4.0.3dev_522f93/doxygen/generic__assembly_8hh_source.html

 /*!

  *

  * Copyright (C) 2015 Technical University of Liberec.  All rights reserved.

  *

  * This program is free software; you can redistribute it and/or modify it under

  * the terms of the GNU General Public License version 3 as published by the

  * Free Software Foundation. (http://www.gnu.org/licenses/gpl-3.0.en.html)

  *

  * This program 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 General Public License for more details.

  *

  *

  * @file    generic_assembly.hh

  * @brief

  */


 #ifndef GENERIC_ASSEMBLY_HH_

 #define GENERIC_ASSEMBLY_HH_


 #include "quadrature/quadrature_lib.hh"

 #include "fields/eval_subset.hh"

 #include "fields/eval_points.hh"

 #include "fields/field_value_cache.hh"

 #include "fem/fe_values.hh"

 #include "fem/patch_fe_values.hh"

 #include "tools/revertable_list.hh"

 #include "system/sys_profiler.hh"


 /// Allow set mask of active integrals.

 enum ActiveIntegrals {

     no_intg  =      0,

     bulk     = 0x0001,

     edge     = 0x0002,

     coupling = 0x0004,

     boundary = 0x0008

 };


 /// Set of all used integral necessary in assemblation

 struct AssemblyIntegrals {

     std::array<std::shared_ptr<BulkIntegral>, 3> bulk_;          ///< Bulk integrals of elements of dimensions 1, 2, 3

     std::array<std::shared_ptr<EdgeIntegral>, 3> edge_;          ///< Edge integrals between elements of dimensions 1, 2, 3

     std::array<std::shared_ptr<CouplingIntegral>, 2> coupling_;  ///< Coupling integrals between elements of dimensions 1-2, 2-3

     std::array<std::shared_ptr<BoundaryIntegral>, 3> boundary_;  ///< Boundary integrals betwwen elements of dimensions 1, 2, 3 and boundaries

 };


 /**

  * Common interface class for all Assembly classes.

  */

 class GenericAssemblyBase

 {

 public:

     /**

      * Helper structzre holds data of cell (bulk) integral

      *

      * Data is specified by cell and subset index in EvalPoint object

      */

     struct BulkIntegralData {

         /// Default constructor

         BulkIntegralData() {}


         /// Constructor with data mebers initialization

         BulkIntegralData(DHCellAccessor dhcell, unsigned int subset_idx)

         : cell(dhcell), subset_index(subset_idx) {}


         /// Copy constructor

         BulkIntegralData(const BulkIntegralData &other)

         : cell(other.cell), subset_index(other.subset_index) {}


         DHCellAccessor cell;          ///< Specified cell (element)

         unsigned int subset_index;    ///< Index (order) of subset in EvalPoints object

     };


     /**

      * Helper structzre holds data of edge integral

      *

      * Data is specified by side and subset index in EvalPoint object

      */

     struct EdgeIntegralData {

         /// Default constructor

         EdgeIntegralData()

         : edge_side_range(make_iter<DHEdgeSide, DHCellSide>( DHEdgeSide() ), make_iter<DHEdgeSide, DHCellSide>( DHEdgeSide() )) {}


         /// Copy constructor

         EdgeIntegralData(const EdgeIntegralData &other)

         : edge_side_range(other.edge_side_range), subset_index(other.subset_index) {}


         /// Constructor with data mebers initialization

         EdgeIntegralData(RangeConvert<DHEdgeSide, DHCellSide> range, unsigned int subset_idx)

         : edge_side_range(range), subset_index(subset_idx) {}


         RangeConvert<DHEdgeSide, DHCellSide> edge_side_range;   ///< Specified cell side (element)

         unsigned int subset_index;                              ///< Index (order) of subset in EvalPoints object

     };


     /**

      * Helper structzre holds data of neighbour (coupling) integral

      *

      * Data is specified by cell, side and their subset indices in EvalPoint object

      */

     struct CouplingIntegralData {

         /// Default constructor

         CouplingIntegralData() {}


         /// Constructor with data mebers initialization

         CouplingIntegralData(DHCellAccessor dhcell, unsigned int bulk_idx, DHCellSide dhside, unsigned int side_idx)

