensor2<FTensor::PackPtr<double *, 3>, size_symm, 3>(


        &m(r + 0, c + 0), &m(r + 0, c + 1), &m(r + 0, c + 2),


        &m(r + 1, c + 0), &m(r + 1, c + 1), &m(r + 1, c + 2),


        &m(r + 2, c + 0), &m(r + 2, c + 1), &m(r + 2, c + 2),


        &m(r + 3, c + 0), &m(r + 3, c + 1), &m(r + 3, c + 2),


        &m(r + 4, c + 0), &m(r + 4, c + 1), &m(r + 4, c + 2),


        &m(r + 5, c + 0), &m(r + 5, c + 1), &m(r + 5, c + 2)


    );

  };

  FTensor::Index<'i', 3> i;

  FTensor::Index<'j', 3> j;

  FTensor::Index<'k', 3> k;

  FTensor::Index<'m', 3> m;

  FTensor::Index<'n', 3> n;


  auto v = getVolume();

  auto t_w = getFTensor0IntegrationWeight();

  auto t_approx_P_adjont_log_du_domega =

      getFTensor2FromMat<3, size_symm>(dataAtPts->adjontPdUdOmegaAtPts);


  int row_nb_base_functions = row_data.getN().size2();

  auto t_row_base_fun = row_data.getFTensor0N();


  int nb_integration_pts = row_data.getN().size1();


  for (int gg = 0; gg != nb_integration_pts; ++gg) {

    double a = v * t_w;


    int rr = 0;

    for (; rr != row_nb_dofs / 6; ++rr) {

      auto t_col_base_fun = col_data.getFTensor0N(gg, 0);

      auto t_m = get_ftensor3(K, 6 * rr, 0);

      for (int cc = 0; cc != col_nb_dofs / 3; ++cc) {

        double v = a * t_row_base_fun * t_col_base_fun;

        t_m(L, k) += v * t_approx_P_adjont_log_du_domega(k, L);

        ++t_m;

        ++t_col_base_fun;

      }

      ++t_row_base_fun;

    }


    for (; rr != row_nb_base_functions; ++rr)

      ++t_row_base_fun;


    ++t_w;

    ++t_approx_P_adjont_log_du_domega;

  }


  MoFEMFunctionReturn(0);

}


MoFEMErrorCode OpSpatialRotation_domega_dP::integrate(EntData &row_data,

                                                      EntData &col_data) {

  MoFEMFunctionBegin;

  int nb_integration_pts = getGaussPts().size2();

  int row_nb_dofs = row_data.getIndices().size();

  int col_nb_dofs = col_data.getIndices().size();

  auto get_ftensor2 = [](MatrixDouble &m, const int r, const int c) {

    return FTensor::Tensor2<FTensor::PackPtr<double *, 3>, 3, 3>(


        &m(r + 0, c + 0), &m(r + 0, c + 1), &m(r + 0, c + 2),


        &m(r + 1, c + 0), &m(r + 1, c + 1), &m(r + 1, c + 2),


        &m(r + 2, c + 0), &m(r + 2, c + 1), &m(r + 2, c + 2)


    );

  };

  FTensor::Index<'i', 3> i;

  FTensor::Index<'j', 3> j;

  FTensor::Index<'k', 3> k;

  FTensor::Index<'l', 3> l;

  FTensor::Index<'m', 3> m;

  FTensor::Index<'n', 3> n;

  auto v = getVolume();

  auto t_w = getFTensor0IntegrationWeight();

  auto t_levi_kirchoff_dP =

      getFTensor3FromMat<3, 3, 3>(dataAtPts->leviKirchoffdPAtPts);


  int row_nb_base_functions = row_data.getN().size2();

  auto t_row_base_fun = row_data.getFTensor0N();


  for (int gg = 0; gg != nb_integration_pts; ++gg) {

    double a = v * t_w;

    int rr = 0;

    for (; rr != row_nb_dofs / 3; ++rr) {

      double b = a * t_row_base_fun;

      auto t_col_base_fun = col_data.getFTensor1N<3>(gg, 0);

      auto t_m = get_ftensor2(K, 3 * rr, 0);

      for (int cc = 0; cc != col_nb_dofs / 3; ++cc) {

        t_m(k, i) += b * (t_levi_kirchoff_dP(i, l, k) * t_col_base_fun(l));

        ++t_m;

        ++t_col_base_fun;

      }

      ++t_row_base_fun;

    }

    for (; rr != row_nb_base_functions; ++rr) {

      ++t_row_base_fun;

    }


    ++t_w;

    ++t_levi_kirchoff_dP;

  }

  MoFEMFunctionReturn(0);

}


MoFEMErrorCode OpSpatialRotation_domega_dBubble::integrate(EntData &row_data,

                                                           EntData &col_data) {

  MoFEMFunctionBegin;

  int nb_integration_pts = getGaussPts().size2();

  int row_nb_dofs = row_data.getIndices().size();

  int col_nb_dofs = col_data.getIndices().size();


  auto get_ftensor1 = [](MatrixDouble &m, const int r, const int c) {

    return FTensor::Tensor1<FTensor::PackPtr<double *, 1>, 3>(

        &m(r + 0, c), &m(r + 1, c), &m(r + 2, c));

  };


  FTensor::Index<'i', 3> i;

  FTensor::Index<'j', 3> j;

  FTensor::Index<'k', 3> k;

  FTensor::Index<'l', 3> l;

