diff --git a/src/model/solid_mechanics/materials/internal_field.hh b/src/model/solid_mechanics/materials/internal_field.hh index a4789c7c0..5054a0214 100644 --- a/src/model/solid_mechanics/materials/internal_field.hh +++ b/src/model/solid_mechanics/materials/internal_field.hh @@ -1,277 +1,277 @@ /** * @file internal_field.hh * * @author Nicolas Richart * * @date creation: Fri Jun 18 2010 * @date last modification: Thu Feb 08 2018 * * @brief Material internal properties * * @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 . * */ /* -------------------------------------------------------------------------- */ #include "aka_common.hh" #include "element_type_map.hh" /* -------------------------------------------------------------------------- */ #ifndef __AKANTU_INTERNAL_FIELD_HH__ #define __AKANTU_INTERNAL_FIELD_HH__ namespace akantu { class Material; class FEEngine; /** * class for the internal fields of materials * to store values for each quadrature */ template class InternalField : public ElementTypeMapArray { /* ------------------------------------------------------------------------ */ /* Constructors/Destructors */ /* ------------------------------------------------------------------------ */ public: InternalField(const ID & id, Material & material); ~InternalField() override; /// This constructor is only here to let cohesive elements compile InternalField(const ID & id, Material & material, FEEngine & fem, const ElementTypeMapArray & element_filter); /// More general constructor InternalField(const ID & id, Material & material, UInt dim, FEEngine & fem, const ElementTypeMapArray & element_filter); InternalField(const ID & id, const InternalField & other); private: InternalField operator=(const InternalField & ) = delete; /* ------------------------------------------------------------------------ */ /* Methods */ /* ------------------------------------------------------------------------ */ public: /// function to reset the FEEngine for the internal field virtual void setFEEngine(FEEngine & fe_engine); /// function to reset the element kind for the internal virtual void setElementKind(ElementKind element_kind); /// initialize the field to a given number of component virtual void initialize(UInt nb_component); /// activate the history of this field virtual void initializeHistory(); /// resize the arrays and set the new element to 0 virtual void resize(); /// set the field to a given value v virtual void setDefaultValue(const T & v); /// reset all the fields to the default value virtual void reset(); /// save the current values in the history virtual void saveCurrentValues(); /// restore the previous values from the history virtual void restorePreviousValues(); /// remove the quadrature points corresponding to suppressed elements virtual void removeIntegrationPoints(const ElementTypeMapArray & new_numbering); /// print the content void printself(std::ostream & stream, int /*indent*/ = 0) const override; /// get the default value inline operator T() const; virtual FEEngine & getFEEngine() { return *fem; } virtual const FEEngine & getFEEngine() const { return *fem; } /// AKANTU_GET_MACRO(FEEngine, *fem, FEEngine &); protected: /// initialize the arrays in the ElementTypeMapArray void internalInitialize(UInt nb_component); /// set the values for new internals virtual void setArrayValues(T * begin, T * end); /* ------------------------------------------------------------------------ */ /* Accessors */ /* ------------------------------------------------------------------------ */ public: // using type_iterator = typename ElementTypeMapArray::type_iterator; // using filter_type_iterator = // typename ElementTypeMapArray::type_iterator; // /// get the type iterator on all types contained in the internal field // type_iterator firstType(const GhostType & ghost_type = _not_ghost) const { // return ElementTypeMapArray::firstType(this->spatial_dimension, // ghost_type, this->element_kind); // } // /// get the type iterator on the last type contained in the internal field // type_iterator lastType(const GhostType & ghost_type = _not_ghost) const { // return ElementTypeMapArray::lastType(this->spatial_dimension, ghost_type, // this->element_kind); // } // /// get the type iterator on all types contained in the internal field // filter_type_iterator // filterFirstType(const GhostType & ghost_type = _not_ghost) const { // return this->element_filter.firstType(this->spatial_dimension, ghost_type, // this->element_kind); // } // /// get the type iterator on the last type contained in the internal field // filter_type_iterator // filterLastType(const GhostType & ghost_type = _not_ghost) const { // return this->element_filter.lastType(this->spatial_dimension, ghost_type, // this->element_kind); // } /// get filter types for range loop - decltype(auto) elementTypes(const GhostType & ghost_type) const { + decltype(auto) elementTypes(const GhostType & ghost_type = _not_ghost) const { return ElementTypeMapArray::elementTypes( _spatial_dimension = this->spatial_dimension, _element_kind = this->element_kind, _ghost_type = ghost_type); } /// get filter types for range loop - decltype(auto) filterTypes(const GhostType & ghost_type) const { + decltype(auto) filterTypes(const GhostType & ghost_type = _not_ghost) const { return this->element_filter.elementTypes( _spatial_dimension = this->spatial_dimension, _element_kind = this->element_kind, _ghost_type = ghost_type); } /// get the array for a given type of the element_filter const Array & getFilter(const ElementType & type, const GhostType & ghost_type = _not_ghost) const { return this->element_filter(type, ghost_type); } /// get the Array corresponding to the type en ghost_type specified virtual Array & operator()(const ElementType & type, const GhostType & ghost_type = _not_ghost) { return ElementTypeMapArray::operator()(type, ghost_type); } virtual const Array & operator()(const ElementType & type, const GhostType & ghost_type = _not_ghost) const { return ElementTypeMapArray::operator()(type, ghost_type); } virtual Array & previous(const ElementType & type, const GhostType & ghost_type = _not_ghost) { AKANTU_DEBUG_ASSERT(previous_values != nullptr, "The history of the internal " << this->getID() << " has not been activated"); return this->previous_values->operator()(type, ghost_type); } virtual const Array & previous(const ElementType & type, const GhostType & ghost_type = _not_ghost) const { AKANTU_DEBUG_ASSERT(previous_values != nullptr, "The history of the internal " << this->getID() << " has not been activated"); return this->previous_values->operator()(type, ghost_type); } virtual InternalField & previous() { AKANTU_DEBUG_ASSERT(previous_values != nullptr, "The history of the internal " << this->getID() << " has not been activated"); return *(this->previous_values); } virtual const InternalField & previous() const { AKANTU_DEBUG_ASSERT(previous_values != nullptr, "The history of the internal " << this->getID() << " has not been activated"); return *(this->previous_values); } /// check if the history is used or not bool hasHistory() const { return (previous_values != nullptr); } /// get the kind treated by the internal const ElementKind & getElementKind() const { return element_kind; } /// return the number of components UInt getNbComponent() const { return nb_component; } /// return the spatial dimension corresponding to the internal element type /// loop filter UInt getSpatialDimension() const { return this->spatial_dimension; } /* ------------------------------------------------------------------------ */ /* Class Members */ /* ------------------------------------------------------------------------ */ protected: /// the material for which this is an internal parameter Material & material; /// the fem containing the mesh and the element informations FEEngine * fem{nullptr}; /// Element filter if needed const ElementTypeMapArray & element_filter; /// default value T default_value{}; /// spatial dimension of the element to consider UInt spatial_dimension{0}; /// ElementKind of the element to consider ElementKind element_kind{_ek_regular}; /// Number of component of the internal field UInt nb_component{0}; /// Is the field initialized bool is_init{false}; /// previous values std::unique_ptr> previous_values; }; /// standard output stream operator template inline std::ostream & operator<<(std::ostream & stream, const InternalField & _this) { _this.printself(stream); return stream; } } // namespace akantu #endif /* __AKANTU_INTERNAL_FIELD_HH__ */