         : cell(dhcell), bulk_subset_index(bulk_idx), side(dhside), side_subset_index(side_idx) {}


         /// Copy constructor

         CouplingIntegralData(const CouplingIntegralData &other)

         : cell(other.cell), bulk_subset_index(other.bulk_subset_index), side(other.side), side_subset_index(other.side_subset_index) {}


         DHCellAccessor cell;

         unsigned int bulk_subset_index;    ///< Index (order) of lower dim subset in EvalPoints object

         DHCellSide side;                   ///< Specified cell side (higher dim element)

         unsigned int side_subset_index;    ///< Index (order) of higher dim subset in EvalPoints object

     };


     /**

      * Helper structzre holds data of boundary integral

      *

      * Data is specified by side and subset indices of side and appropriate boundary element in EvalPoint object

      */

     struct BoundaryIntegralData {

         /// Default constructor

         BoundaryIntegralData() {}


         /// Constructor with data mebers initialization

         BoundaryIntegralData(unsigned int bdr_idx, DHCellSide dhside, unsigned int side_idx)

         : bdr_subset_index(bdr_idx), side(dhside), side_subset_index(side_idx) {}


         /// Copy constructor

         BoundaryIntegralData(const BoundaryIntegralData &other)

         : bdr_subset_index(other.bdr_subset_index), side(other.side), side_subset_index(other.side_subset_index) {}


         // We don't need hold ElementAccessor of boundary element, side.cond().element_accessor() provides it.

         unsigned int bdr_subset_index;     ///< Index (order) of subset on boundary element in EvalPoints object

         DHCellSide side;                   ///< Specified cell side (bulk element)

         unsigned int side_subset_index;    ///< Index (order) of subset on side of bulk element in EvalPoints object

     };


     GenericAssemblyBase() {}


     virtual ~GenericAssemblyBase(){}

     virtual void assemble(std::shared_ptr<DOFHandlerMultiDim> dh) = 0;


     /// Getter to EvalPoints object

     inline std::shared_ptr<EvalPoints> eval_points() const {

         return eval_points_;

     }


 protected:

     AssemblyIntegrals integrals_;                                 ///< Holds integral objects.

     std::shared_ptr<EvalPoints> eval_points_;                     ///< EvalPoints object shared by all integrals

     ElementCacheMap element_cache_map_;                           ///< ElementCacheMap according to EvalPoints

 };


 /**

  * @brief Generic class of assemblation.

  *

  * Class

  *  - holds assemblation structures (EvalPoints, Integral objects, Integral data table).

  *  - associates assemblation objects specified by dimension

  *  - provides general assemble method

  *  - provides methods that allow construction of element patches

  */

 template < template<IntDim...> class DimAssembly>

 class GenericAssembly : public GenericAssemblyBase

 {

 public:

     /// Constructor

     GenericAssembly( typename DimAssembly<1>::EqFields *eq_fields, typename DimAssembly<1>::EqData *eq_data)

     : use_patch_fe_values_(false),

       multidim_assembly_(eq_fields, eq_data),

       min_edge_sides_(2),

       bulk_integral_data_(20, 10),

       edge_integral_data_(12, 6),

       coupling_integral_data_(12, 6),

       boundary_integral_data_(8, 4),

       table_sizes_(2, std::vector<uint>(3, 0))

     {

         initialize();

     }


     /// Constructor

     GenericAssembly( typename DimAssembly<1>::EqFields *eq_fields, typename DimAssembly<1>::EqData *eq_data, DOFHandlerMultiDim* dh)

     : fe_values_(CacheMapElementNumber::get(), eq_data->quad_order(), dh->ds()->fe()),

       use_patch_fe_values_(true),

       multidim_assembly_(eq_fields, eq_data, &this->fe_values_),

       min_edge_sides_(2),

       bulk_integral_data_(20, 10),

       edge_integral_data_(12, 6),

       coupling_integral_data_(12, 6),

       boundary_integral_data_(8, 4),

       table_sizes_(2, std::vector<uint>(3, 0))

     {

         initialize();

     }


     /// Getter to set of assembly objects

     inline MixedPtr<DimAssembly, 1> multidim_assembly() const {

         return multidim_assembly_;

     }


     void set_min_edge_sides(unsigned int val) {

         min_edge_sides_ = val;

     }


     /**

      * @brief General assemble methods.