  FTensor::Index<'m', 3> m;


  auto v = getVolume();

  auto t_w = getFTensor0IntegrationWeight();

  auto t_levi_kirchoff_dP =

      getFTensor3FromMat<3, 3, 3>(dataAtPts->leviKirchoffdPAtPts);


  int row_nb_base_functions = row_data.getN().size2();

  auto t_row_base_fun = row_data.getFTensor0N();


  for (int gg = 0; gg != nb_integration_pts; ++gg) {

    double a = v * t_w;

    int rr = 0;

    for (; rr != row_nb_dofs / 3; ++rr) {

      double b = a * t_row_base_fun;

      auto t_col_base_fun = col_data.getFTensor2N<3, 3>(gg, 0);

      auto t_m = get_ftensor1(K, 3 * rr, 0);

      for (int cc = 0; cc != col_nb_dofs; ++cc) {

        t_m(k) += b * (t_levi_kirchoff_dP(i, j, k) * t_col_base_fun(i, j));

        ++t_m;

        ++t_col_base_fun;

      }

      ++t_row_base_fun;

    }


    for (; rr != row_nb_base_functions; ++rr) {

      ++t_row_base_fun;

    }

    ++t_w;

    ++t_levi_kirchoff_dP;

  }

  MoFEMFunctionReturn(0);

}


MoFEMErrorCode OpSpatialRotation_domega_domega::integrate(EntData &row_data,

                                                          EntData &col_data) {

  MoFEMFunctionBegin;

  int nb_integration_pts = getGaussPts().size2();

  int row_nb_dofs = row_data.getIndices().size();

  int col_nb_dofs = col_data.getIndices().size();

  auto get_ftensor2 = [](MatrixDouble &m, const int r, const int c) {

    return FTensor::Tensor2<FTensor::PackPtr<double *, 3>, 3, 3>(


        &m(r + 0, c + 0), &m(r + 0, c + 1), &m(r + 0, c + 2),


        &m(r + 1, c + 0), &m(r + 1, c + 1), &m(r + 1, c + 2),


        &m(r + 2, c + 0), &m(r + 2, c + 1), &m(r + 2, c + 2)


    );

  };

  FTensor::Index<'i', 3> i;

  FTensor::Index<'j', 3> j;

  FTensor::Index<'k', 3> k;

  FTensor::Index<'l', 3> l;

  FTensor::Index<'m', 3> m;

  FTensor::Index<'n', 3> n;


  auto v = getVolume();

  auto t_w = getFTensor0IntegrationWeight();

  auto t_levi_kirchoff_domega =

      getFTensor2FromMat<3, 3>(dataAtPts->leviKirchoffdOmegaAtPts);

  int row_nb_base_functions = row_data.getN().size2();

  auto t_row_base_fun = row_data.getFTensor0N();

  for (int gg = 0; gg != nb_integration_pts; ++gg) {

    double a = v * t_w;

    int rr = 0;

    for (; rr != row_nb_dofs / 3; ++rr) {

      auto t_m = get_ftensor2(K, 3 * rr, 0);

      const double b = a * t_row_base_fun;

      auto t_col_base_fun = col_data.getFTensor0N(gg, 0);

      for (int cc = 0; cc != col_nb_dofs / 3; ++cc) {

        t_m(k, l) += (b * t_col_base_fun) * t_levi_kirchoff_domega(k, l);

        ++t_m;

        ++t_col_base_fun;

      }

      ++t_row_base_fun;

    }

    for (; rr != row_nb_base_functions; ++rr) {

      ++t_row_base_fun;

    }

    ++t_w;

    ++t_levi_kirchoff_domega;

  }

  MoFEMFunctionReturn(0);

}


MoFEMErrorCode OpSpatialConsistency_dP_domega::integrate(EntData &row_data,

                                                         EntData &col_data) {

  MoFEMFunctionBegin;


  int nb_integration_pts = row_data.getN().size1();

  int row_nb_dofs = row_data.getIndices().size();

  int col_nb_dofs = col_data.getIndices().size();


  auto get_ftensor2 = [](MatrixDouble &m, const int r, const int c) {

    return FTensor::Tensor2<FTensor::PackPtr<double *, 3>, 3, 3>(


        &m(r + 0, c + 0), &m(r + 0, c + 1), &m(r + 0, c + 2),


        &m(r + 1, c + 0), &m(r + 1, c + 1), &m(r + 1, c + 2),


        &m(r + 2, c + 0), &m(r + 2, c + 1), &m(r + 2, c + 2)


    );

  };


  FTensor::Index<'i', 3> i;

  FTensor::Index<'j', 3> j;

  FTensor::Index<'k', 3> k;

  FTensor::Index<'l', 3> l;

  FTensor::Index<'m', 3> m;

  FTensor::Index<'n', 3> n;


  auto v = getVolume();

  auto t_w = getFTensor0IntegrationWeight();

  auto t_h_domega = getFTensor3FromMat<3, 3, 3>(dataAtPts->hdOmegaAtPts);

  int row_nb_base_functions = row_data.getN().size2() / 3;

  auto t_row_base_fun = row_data.getFTensor1N<3>();


  const double ts_a = getTSa();


  for (int gg = 0; gg != nb_integration_pts; ++gg) {

    double a = v * t_w;


    constexpr auto t_kd = FTensor::Kronecker_Delta<int>();


    int rr = 0;

    for (; rr != row_nb_dofs / 3; ++rr) {


      FTensor::Tensor2<double, 3, 3> t_PRT;

      t_PRT(i, k) = t_row_base_fun(j) * t_h_domega(i, j, k);


      auto t_col_base_fun = col_data.getFTensor0N(gg, 0);

      auto t_m = get_ftensor2(K, 3 * rr, 0);

      for (int cc = 0; cc != col_nb_dofs / 3; ++cc) {

        t_m(i, j) += (a * t_col_base_fun) * t_PRT(i, j);

        ++t_m;

        ++t_col_base_fun;

      }


      ++t_row_base_fun;

