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material_inline_impl.cc
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/**
* @file material_inline_impl.cc
*
* @author Daniel Pino Muñoz <daniel.pinomunoz@epfl.ch>
* @author Nicolas Richart <nicolas.richart@epfl.ch>
* @author Marco Vocialta <marco.vocialta@epfl.ch>
*
* @date creation: Tue Jul 27 2010
* @date last modification: Tue Feb 20 2018
*
* @brief Implementation of the inline functions of the class material
*
* @section LICENSE
*
* Copyright (©) 2010-2018 EPFL (Ecole Polytechnique Fédérale de Lausanne)
* Laboratory (LSMS - Laboratoire de Simulation en Mécanique des Solides)
*
* Akantu 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.
*
* Akantu 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 Akantu. If not, see <http://www.gnu.org/licenses/>.
*
*/
/* -------------------------------------------------------------------------- */
#include "solid_mechanics_model.hh"
/* -------------------------------------------------------------------------- */
#ifndef __AKANTU_MATERIAL_INLINE_IMPL_CC__
#define __AKANTU_MATERIAL_INLINE_IMPL_CC__
namespace akantu {
/* -------------------------------------------------------------------------- */
inline UInt Material::addElement(const ElementType & type, UInt element,
const GhostType & ghost_type) {
Array<UInt> & el_filter = this->element_filter(type, ghost_type);
el_filter.push_back(element);
return el_filter.size() - 1;
}
/* -------------------------------------------------------------------------- */
inline UInt Material::addElement(const Element & element) {
return this->addElement(element.type, element.element, element.ghost_type);
}
/* -------------------------------------------------------------------------- */
inline UInt Material::getTangentStiffnessVoigtSize(UInt dim) const {
return (dim * (dim - 1) / 2 + dim);
}
/* -------------------------------------------------------------------------- */
inline UInt Material::getCauchyStressMatrixSize(UInt dim) const {
return (dim * dim);
}
/* -------------------------------------------------------------------------- */
template <UInt dim>
inline void Material::gradUToF(const Matrix<Real> & grad_u, Matrix<Real> & F) {
AKANTU_DEBUG_ASSERT(F.size() >= grad_u.size() && grad_u.size() == dim * dim,
"The dimension of the tensor F should be greater or "
"equal to the dimension of the tensor grad_u.");
F.eye();
for (UInt i = 0; i < dim; ++i)
for (UInt j = 0; j < dim; ++j)
F(i, j) += grad_u(i, j);
}
/* -------------------------------------------------------------------------- */
template <UInt dim>
inline decltype(auto) Material::gradUToF(const Matrix<Real> & grad_u) {
Matrix<Real> F(dim, dim);
gradUToF<dim>(grad_u, F);
return F;
}
/* -------------------------------------------------------------------------- */
template <UInt dim>
inline void Material::StoCauchy(const Matrix<Real> & F, const Matrix<Real> & S,
Matrix<Real> & sigma, const Real & C33) const {
Real J = F.det() * sqrt(C33);
Matrix<Real> F_S(dim, dim);
F_S = F * S;
Real constant = J ? 1. / J : 0;
sigma.mul<false, true>(F_S, F, constant);
}
/* -------------------------------------------------------------------------- */
inline void Material::rightCauchy(const Matrix<Real> & F, Matrix<Real> & C) {
C.mul<true, false>(F, F);
}
/* -------------------------------------------------------------------------- */
inline void Material::leftCauchy(const Matrix<Real> & F, Matrix<Real> & B) {
B.mul<false, true>(F, F);
}
/* -------------------------------------------------------------------------- */
template <UInt dim>
inline void Material::gradUToEpsilon(const Matrix<Real> & grad_u,
Matrix<Real> & epsilon) {
for (UInt i = 0; i < dim; ++i)
for (UInt j = 0; j < dim; ++j)
epsilon(i, j) = 0.5 * (grad_u(i, j) + grad_u(j, i));
}
/* -------------------------------------------------------------------------- */
template <UInt dim>
inline decltype(auto) Material::gradUToEpsilon(const Matrix<Real> & grad_u) {
Matrix<Real> epsilon(dim, dim);
Material::template gradUToEpsilon<dim>(grad_u, epsilon);
return epsilon;
}
/* -------------------------------------------------------------------------- */
template <UInt dim>
inline void Material::gradUToE(const Matrix<Real> & grad_u, Matrix<Real> & E) {
E.mul<true, false>(grad_u, grad_u, .5);
for (UInt i = 0; i < dim; ++i)
for (UInt j = 0; j < dim; ++j)
E(i, j) += 0.5 * (grad_u(i, j) + grad_u(j, i));
}
/* -------------------------------------------------------------------------- */
template <UInt dim>
inline decltype(auto) Material::gradUToE(const Matrix<Real> & grad_u) {
Matrix<Real> E(dim, dim);
gradUToE<dim>(grad_u, E);
return E;
}
/* -------------------------------------------------------------------------- */
inline Real Material::stressToVonMises(const Matrix<Real> & stress) {
// compute deviatoric stress
UInt dim = stress.cols();
Matrix<Real> deviatoric_stress =