      *

      * Loops through local cells and calls assemble methods of assembly

      * object of each cells over space dimension.

      *

      * TODO:

      * - make estimate of the cache fill for combination of (integral_type x element dimension)

      * - add next cell to patch if current_patch_size + next_element_size <= fixed_cache_size

      * - avoid reverting the integral data lists.

      */

     void assemble(std::shared_ptr<DOFHandlerMultiDim> dh) override {

         START_TIMER( DimAssembly<1>::name() );

         this->reallocate_cache();

         multidim_assembly_[1_d]->begin();


         bool add_into_patch = false; // control variable

         for(auto cell_it = dh->local_range().begin(); cell_it != dh->local_range().end(); )

         {


             if (!add_into_patch) {

                 element_cache_map_.start_elements_update();

                 add_into_patch = true;

             }


             START_TIMER("add_integrals_to_patch");

             this->add_integrals_of_computing_step(*cell_it);

             END_TIMER("add_integrals_to_patch");


             if (element_cache_map_.get_simd_rounded_size() > CacheMapElementNumber::get()) {

                 bulk_integral_data_.revert_temporary();

                 edge_integral_data_.revert_temporary();

                 coupling_integral_data_.revert_temporary();

                 boundary_integral_data_.revert_temporary();

                 element_cache_map_.eval_point_data_.revert_temporary();

                 this->assemble_integrals();

                 add_into_patch = false;

             } else {

                 bulk_integral_data_.make_permanent();

                 edge_integral_data_.make_permanent();

                 coupling_integral_data_.make_permanent();

                 boundary_integral_data_.make_permanent();

                 element_cache_map_.make_paermanent_eval_points();

                 if (element_cache_map_.get_simd_rounded_size() == CacheMapElementNumber::get()) {

                     this->assemble_integrals();

                     add_into_patch = false;

                 }

                 ++cell_it;

             }

         }

         if (add_into_patch) {

             this->assemble_integrals();

         }


         multidim_assembly_[1_d]->end();

         END_TIMER( DimAssembly<1>::name() );

     }


     /// Return ElementCacheMap

     inline const ElementCacheMap &cache_map() const {

         return element_cache_map_;

     }


 private:

     /// Common part of GenericAssemblz constructors.

     void initialize() {

         eval_points_ = std::make_shared<EvalPoints>();

         // first step - create integrals, then - initialize cache and initialize subobject of dimensions

         multidim_assembly_[1_d]->create_integrals(eval_points_, integrals_);

         multidim_assembly_[2_d]->create_integrals(eval_points_, integrals_);

         multidim_assembly_[3_d]->create_integrals(eval_points_, integrals_);

         element_cache_map_.init(eval_points_);

         multidim_assembly_[1_d]->initialize(&element_cache_map_);

         multidim_assembly_[2_d]->initialize(&element_cache_map_);

         multidim_assembly_[3_d]->initialize(&element_cache_map_);

         active_integrals_ = multidim_assembly_[1_d]->n_active_integrals();

     }


     /// Call assemblations when patch is filled

     void assemble_integrals() {

         START_TIMER("create_patch");

         element_cache_map_.create_patch();

         END_TIMER("create_patch");

         if (use_patch_fe_values_) {

             START_TIMER("patch_reinit");

             patch_reinit();

             END_TIMER("patch_reinit");

         }

         START_TIMER("cache_update");

         multidim_assembly_[1_d]->eq_fields_->cache_update(element_cache_map_); // TODO replace with sub FieldSet

         END_TIMER("cache_update");

         element_cache_map_.finish_elements_update();