    }


    for (; rr != row_nb_base_functions; ++rr)

      ++t_row_base_fun;

    ++t_w;

    ++t_h_domega;

  }

  MoFEMFunctionReturn(0);

}


MoFEMErrorCode

OpSpatialConsistency_dBubble_domega::integrate(EntData &row_data,

                                               EntData &col_data) {

  MoFEMFunctionBegin;


  int nb_integration_pts = row_data.getN().size1();

  int row_nb_dofs = row_data.getIndices().size();

  int col_nb_dofs = col_data.getIndices().size();


  auto get_ftensor2 = [](MatrixDouble &m, const int r, const int c) {

    return FTensor::Tensor1<FTensor::PackPtr<double *, 3>, 3>(

        &m(r, c + 0), &m(r, c + 1), &m(r, c + 2));

  };


  FTensor::Index<'i', 3> i;

  FTensor::Index<'j', 3> j;

  FTensor::Index<'k', 3> k;

  FTensor::Index<'l', 3> l;

  FTensor::Index<'m', 3> m;

  FTensor::Index<'n', 3> n;


  auto v = getVolume();

  auto t_w = getFTensor0IntegrationWeight();

  auto t_h_domega = getFTensor3FromMat<3, 3, 3>(dataAtPts->hdOmegaAtPts);

  int row_nb_base_functions = row_data.getN().size2() / 9;

  auto t_row_base_fun = row_data.getFTensor2N<3, 3>();


  const double ts_a = getTSa();


  for (int gg = 0; gg != nb_integration_pts; ++gg) {

    double a = v * t_w;


    int rr = 0;

    for (; rr != row_nb_dofs; ++rr) {


      FTensor::Tensor1<double, 3> t_PRT;

      t_PRT(k) = t_row_base_fun(i, j) * t_h_domega(i, j, k);


      auto t_col_base_fun = col_data.getFTensor0N(gg, 0);

      auto t_m = get_ftensor2(K, rr, 0);

      for (int cc = 0; cc != col_nb_dofs / 3; ++cc) {

        t_m(j) += (a * t_col_base_fun) * t_PRT(j);

        ++t_m;

        ++t_col_base_fun;

      }


      ++t_row_base_fun;

    }


    for (; rr != row_nb_base_functions; ++rr)

      ++t_row_base_fun;


    ++t_w;

    ++t_h_domega;

  }

  MoFEMFunctionReturn(0);

}


MoFEMErrorCode OpPostProcDataStructure::doWork(int side, EntityType type,

                                               EntData &data) {

  MoFEMFunctionBegin;


  auto create_tag = [this](const std::string tag_name, const int size) {

    double def_VAL[] = {0, 0, 0, 0, 0, 0, 0, 0, 0};

    Tag th;

    CHKERR postProcMesh.tag_get_handle(tag_name.c_str(), size, MB_TYPE_DOUBLE,

                                       th, MB_TAG_CREAT | MB_TAG_SPARSE,

                                       def_VAL);

    return th;

  };


  Tag th_w = create_tag("SpatialDisplacement", 3);

  Tag th_omega = create_tag("Omega", 3);

  Tag th_approxP = create_tag("Piola1Stress", 9);

  Tag th_sigma = create_tag("CauchyStress", 9);

  Tag th_log_u = create_tag("LogSpatialStretch", 9);

  Tag th_u = create_tag("SpatialStretch", 9);

  Tag th_h = create_tag("h", 9);

  Tag th_X = create_tag("X", 3);

  Tag th_detF = create_tag("detF", 1);

  Tag th_angular_momentum = create_tag("AngularMomentum", 3);


  Tag th_u_eig_vec = create_tag("SpatialStretchEigenVec", 9);

  Tag th_u_eig_vals = create_tag("SpatialStretchEigenVals", 3);

  Tag th_traction = create_tag("traction", 3);


  Tag th_disp = create_tag("U", 3);

  Tag th_disp_error = create_tag("U_ERROR", 1);


  auto t_w = getFTensor1FromMat<3>(dataAtPts->wL2AtPts);

  auto t_omega = getFTensor1FromMat<3>(dataAtPts->rotAxisAtPts);

  auto t_h = getFTensor2FromMat<3, 3>(dataAtPts->hAtPts);

  auto t_log_u =

      getFTensor2SymmetricFromMat<3>(dataAtPts->logStretchTensorAtPts);

  auto t_u = getFTensor2SymmetricFromMat<3>(dataAtPts->stretchTensorAtPts);

  auto t_R = getFTensor2FromMat<3, 3>(dataAtPts->rotMatAtPts);

  auto t_approx_P = getFTensor2FromMat<3, 3>(dataAtPts->approxPAtPts);

  auto t_levi_kirchoff = getFTensor1FromMat<3>(dataAtPts->leviKirchoffAtPts);

  auto t_coords = getFTensor1CoordsAtGaussPts();

  auto t_normal = getFTensor1NormalsAtGaussPts();

  auto t_disp = getFTensor1FromMat<3>(dataAtPts->wH1AtPts);


  FTensor::Index<'i', 3> i;

  FTensor::Index<'j', 3> j;

  FTensor::Index<'k', 3> k;

  FTensor::Index<'l', 3> l;


  auto set_float_precision = [](const double x) {

    if (std::abs(x) < std::numeric_limits<float>::epsilon())

      return 0.;

    else

      return x;

  };


  // scalars

  auto save_scal_tag = [&](auto &th, auto v, const int gg) {

    MoFEMFunctionBegin;

    v = set_float_precision(v);

    CHKERR postProcMesh.tag_set_data(th, &mapGaussPts[gg], 1, &v);

    MoFEMFunctionReturn(0);

  };


  // vectors

  VectorDouble3 v(3);