Matrix<Real>::eye(dim, -1. * stress.trace() / 3.);
for (UInt i = 0; i < dim; ++i)
for (UInt j = 0; j < dim; ++j)
deviatoric_stress(i, j) += stress(i, j);
// return Von Mises stress
return std::sqrt(3. * deviatoric_stress.doubleDot(deviatoric_stress) / 2.);
}
/* -------------------------------------------------------------------------- */
template <UInt dim>
inline void Material::setCauchyStressMatrix(const Matrix<Real> & S_t,
Matrix<Real> & sigma) {
AKANTU_DEBUG_IN();
sigma.clear();
/// see Finite ekement formulations for large deformation dynamic analysis,
/// Bathe et al. IJNME vol 9, 1975, page 364 ^t\tau
for (UInt i = 0; i < dim; ++i) {
for (UInt m = 0; m < dim; ++m) {
for (UInt n = 0; n < dim; ++n) {
sigma(i * dim + m, i * dim + n) = S_t(m, n);
}
}
}
AKANTU_DEBUG_OUT();
}
/* -------------------------------------------------------------------------- */
inline Element
Material::convertToLocalElement(const Element & global_element) const {
UInt ge = global_element.element;
#ifndef AKANTU_NDEBUG
UInt model_mat_index = this->model.getMaterialByElement(
global_element.type, global_element.ghost_type)(ge);
UInt mat_index = this->model.getMaterialIndex(this->name);
AKANTU_DEBUG_ASSERT(model_mat_index == mat_index,
"Conversion of a global element in a local element for "
"the wrong material "
<< this->name << std::endl);
#endif
UInt le = this->model.getMaterialLocalNumbering(
global_element.type, global_element.ghost_type)(ge);
Element tmp_quad{global_element.type, le, global_element.ghost_type};
return tmp_quad;
}
/* -------------------------------------------------------------------------- */
inline Element
Material::convertToGlobalElement(const Element & local_element) const {
UInt le = local_element.element;
UInt ge =
this->element_filter(local_element.type, local_element.ghost_type)(le);
Element tmp_quad{local_element.type, ge, local_element.ghost_type};
return tmp_quad;
}
/* -------------------------------------------------------------------------- */
inline IntegrationPoint
Material::convertToLocalPoint(const IntegrationPoint & global_point) const {
const FEEngine & fem = this->model.getFEEngine();
UInt nb_quad = fem.getNbIntegrationPoints(global_point.type);
Element el =
this->convertToLocalElement(static_cast<const Element &>(global_point));
IntegrationPoint tmp_quad(el, global_point.num_point, nb_quad);
return tmp_quad;
}
/* -------------------------------------------------------------------------- */
inline IntegrationPoint
Material::convertToGlobalPoint(const IntegrationPoint & local_point) const {
const FEEngine & fem = this->model.getFEEngine();
UInt nb_quad = fem.getNbIntegrationPoints(local_point.type);
Element el =
this->convertToGlobalElement(static_cast<const Element &>(local_point));
IntegrationPoint tmp_quad(el, local_point.num_point, nb_quad);
return tmp_quad;
}
/* -------------------------------------------------------------------------- */
inline UInt Material::getNbData(const Array<Element> & elements,
const SynchronizationTag & tag) const {
if (tag == SynchronizationTag::_smm_stress) {
return (this->isFiniteDeformation() ? 3 : 1) * spatial_dimension *
spatial_dimension * sizeof(Real) *
this->getModel().getNbIntegrationPoints(elements);
}
return 0;
}
/* -------------------------------------------------------------------------- */
inline void Material::packData(CommunicationBuffer & buffer,
const Array<Element> & elements,
const SynchronizationTag & tag) const {
if (tag == SynchronizationTag::_smm_stress) {
if (this->isFiniteDeformation()) {
packElementDataHelper(piola_kirchhoff_2, buffer, elements);
packElementDataHelper(gradu, buffer, elements);
}
packElementDataHelper(stress, buffer, elements);
}
}
/* -------------------------------------------------------------------------- */
inline void Material::unpackData(CommunicationBuffer & buffer,
const Array<Element> & elements,
const SynchronizationTag & tag) {
if (tag == SynchronizationTag::_smm_stress) {
if (this->isFiniteDeformation()) {
unpackElementDataHelper(piola_kirchhoff_2, buffer, elements);
unpackElementDataHelper(gradu, buffer, elements);
}
unpackElementDataHelper(stress, buffer, elements);
}
}
/* -------------------------------------------------------------------------- */
inline const Parameter & Material::getParam(const ID & param) const {
try {
return get(param);
} catch (...) {
AKANTU_EXCEPTION("No parameter " << param << " in the material "
<< getID());
}
}
/* -------------------------------------------------------------------------- */
template <typename T>
inline void Material::setParam(const ID & param, T value) {
try {
set<T>(param, value);
} catch (...) {
AKANTU_EXCEPTION("No parameter " << param << " in the material "
<< getID());
}
updateInternalParameters();
}
/* -------------------------------------------------------------------------- */
template <typename T>
inline void Material::packElementDataHelper(