         {

             START_TIMER("assemble_volume_integrals");

             multidim_assembly_[1_d]->assemble_cell_integrals(bulk_integral_data_);

             multidim_assembly_[2_d]->assemble_cell_integrals(bulk_integral_data_);

             multidim_assembly_[3_d]->assemble_cell_integrals(bulk_integral_data_);

             END_TIMER("assemble_volume_integrals");

         }


         {

             START_TIMER("assemble_fluxes_boundary");

             multidim_assembly_[1_d]->assemble_boundary_side_integrals(boundary_integral_data_);

             multidim_assembly_[2_d]->assemble_boundary_side_integrals(boundary_integral_data_);

             multidim_assembly_[3_d]->assemble_boundary_side_integrals(boundary_integral_data_);

             END_TIMER("assemble_fluxes_boundary");

         }


         {

             START_TIMER("assemble_fluxes_elem_elem");

             multidim_assembly_[1_d]->assemble_edge_integrals(edge_integral_data_);

             multidim_assembly_[2_d]->assemble_edge_integrals(edge_integral_data_);

             multidim_assembly_[3_d]->assemble_edge_integrals(edge_integral_data_);

             END_TIMER("assemble_fluxes_elem_elem");

         }


         {

             START_TIMER("assemble_fluxes_elem_side");

             multidim_assembly_[2_d]->assemble_neighbour_integrals(coupling_integral_data_);

             multidim_assembly_[3_d]->assemble_neighbour_integrals(coupling_integral_data_);

             END_TIMER("assemble_fluxes_elem_side");

         }

         // clean integral data

         bulk_integral_data_.reset();

         edge_integral_data_.reset();

         coupling_integral_data_.reset();

         boundary_integral_data_.reset();

         element_cache_map_.clear_element_eval_points_map();

         if (use_patch_fe_values_) {

             for (uint i=0; i<table_sizes_.size(); ++i)

                 for (uint j=0; j<table_sizes_[i].size(); ++j)

                     table_sizes_[i][j] = 0;

             fe_values_.reset();

         }

     }


     void patch_reinit() {

         fe_values_.resize_tables(table_sizes_);

         if (bulk_integral_data_.permanent_size() > 0) {

             multidim_assembly_[1_d]->add_patch_bulk_points(bulk_integral_data_);

             multidim_assembly_[2_d]->add_patch_bulk_points(bulk_integral_data_);

             multidim_assembly_[3_d]->add_patch_bulk_points(bulk_integral_data_);

         }

         if (boundary_integral_data_.permanent_size() > 0) {

             multidim_assembly_[1_d]->add_patch_bdr_side_points(boundary_integral_data_);

             multidim_assembly_[2_d]->add_patch_bdr_side_points(boundary_integral_data_);

             multidim_assembly_[3_d]->add_patch_bdr_side_points(boundary_integral_data_);

         }

         if (edge_integral_data_.permanent_size() > 0) {

             multidim_assembly_[1_d]->add_patch_edge_points(edge_integral_data_);

             multidim_assembly_[2_d]->add_patch_edge_points(edge_integral_data_);

             multidim_assembly_[3_d]->add_patch_edge_points(edge_integral_data_);

         }

         if (coupling_integral_data_.permanent_size() > 0) {

             multidim_assembly_[2_d]->add_patch_coupling_integrals(coupling_integral_data_);

             multidim_assembly_[3_d]->add_patch_coupling_integrals(coupling_integral_data_);

         }

         this->fe_values_.reinit_patch();


 //        OLD temporary

 //        const std::vector<unsigned int> &elm_idx_vec = element_cache_map_.elm_idx_vec();

 //        std::array<PatchElementsList, 4> patch_elements;

 //

 //        for (unsigned int i=0; i<elm_idx_vec.size(); ++i) {

 //            // Skip invalid element indices.

 //            if ( elm_idx_vec[i] == std::numeric_limits<unsigned int>::max() ) continue;

 //

 //            ElementAccessor<3> elm(dh->mesh(), elm_idx_vec[i]);

 //            patch_elements[elm.dim()].push_back(std::make_pair(elm, i));

 //        }

 //        this->fe_values_.reinit(patch_elements);

     }


     /**

      * Add data of integrals to appropriate structure and register elements to ElementCacheMap.