  FTensor::Tensor1<FTensor::PackPtr<double *, 0>, 3> t_v(&v[0], &v[1], &v[2]);

  auto save_vec_tag = [&](auto &th, auto &t_d, const int gg) {

    MoFEMFunctionBegin;

    t_v(i) = t_d(i);

    for (auto &a : v.data())

      a = set_float_precision(a);

    CHKERR postProcMesh.tag_set_data(th, &mapGaussPts[gg], 1,

                                     &*v.data().begin());

    MoFEMFunctionReturn(0);

  };


  // tensors


  MatrixDouble3by3 m(3, 3);

  FTensor::Tensor2<FTensor::PackPtr<double *, 0>, 3, 3> t_m(

      &m(0, 0), &m(0, 1), &m(0, 2),


      &m(1, 0), &m(1, 1), &m(1, 2),


      &m(2, 0), &m(2, 1), &m(2, 2));


  auto save_mat_tag = [&](auto &th, auto &t_d, const int gg) {

    MoFEMFunctionBegin;

    t_m(i, j) = t_d(i, j);

    for (auto &v : m.data())

      v = set_float_precision(v);

    CHKERR postProcMesh.tag_set_data(th, &mapGaussPts[gg], 1,

                                     &*m.data().begin());

    MoFEMFunctionReturn(0);

  };


  const auto nb_gauss_pts = getGaussPts().size2();

  for (auto gg = 0; gg != nb_gauss_pts; ++gg) {


    FTensor::Tensor1<double, 3> t_traction;

    t_traction(i) = t_approx_P(i, j) * t_normal(j) / t_normal.l2();


    // vectors

    CHKERR save_vec_tag(th_w, t_w, gg);

    CHKERR save_vec_tag(th_X, t_coords, gg);

    CHKERR save_vec_tag(th_omega, t_omega, gg);

    CHKERR save_vec_tag(th_traction, t_traction, gg);


    // tensors

    CHKERR save_mat_tag(th_h, t_h, gg);


    FTensor::Tensor2<double, 3, 3> t_log_u_tmp;

    for (int ii = 0; ii != 3; ++ii)

      for (int jj = 0; jj != 3; ++jj)

        t_log_u_tmp(ii, jj) = t_log_u(ii, jj);


    CHKERR save_mat_tag(th_log_u, t_log_u_tmp, gg);


    FTensor::Tensor2<double, 3, 3> t_u_tmp;

    for (int ii = 0; ii != 3; ++ii)

      for (int jj = 0; jj != 3; ++jj)

        t_u_tmp(ii, jj) = t_u(ii, jj);


    CHKERR save_mat_tag(th_u, t_u_tmp, gg);

    CHKERR save_mat_tag(th_approxP, t_approx_P, gg);

    CHKERR save_vec_tag(th_disp, t_disp, gg);


    double u_error = sqrt((t_disp(i) - t_w(i)) * (t_disp(i) - t_w(i)));

    CHKERR save_scal_tag(th_disp_error, u_error, gg);


    const double jac = determinantTensor3by3(t_h);

    FTensor::Tensor2<double, 3, 3> t_cauchy;

    t_cauchy(i, j) = (1. / jac) * (t_approx_P(i, k) * t_h(j, k));

    CHKERR save_mat_tag(th_sigma, t_cauchy, gg);

    CHKERR postProcMesh.tag_set_data(th_detF, &mapGaussPts[gg], 1, &jac);


    FTensor::Tensor1<double, 3> t_levi;

    t_levi(k) = t_levi_kirchoff(k);

    CHKERR postProcMesh.tag_set_data(th_angular_momentum, &mapGaussPts[gg], 1,

                                     &t_levi(0));


    auto get_eiegn_vector_symmetric = [&](auto &t_u) {

      MoFEMFunctionBegin;


      for (int ii = 0; ii != 3; ++ii)

        for (int jj = 0; jj != 3; ++jj)

          t_m(ii, jj) = t_u(ii, jj);


      VectorDouble3 eigen_values(3);

      auto t_eigen_values = getFTensor1FromArray<3>(eigen_values);

      CHKERR computeEigenValuesSymmetric(t_m, t_eigen_values);


      CHKERR postProcMesh.tag_set_data(th_u_eig_vec, &mapGaussPts[gg], 1,

                                       &*m.data().begin());

      CHKERR postProcMesh.tag_set_data(th_u_eig_vals, &mapGaussPts[gg], 1,

                                       &*eigen_values.data().begin());


      MoFEMFunctionReturn(0);

    };


    CHKERR get_eiegn_vector_symmetric(t_u);


    ++t_w;

    ++t_h;

    ++t_log_u;

    ++t_u;

    ++t_omega;

    ++t_R;

    ++t_approx_P;

    ++t_levi_kirchoff;

    ++t_coords;

    ++t_normal;

    ++t_disp;

  }


  MoFEMFunctionReturn(0);

}


MoFEMErrorCode

OpCalculateStrainEnergy::doWork(int side, EntityType type,

                                EntitiesFieldData::EntData &data) {

  MoFEMFunctionBegin;

  if (type == MBTET) {

    int nb_integration_pts = data.getN().size1();

    auto v = getVolume();

    auto t_w = getFTensor0IntegrationWeight();

    auto t_P = getFTensor2FromMat<3, 3>(dataAtPts->approxPAtPts);

    auto t_h = getFTensor2FromMat<3, 3>(dataAtPts->hAtPts);


    FTensor::Index<'i', 3> i;

    FTensor::Index<'J', 3> J;


    for (int gg = 0; gg != nb_integration_pts; ++gg) {

      const double a = t_w * v;

      // FIXME: this is wrong, energy should be calculated in material

      (*energy) += a * t_P(i, J) * t_h(i, J);

      ++t_w;

      ++t_P;

      ++t_h;

    }

  }

  MoFEMFunctionReturn(0);

}


} // namespace EshelbianPlasticity

J
static Index< 'J', 3 > J
Definition: BasicFeTools.hpp:93

N2
static Number< 2 > N2
Definition: BasicFeTools.hpp:101

N1
static Number< 1 > N1
Definition: BasicFeTools.hpp:100

N0
static Number< 0 > N0
Definition: BasicFeTools.hpp:99

EshelbianPlasticity.hpp
Eshelbian plasticity interface.