const ElementTypeMapArray<T> & data_to_pack, CommunicationBuffer & buffer,
const Array<Element> & elements, const ID & fem_id) const {
DataAccessor::packElementalDataHelper<T>(data_to_pack, buffer, elements, true,
model.getFEEngine(fem_id));
}
/* -------------------------------------------------------------------------- */
template <typename T>
inline void Material::unpackElementDataHelper(
ElementTypeMapArray<T> & data_to_unpack, CommunicationBuffer & buffer,
const Array<Element> & elements, const ID & fem_id) {
DataAccessor::unpackElementalDataHelper<T>(data_to_unpack, buffer, elements,
true, model.getFEEngine(fem_id));
}
/* -------------------------------------------------------------------------- */
template <>
inline void Material::registerInternal<Real>(InternalField<Real> & vect) {
internal_vectors_real[vect.getID()] = &vect;
}
template <>
inline void Material::registerInternal<UInt>(InternalField<UInt> & vect) {
internal_vectors_uint[vect.getID()] = &vect;
}
template <>
inline void Material::registerInternal<bool>(InternalField<bool> & vect) {
internal_vectors_bool[vect.getID()] = &vect;
}
/* -------------------------------------------------------------------------- */
template <>
inline void Material::unregisterInternal<Real>(InternalField<Real> & vect) {
internal_vectors_real.erase(vect.getID());
}
template <>
inline void Material::unregisterInternal<UInt>(InternalField<UInt> & vect) {
internal_vectors_uint.erase(vect.getID());
}
template <>
inline void Material::unregisterInternal<bool>(InternalField<bool> & vect) {
internal_vectors_bool.erase(vect.getID());
}
/* -------------------------------------------------------------------------- */
template <typename T>
inline bool Material::isInternal(__attribute__((unused)) const ID & id,
__attribute__((unused))
const ElementKind & element_kind) const {
AKANTU_TO_IMPLEMENT();
}
template <>
inline bool Material::isInternal<Real>(const ID & id,
const ElementKind & element_kind) const {
auto internal_array = internal_vectors_real.find(this->getID() + ":" + id);
if (internal_array == internal_vectors_real.end() ||
internal_array->second->getElementKind() != element_kind)
return false;
return true;
}
/* -------------------------------------------------------------------------- */
template <typename T>
inline ElementTypeMap<UInt>
Material::getInternalDataPerElem(const ID & field_id,
const ElementKind & element_kind) const {
if (!this->template isInternal<T>(field_id, element_kind))
AKANTU_EXCEPTION("Cannot find internal field " << id << " in material "
<< this->name);
const InternalField<T> & internal_field =
this->template getInternal<T>(field_id);
const FEEngine & fe_engine = internal_field.getFEEngine();
UInt nb_data_per_quad = internal_field.getNbComponent();
ElementTypeMap<UInt> res;
for (auto ghost_type : ghost_types) {
for (auto & type : internal_field.elementTypes(ghost_type)) {
UInt nb_quadrature_points =
fe_engine.getNbIntegrationPoints(type, ghost_type);
res(type, ghost_type) = nb_data_per_quad * nb_quadrature_points;
}
}
return res;
}
/* -------------------------------------------------------------------------- */
template <typename T>
void Material::flattenInternal(const std::string & field_id,
ElementTypeMapArray<T> & internal_flat,
const GhostType ghost_type,
ElementKind element_kind) const {
if (!this->template isInternal<T>(field_id, element_kind))
AKANTU_EXCEPTION("Cannot find internal field " << id << " in material "
<< this->name);
const InternalField<T> & internal_field =
this->template getInternal<T>(field_id);
const FEEngine & fe_engine = internal_field.getFEEngine();
const Mesh & mesh = fe_engine.getMesh();
for (auto && type : internal_field.filterTypes(ghost_type)) {
const Array<Real> & src_vect = internal_field(type, ghost_type);
const Array<UInt> & filter = internal_field.getFilter(type, ghost_type);
// total number of elements in the corresponding mesh
UInt nb_element_dst = mesh.getNbElement(type, ghost_type);
// number of element in the internal field
UInt nb_element_src = filter.size();
// number of quadrature points per elem
UInt nb_quad_per_elem = fe_engine.getNbIntegrationPoints(type);
// number of data per quadrature point
UInt nb_data_per_quad = internal_field.getNbComponent();
if (!internal_flat.exists(type, ghost_type)) {
internal_flat.alloc(nb_element_dst * nb_quad_per_elem, nb_data_per_quad,
type, ghost_type);
}
if (nb_element_src == 0)
continue;
// number of data per element
UInt nb_data = nb_quad_per_elem * nb_data_per_quad;
Array<Real> & dst_vect = internal_flat(type, ghost_type);
dst_vect.resize(nb_element_dst * nb_quad_per_elem);
auto it_dst = make_view(dst_vect, nb_data).begin();
for (auto && data : zip(filter, make_view(src_vect, nb_data))) {
it_dst[std::get<0>(data)] = std::get<1>(data);
}
}
}
} // namespace akantu
#endif /* __AKANTU_MATERIAL_INLINE_IMPL_CC__ */

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