      *

      * Types of used integrals must be set in data member \p active_integrals_.

      */

     void add_integrals_of_computing_step(DHCellAccessor cell) {

         if (active_integrals_ & ActiveIntegrals::bulk)

             if (cell.is_own()) { // Not ghost

                 this->add_volume_integral(cell);

             }


         for( DHCellSide cell_side : cell.side_range() ) {

             if (active_integrals_ & ActiveIntegrals::boundary)

                 if (cell.is_own()) // Not ghost

                     if ( (cell_side.side().edge().n_sides() == 1) && (cell_side.side().is_boundary()) ) {

                         this->add_boundary_integral(cell_side);

                         continue;

                     }

             if (active_integrals_ & ActiveIntegrals::edge)

                 if ( (cell_side.n_edge_sides() >= min_edge_sides_) && (cell_side.edge_sides().begin()->element().idx() == cell.elm_idx())) {

                     this->add_edge_integral(cell_side);

                 }

         }


         if (active_integrals_ & ActiveIntegrals::coupling) {

             bool add_low = true;

             for( DHCellSide neighb_side : cell.neighb_sides() ) { // cell -> elm lower dim, neighb_side -> elm higher dim

                 if (cell.dim() != neighb_side.dim()-1) continue;

                 this->add_coupling_integral(cell, neighb_side, add_low);

                 add_low = false;

             }

         }

     }


     /// Add data of volume integral to appropriate data structure.

     inline void add_volume_integral(const DHCellAccessor &cell) {

         uint subset_idx = integrals_.bulk_[cell.dim()-1]->get_subset_idx();

         bulk_integral_data_.emplace_back(cell, subset_idx);


         unsigned int reg_idx = cell.elm().region_idx().idx();

         // Different access than in other integrals: We can't use range method CellIntegral::points

         // because it passes element_patch_idx as argument that is not known during patch construction.

         for (uint i=uint( eval_points_->subset_begin(cell.dim(), subset_idx) );

                   i<uint( eval_points_->subset_end(cell.dim(), subset_idx) ); ++i) {

             element_cache_map_.add_eval_point(reg_idx, cell.elm_idx(), i, cell.local_idx());

             table_sizes_[0][cell.dim()-1]++;

         }

     }


     /// Add data of edge integral to appropriate data structure.

     inline void add_edge_integral(const DHCellSide &cell_side) {

         auto range = cell_side.edge_sides();

         uint dim = range.begin()->dim();

         edge_integral_data_.emplace_back(range, integrals_.edge_[dim-1]->get_subset_idx());


         for( DHCellSide edge_side : range ) {

             unsigned int reg_idx = edge_side.element().region_idx().idx();

             for (auto p : integrals_.edge_[dim-1]->points(edge_side, &element_cache_map_) ) {

                 element_cache_map_.add_eval_point(reg_idx, edge_side.elem_idx(), p.eval_point_idx(), edge_side.cell().local_idx());

                 table_sizes_[1][dim-1]++;

             }

         }

     }


     /// Add data of coupling integral to appropriate data structure.

     inline void add_coupling_integral(const DHCellAccessor &cell, const DHCellSide &ngh_side, bool add_low) {

         coupling_integral_data_.emplace_back(cell, integrals_.coupling_[cell.dim()-1]->get_subset_low_idx(), ngh_side,

                 integrals_.coupling_[cell.dim()-1]->get_subset_high_idx());


         unsigned int reg_idx_low = cell.elm().region_idx().idx();

         unsigned int reg_idx_high = ngh_side.element().region_idx().idx();

         for (auto p : integrals_.coupling_[cell.dim()-1]->points(ngh_side, &element_cache_map_) ) {

             element_cache_map_.add_eval_point(reg_idx_high, ngh_side.elem_idx(), p.eval_point_idx(), ngh_side.cell().local_idx());

             table_sizes_[1][cell.dim()]++;


             if (add_low) {

                 auto p_low = p.lower_dim(cell); // equivalent point on low dim cell

                 element_cache_map_.add_eval_point(reg_idx_low, cell.elm_idx(), p_low.eval_point_idx(), cell.local_idx());

                 table_sizes_[0][cell.dim()-1]++;