MatrixFunction.hpp

MoFEM.hpp

a
constexpr double a
Definition: approx_sphere.cpp:30

eps
static const double eps
Definition: check_base_functions_derivatives_on_tet.cpp:11

EntityHandle

EntityType

FTensor::Ddg
Definition: Ddg_value.hpp:8

FTensor::Dg
Definition: Dg_value.hpp:10

FTensor::Index
Definition: Index.hpp:24

FTensor::Kronecker_Delta_symmetric
Kronecker Delta class symmetric.
Definition: Kronecker_Delta.hpp:49

FTensor::Kronecker_Delta
Kronecker Delta class.
Definition: Kronecker_Delta.hpp:15

FTensor::Number
Definition: Number.hpp:12

FTensor::Tensor0
Definition: Tensor0.hpp:17

FTensor::Tensor1
Definition: Tensor1_value.hpp:9

FTensor::Tensor1::l2
T l2() const
Definition: Tensor1_value.hpp:84

FTensor::Tensor2_symmetric
Definition: Tensor2_symmetric_value.hpp:14

FTensor::Tensor2
Definition: Tensor2_value.hpp:17

FTensor::Tensor3
Definition: Tensor3_value.hpp:13

FTensor::Tensor4
Definition: Tensor4_value.hpp:19

MatrixBoundedArray< double, 9 >

UBlasMatrix< double >

MF_ZERO
@ MF_ZERO
Definition: definitions.h:98

MoFEMFunctionReturnHot
#define MoFEMFunctionReturnHot(a)
Last executable line of each PETSc function used for error handling. Replaces return()
Definition: definitions.h:447

MoFEMFunctionBegin
#define MoFEMFunctionBegin
First executable line of each MoFEM function, used for error handling. Final line of MoFEM functions ...
Definition: definitions.h:346

MOFEM_OPERATION_UNSUCCESSFUL
@ MOFEM_OPERATION_UNSUCCESSFUL
Definition: definitions.h:34

MoFEMFunctionReturn
#define MoFEMFunctionReturn(a)
Last executable line of each PETSc function used for error handling. Replaces return()
Definition: definitions.h:416

CHKERR
#define CHKERR
Inline error check.
Definition: definitions.h:535

n
FTensor::Index< 'n', SPACE_DIM > n
Definition: fluid_structure_eigenproblem.cpp:66

m
FTensor::Index< 'm', SPACE_DIM > m
Definition: fluid_structure_eigenproblem.cpp:65

t_kd
constexpr auto t_kd
Definition: free_surface.cpp:137

MoFEM::CoreInterface::loop_finite_elements
virtual MoFEMErrorCode loop_finite_elements(const std::string problem_name, const std::string &fe_name, FEMethod &method, boost::shared_ptr< NumeredEntFiniteElement_multiIndex > fe_ptr=nullptr, MoFEMTypes bh=MF_EXIST, CacheTupleWeakPtr cache_ptr=CacheTupleSharedPtr(), int verb=DEFAULT_VERBOSITY)=0
Make a loop over finite elements.

i
FTensor::Index< 'i', SPACE_DIM > i
Definition: hcurl_divergence_operator_2d.cpp:27

c
const double c
speed of light (cm/ns)
Definition: initial_diffusion.cpp:39

D
double D
Definition: initial_diffusion.cpp:44

v
const double v
phase velocity of light in medium (cm/ns)
Definition: initial_diffusion.cpp:40

lapack_wrap.h

lapack_dposv
static __CLPK_integer lapack_dposv(char uplo, __CLPK_integer n, __CLPK_integer nrhs, __CLPK_doublereal *a, __CLPK_integer lda, __CLPK_doublereal *b, __CLPK_integer ldb)
Definition: lapack_wrap.h:211

ts_ctx
MoFEM::TsCtx * ts_ctx
Definition: level_set.cpp:1884

l
FTensor::Index< 'l', 3 > l
Definition: matrix_function.cpp:21

j
FTensor::Index< 'j', 3 > j
Definition: matrix_function.cpp:19

k
FTensor::Index< 'k', 3 > k
Definition: matrix_function.cpp:20

EigenMatrix::getDiffMat
FTensor::Ddg< double, 3, 3 > getDiffMat(Val< double, 3 > &t_val, Vec< double, 3 > &t_vec, Fun< double > f, Fun< double > d_f, const int nb)
Get the Diff Mat object.
Definition: MatrixFunction.cpp:64

EigenMatrix::getMat
FTensor::Tensor2_symmetric< double, 3 > getMat(Val< double, 3 > &t_val, Vec< double, 3 > &t_vec, Fun< double > f)
Get the Mat object.
Definition: MatrixFunction.cpp:53

EigenMatrix::getDiffDiffMat
FTensor::Ddg< double, 3, 3 > getDiffDiffMat(Val< double, 3 > &t_val, Vec< double, 3 > &t_vec, Fun< double > f, Fun< double > d_f, Fun< double > dd_f, FTensor::Tensor2< double, 3, 3 > &t_S, const int nb)
Definition: MatrixFunction.cpp:78