             }

         }

     }


     /// Add data of boundary integral to appropriate data structure.

     inline void add_boundary_integral(const DHCellSide &bdr_side) {

         boundary_integral_data_.emplace_back(integrals_.boundary_[bdr_side.dim()-1]->get_subset_low_idx(), bdr_side,

                 integrals_.boundary_[bdr_side.dim()-1]->get_subset_high_idx());


         unsigned int reg_idx = bdr_side.element().region_idx().idx();

         for (auto p : integrals_.boundary_[bdr_side.dim()-1]->points(bdr_side, &element_cache_map_) ) {

             element_cache_map_.add_eval_point(reg_idx, bdr_side.elem_idx(), p.eval_point_idx(), bdr_side.cell().local_idx());

             table_sizes_[1][bdr_side.dim()-1]++;


             BulkPoint p_bdr = p.point_bdr(bdr_side.cond().element_accessor()); // equivalent point on boundary element

             unsigned int bdr_reg = bdr_side.cond().element_accessor().region_idx().idx();

             // invalid local_idx value, DHCellAccessor of boundary element doesn't exist

             element_cache_map_.add_eval_point(bdr_reg, bdr_side.cond().bc_ele_idx(), p_bdr.eval_point_idx(), -1);

         }

     }


     /// Calls cache_reallocate method on

     inline void reallocate_cache() {

         multidim_assembly_[1_d]->eq_fields_->cache_reallocate(this->element_cache_map_, multidim_assembly_[1_d]->used_fields_);

         // DebugOut() << "Order of evaluated fields (" << DimAssembly<1>::name() << "):" << multidim_assembly_[1_d]->eq_fields_->print_dependency();

     }


     PatchFEValues<3> fe_values_;                                     ///< Common FEValues object over all dimensions

     bool use_patch_fe_values_;                                       ///< Flag holds if common @p fe_values_ object is used in @p multidim_assembly_

     MixedPtr<DimAssembly, 1> multidim_assembly_;                     ///< Assembly object


     /// Holds mask of active integrals.

     int active_integrals_;


     /**

      * Minimal number of sides on edge.

      *

      * Edge integral is created and calculated if number of sides is greater or equal than this value. Default value

      * is 2 and can be changed

      */

     unsigned int min_edge_sides_;


     // Following variables hold data of all integrals depending of actual computed element.

     // TODO sizes of arrays should be set dynamically, depend on number of elements in ElementCacheMap,

     RevertableList<BulkIntegralData>       bulk_integral_data_;      ///< Holds data for computing bulk integrals.

     RevertableList<EdgeIntegralData>       edge_integral_data_;      ///< Holds data for computing edge integrals.

     RevertableList<CouplingIntegralData>   coupling_integral_data_;  ///< Holds data for computing couplings integrals.

     RevertableList<BoundaryIntegralData>   boundary_integral_data_;  ///< Holds data for computing boundary integrals.


     /**

      * Struct for pre-computing number of elements, sides, bulk points and side points on each dimension.

      * Format:

      *  { {n_bulk_points_1D, 2D, 3D },

      *    {n_side_points_1D, 2D, 3D } }

      *

      * Passes its to PatchFEValues and sets size of tables in this object

      */

     std::vector<std::vector<uint> > table_sizes_;

 };


 #endif /* GENERIC_ASSEMBLY_HH_ */

Boundary::bc_ele_idx
uint bc_ele_idx()
Definition: accessors.hh:374

Boundary::element_accessor
ElementAccessor< 3 > element_accessor()
Definition: accessors_impl.hh:259

BulkPoint
Base point accessor class.
Definition: eval_subset.hh:55

BulkPoint::eval_point_idx
unsigned int eval_point_idx() const
Return index in EvalPoints object.
Definition: eval_subset.hh:84

CacheMapElementNumber
Auxiliary data class holds number of elements in cache and allow to set this value explicitly (e....
Definition: field_value_cache.hh:91

CacheMapElementNumber::get
static unsigned int get()
Return number of stored elements.
Definition: field_value_cache.hh:94