EshelbianPlasticity
Definition: CGGTonsorialBubbleBase.hpp:11

EshelbianPlasticity::get_uniq_nb
auto get_uniq_nb(double *ptr)
Definition: EshelbianOperators.cpp:180

EshelbianPlasticity::diff_tensor
auto diff_tensor()
Definition: EshelbianOperators.cpp:22

EshelbianPlasticity::symm_L_tensor
auto symm_L_tensor()
Definition: EshelbianOperators.cpp:33

EshelbianPlasticity::LINEAR
@ LINEAR
Definition: EshelbianPlasticity.hpp:21

EshelbianPlasticity::LOG
@ LOG
Definition: EshelbianPlasticity.hpp:21

EshelbianPlasticity::RotSelector
RotSelector
Definition: EshelbianPlasticity.hpp:20

EshelbianPlasticity::SMALL_ROT
@ SMALL_ROT
Definition: EshelbianPlasticity.hpp:20

EshelbianPlasticity::MODERATE_ROT
@ MODERATE_ROT
Definition: EshelbianPlasticity.hpp:20

EshelbianPlasticity::LARGE_ROT
@ LARGE_ROT
Definition: EshelbianPlasticity.hpp:20

EshelbianPlasticity::get_diff_rotation_form_vector
auto get_diff_rotation_form_vector(FTensor::Tensor1< T, 3 > &t_omega, RotSelector rotSelector=LARGE_ROT)
Definition: EshelbianOperators.cpp:92

EshelbianPlasticity::size_symm
static constexpr auto size_symm
Definition: EshelbianOperators.cpp:20

EshelbianPlasticity::sort_eigen_vals
auto sort_eigen_vals(FTensor::Tensor1< double, DIM > &eig, FTensor::Tensor2< double, DIM, DIM > &eigen_vec)
Definition: EshelbianOperators.cpp:191

EshelbianPlasticity::get_rotation_form_vector
auto get_rotation_form_vector(FTensor::Tensor1< T, 3 > &t_omega, RotSelector rotSelector=LARGE_ROT)
Definition: EshelbianOperators.cpp:56

EshelbianPlasticity::is_eq
auto is_eq(const double &a, const double &b)
Definition: EshelbianOperators.cpp:176

EshelbianPlasticity::get_diff2_rotation_form_vector
auto get_diff2_rotation_form_vector(FTensor::Tensor1< T, 3 > &t_omega, RotSelector rotSelector=LARGE_ROT)
Definition: EshelbianOperators.cpp:140

FTensor
Tensors class implemented by Walter Landry.
Definition: FTensor.hpp:51

MoFEM::Exceptions::MoFEMErrorCode
PetscErrorCode MoFEMErrorCode
MoFEM/PETSc error code.
Definition: Exceptions.hpp:56

MoFEM::Types::VectorDouble3
VectorBoundedArray< double, 3 > VectorDouble3
Definition: Types.hpp:92

MoFEM
implementation of Data Operators for Forces and Sources
Definition: Common.hpp:10

MoFEM::L
VectorDouble L
Definition: Projection10NodeCoordsOnField.cpp:124

MoFEM::th
Tag th
Definition: Projection10NodeCoordsOnField.cpp:122

MoFEM::computeEigenValuesSymmetric
MoFEMErrorCode computeEigenValuesSymmetric(const MatrixDouble &mat, VectorDouble &eig, MatrixDouble &eigen_vec)
compute eigenvalues of a symmetric matrix using lapack dsyev
Definition: Templates.hpp:1469

MoFEM::determinantTensor3by3
static auto determinantTensor3by3(T &t)
Calculate the determinant of a 3x3 matrix or a tensor of rank 2.
Definition: Templates.hpp:1557

t
constexpr double t
plate stiffness
Definition: plate.cpp:59

EshelbianPlasticity::EshelbianCore::dd_f
static boost::function< double(const double)> dd_f
Definition: EshelbianPlasticity.hpp:832

EshelbianPlasticity::EshelbianCore::gradApperoximator
static enum RotSelector gradApperoximator
Definition: EshelbianPlasticity.hpp:826

EshelbianPlasticity::EshelbianCore::inv_f
static boost::function< double(const double)> inv_f
Definition: EshelbianPlasticity.hpp:833

EshelbianPlasticity::EshelbianCore::stretchSelector
static enum StretchSelector stretchSelector
Definition: EshelbianPlasticity.hpp:827

EshelbianPlasticity::EshelbianCore::d_f
static boost::function< double(const double)> d_f
Definition: EshelbianPlasticity.hpp:831

EshelbianPlasticity::EshelbianCore::rotSelector
static enum RotSelector rotSelector
Definition: EshelbianPlasticity.hpp:825

EshelbianPlasticity::EshelbianCore::f
static boost::function< double(const double)> f
Definition: EshelbianPlasticity.hpp:830

EshelbianPlasticity::FaceRule
Definition: EshelbianPlasticity.cpp:723

EshelbianPlasticity::FeTractionBc::preProcess
MoFEMErrorCode preProcess()
Definition: EshelbianOperators.cpp:917

EshelbianPlasticity::FeTractionBc::bcData
boost::shared_ptr< TractionBcVec > bcData
Definition: EshelbianPlasticity.hpp:607

EshelbianPlasticity::FeTractionBc::mField
MoFEM::Interface & mField
Definition: EshelbianPlasticity.hpp:606

EshelbianPlasticity::OpAssembleBasic< VolUserDataOperator >::K
MatrixDouble K
local tangent matrix
Definition: EshelbianPlasticity.hpp:354

EshelbianPlasticity::OpAssembleBasic< VolUserDataOperator >::nF
VectorDouble nF
local right hand side vector
Definition: EshelbianPlasticity.hpp:353

EshelbianPlasticity::OpAssembleBasic< VolUserDataOperator >::dataAtPts
boost::shared_ptr< DataAtIntegrationPts > dataAtPts
data at integration pts
Definition: EshelbianPlasticity.hpp:339

EshelbianPlasticity::OpCalculateRotationAndSpatialGradient::doWork
MoFEMErrorCode doWork(int side, EntityType type, EntData &data)
Definition: EshelbianOperators.cpp:230

EshelbianPlasticity::OpCalculateRotationAndSpatialGradient::dataAtPts
boost::shared_ptr< DataAtIntegrationPts > dataAtPts
data at integration pts
Definition: EshelbianPlasticity.hpp:472

EshelbianPlasticity::OpCalculateStrainEnergy::doWork
MoFEMErrorCode doWork(int side, EntityType type, EntitiesFieldData::EntData &data)
Definition: EshelbianOperators.cpp:2074

EshelbianPlasticity::OpCalculateStrainEnergy::dataAtPts
boost::shared_ptr< DataAtIntegrationPts > dataAtPts
Definition: EshelbianPlasticity.hpp:819

EshelbianPlasticity::OpDispBc::bcDispPtr
boost::shared_ptr< BcDispVec > bcDispPtr
Definition: EshelbianPlasticity.hpp:539

EshelbianPlasticity::OpDispBc::integrate
MoFEMErrorCode integrate(EntData &data)
Definition: EshelbianOperators.cpp:811

EshelbianPlasticity::OpPostProcDataStructure::postProcMesh
moab::Interface & postProcMesh
Definition: EshelbianPlasticity.hpp:766

EshelbianPlasticity::OpPostProcDataStructure::mapGaussPts
std::vector< EntityHandle > & mapGaussPts
Definition: EshelbianPlasticity.hpp:767

EshelbianPlasticity::OpPostProcDataStructure::doWork
MoFEMErrorCode doWork(int side, EntityType type, EntData &data)
Definition: EshelbianOperators.cpp:1894

EshelbianPlasticity::OpPostProcDataStructure::dataAtPts
boost::shared_ptr< DataAtIntegrationPts > dataAtPts
Definition: EshelbianPlasticity.hpp:768

EshelbianPlasticity::OpRotationBc::integrate
MoFEMErrorCode integrate(EntData &data)
Definition: EshelbianOperators.cpp:858

EshelbianPlasticity::OpRotationBc::bcRotPtr
boost::shared_ptr< BcRotVec > bcRotPtr
Definition: EshelbianPlasticity.hpp:560

EshelbianPlasticity::OpSpatialConsistency_dBubble_domega::integrate
MoFEMErrorCode integrate(EntData &row_data, EntData &col_data)
Definition: EshelbianOperators.cpp:1837

EshelbianPlasticity::OpSpatialConsistency_dP_domega::integrate
MoFEMErrorCode integrate(EntData &row_data, EntData &col_data)
Definition: EshelbianOperators.cpp:1771

EshelbianPlasticity::OpSpatialConsistencyBubble::integrate
MoFEMErrorCode integrate(EntData &data)
Definition: EshelbianOperators.cpp:731

EshelbianPlasticity::OpSpatialConsistencyDivTerm::integrate
MoFEMErrorCode integrate(EntData &data)
Definition: EshelbianOperators.cpp:776

EshelbianPlasticity::OpSpatialConsistencyP::integrate
MoFEMErrorCode integrate(EntData &data)
Definition: EshelbianOperators.cpp:684

EshelbianPlasticity::OpSpatialEquilibrium_dw_dP::integrate
MoFEMErrorCode integrate(EntData &row_data, EntData &col_data)
Definition: EshelbianOperators.cpp:1088

EshelbianPlasticity::OpSpatialEquilibrium_dw_dw::integrate
MoFEMErrorCode integrate(EntData &row_data, EntData &col_data)
Definition: EshelbianOperators.cpp:1124

EshelbianPlasticity::OpSpatialEquilibrium_dw_dw::alphaW
const double alphaW
Definition: EshelbianPlasticity.hpp:624

EshelbianPlasticity::OpSpatialEquilibrium_dw_dw::alphaRho
const double alphaRho
Definition: EshelbianPlasticity.hpp:625

EshelbianPlasticity::OpSpatialEquilibrium::integrate
MoFEMErrorCode integrate(EntData &data)
Definition: EshelbianOperators.cpp:470

EshelbianPlasticity::OpSpatialEquilibrium::alphaW
const double alphaW
Definition: EshelbianPlasticity.hpp:480

EshelbianPlasticity::OpSpatialEquilibrium::alphaRho
const double alphaRho
Definition: EshelbianPlasticity.hpp:481

EshelbianPlasticity::OpSpatialPhysical_du_dBubble::integrate
MoFEMErrorCode integrate(EntData &row_data, EntData &col_data)
Definition: EshelbianOperators.cpp:1239

EshelbianPlasticity::OpSpatialPhysical_du_dP::integrate
MoFEMErrorCode integrate(EntData &row_data, EntData &col_data)
Definition: EshelbianOperators.cpp:1179

EshelbianPlasticity::OpSpatialPhysical_du_domega::integrate
MoFEMErrorCode integrate(EntData &row_data, EntData &col_data)
Definition: EshelbianOperators.cpp:1545

EshelbianPlasticity::OpSpatialPhysical_du_du::integrateHencky
MoFEMErrorCode integrateHencky(EntData &row_data, EntData &col_data)
Definition: EshelbianOperators.cpp:1298

EshelbianPlasticity::OpSpatialPhysical_du_du::integratePiola
MoFEMErrorCode integratePiola(EntData &row_data, EntData &col_data)
Definition: EshelbianOperators.cpp:1421

EshelbianPlasticity::OpSpatialPhysical_du_du::alphaU
const double alphaU
Definition: EshelbianPlasticity.hpp:638

EshelbianPlasticity::OpSpatialPhysical_du_du::integrate
MoFEMErrorCode integrate(EntData &row_data, EntData &col_data)
Definition: EshelbianOperators.cpp:1287

EshelbianPlasticity::OpSpatialPhysical::integratePiola
MoFEMErrorCode integratePiola(EntData &data)
Definition: EshelbianOperators.cpp:619

EshelbianPlasticity::OpSpatialPhysical::integrate
MoFEMErrorCode integrate(EntData &data)
Definition: EshelbianOperators.cpp:550

EshelbianPlasticity::OpSpatialPhysical::integrateHencky
MoFEMErrorCode integrateHencky(EntData &data)
Definition: EshelbianOperators.cpp:562

EshelbianPlasticity::OpSpatialPhysical::alphaU
const double alphaU
Definition: EshelbianPlasticity.hpp:510

EshelbianPlasticity::OpSpatialRotation_domega_dBubble::integrate
MoFEMErrorCode integrate(EntData &row_data, EntData &col_data)
Definition: EshelbianOperators.cpp:1668

EshelbianPlasticity::OpSpatialRotation_domega_dP::integrate
MoFEMErrorCode integrate(EntData &row_data, EntData &col_data)
Definition: EshelbianOperators.cpp:1613

EshelbianPlasticity::OpSpatialRotation_domega_domega::integrate
MoFEMErrorCode integrate(EntData &row_data, EntData &col_data)
Definition: EshelbianOperators.cpp:1718

EshelbianPlasticity::OpSpatialRotation::integrate
MoFEMErrorCode integrate(EntData &data)
Definition: EshelbianOperators.cpp:516

EshelbianPlasticity::OpTractionBc
Definition: EshelbianPlasticity.hpp:582

EshelbianPlasticity::OpTractionBc::bcFe
FeTractionBc & bcFe
Definition: EshelbianPlasticity.hpp:589

EshelbianPlasticity::OpTractionBc::vecPv
MatrixDouble vecPv
Definition: EshelbianPlasticity.hpp:591

EshelbianPlasticity::OpTractionBc::matPP
MatrixDouble matPP
Definition: EshelbianPlasticity.hpp:590

EshelbianPlasticity::OpTractionBc::doWork
MoFEMErrorCode doWork(int side, EntityType type, EntData &data)
Definition: EshelbianOperators.cpp:944

EshelbianPlasticity::TensorTypeExtractor< FTensor::PackPtr< T, I > >::Type
std::remove_pointer< T >::type Type
Definition: EshelbianOperators.cpp:52

EshelbianPlasticity::TensorTypeExtractor
Definition: EshelbianOperators.cpp:48

EshelbianPlasticity::TensorTypeExtractor::Type
std::remove_pointer< T >::type Type
Definition: EshelbianOperators.cpp:49

EshelbianPlasticity::isEq
Definition: EshelbianOperators.cpp:166

EshelbianPlasticity::isEq::absMax
static double absMax
Definition: EshelbianOperators.cpp:171

EshelbianPlasticity::isEq::check
static auto check(const double &a, const double &b)
Definition: EshelbianOperators.cpp:167

MoFEM::AddHOOps
Add operators pushing bases from local to physical configuration.
Definition: HODataOperators.hpp:503

MoFEM::EntitiesFieldData::EntData
Data on single entity (This is passed as argument to DataOperator::doWork)
Definition: EntitiesFieldData.hpp:127

MoFEM::EntitiesFieldData::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: EntitiesFieldData.cpp:521

MoFEM::EntitiesFieldData::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: EntitiesFieldData.cpp:623

MoFEM::EntitiesFieldData::EntData::getFTensor0N
FTensor::Tensor0< FTensor::PackPtr< double *, 1 > > getFTensor0N(const FieldApproximationBase base)
Get base function as Tensor0.
Definition: EntitiesFieldData.hpp:1489

MoFEM::EntitiesFieldData::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: EntitiesFieldData.hpp:1305

MoFEM::EntitiesFieldData::EntData::getFieldData
const VectorDouble & getFieldData() const
get dofs values
Definition: EntitiesFieldData.hpp:1241

MoFEM::EntitiesFieldData::EntData::getFTensor1N
FTensor::Tensor1< FTensor::PackPtr< double *, Tensor_Dim >, Tensor_Dim > getFTensor1N(FieldApproximationBase base)
Get base functions for Hdiv/Hcurl spaces.
Definition: EntitiesFieldData.cpp:501

MoFEM::EntitiesFieldData::EntData::getFieldDofs
const VectorDofs & getFieldDofs() const
get dofs data stature FEDofEntity
Definition: EntitiesFieldData.hpp:1256

MoFEM::EntitiesFieldData::EntData::getIndices
const VectorInt & getIndices() const
Get global indices of dofs on entity.
Definition: EntitiesFieldData.hpp:1201

MoFEM::FaceElementForcesAndSourcesCore
Face finite element.
Definition: FaceElementForcesAndSourcesCore.hpp:25

MoFEM::ForcesAndSourcesCore::getOpPtrVector
boost::ptr_deque< UserDataOperator > & getOpPtrVector()
Use to push back operator for row operator.
Definition: ForcesAndSourcesCore.hpp:83

MoFEM::ForcesAndSourcesCore::getRuleHook
RuleHookFun getRuleHook
Hook to get rule.
Definition: ForcesAndSourcesCore.hpp:42

MoFEM::TSMethod::ts_t
PetscReal ts_t
time
Definition: LoopMethods.hpp:162