DHCellAccessor
Cell accessor allow iterate over DOF handler cells.
Definition: dh_cell_accessor.hh:43

DHCellAccessor::neighb_sides
RangeConvert< DHNeighbSide, DHCellSide > neighb_sides() const
Returns range of neighbour cell of lower dimension corresponding to cell of higher dimension.
Definition: dh_cell_accessor.hh:471

DHCellAccessor::is_own
bool is_own() const
Return true if accessor represents own element (false for ghost element)
Definition: dh_cell_accessor.hh:130

DHCellAccessor::dim
unsigned int dim() const
Return dimension of element appropriate to cell.
Definition: dh_cell_accessor.hh:101

DHCellAccessor::side_range
Range< DHCellSide > side_range() const
Returns range of cell sides.
Definition: dh_cell_accessor.hh:464

DHCellAccessor::elm_idx
unsigned int elm_idx() const
Return serial idx to element of loc_ele_idx_.
Definition: dh_cell_accessor.hh:64

DHCellAccessor::elm
ElementAccessor< 3 > elm() const
Return ElementAccessor to element of loc_ele_idx_.
Definition: dh_cell_accessor.hh:71

DHCellAccessor::local_idx
unsigned int local_idx() const
Return local index to element (index of DOF handler).
Definition: dh_cell_accessor.hh:58

DHCellSide
Side accessor allows to iterate over sides of DOF handler cell.
Definition: dh_cell_accessor.hh:176

DHCellSide::elem_idx
unsigned int elem_idx() const
Definition: dh_cell_accessor.hh:227

DHCellSide::cond
Boundary cond() const
Definition: dh_cell_accessor.hh:231

DHCellSide::cell
const DHCellAccessor & cell() const
Return DHCellAccessor appropriate to the side.
Definition: dh_cell_accessor.hh:204

DHCellSide::edge_sides
RangeConvert< DHEdgeSide, DHCellSide > edge_sides() const
Returns range of all sides looped over common Edge.
Definition: dh_cell_accessor.hh:479

DHCellSide::dim
unsigned int dim() const
Return dimension of element appropriate to the side.
Definition: dh_cell_accessor.hh:214

DHCellSide::element
ElementAccessor< 3 > element() const
Definition: dh_cell_accessor.hh:223

DHEdgeSide
Class allows to iterate over sides of edge.
Definition: dh_cell_accessor.hh:293

DOFHandlerMultiDim
Provides the numbering of the finite element degrees of freedom on the computational mesh.
Definition: dofhandler.hh:151

ElementAccessor::region_idx
RegionIdx region_idx() const
Definition: accessors.hh:201

ElementCacheMap
Directing class of FieldValueCache.
Definition: field_value_cache.hh:152

ElementCacheMap::get_simd_rounded_size
unsigned int get_simd_rounded_size()
Returns number of eval. points with addition of max simd duplicates due to regions.
Definition: field_value_cache.hh:204

ElementCacheMap::start_elements_update
void start_elements_update()
Start update of cache.
Definition: field_value_cache.cc:123

ElementCacheMap::finish_elements_update
void finish_elements_update()
Finish update after reading data to cache.
Definition: field_value_cache.cc:127

ElementCacheMap::clear_element_eval_points_map
void clear_element_eval_points_map()
Reset all items of elements_eval_points_map.
Definition: field_value_cache.hh:170

ElementCacheMap::create_patch
void create_patch()
Create patch of cached elements before reading data to cache.
Definition: field_value_cache.cc:62

ElementCacheMap::eval_point_data_
RevertableList< EvalPointData > eval_point_data_
Definition: field_value_cache.hh:374

ElementCacheMap::add_eval_point
void add_eval_point(unsigned int i_reg, unsigned int i_ele, unsigned int i_eval_point, unsigned int dh_loc_idx)
Definition: field_value_cache.hh:197

ElementCacheMap::init
void init(std::shared_ptr< EvalPoints > eval_points)
Init cache.
Definition: field_value_cache.cc:52

ElementCacheMap::make_paermanent_eval_points
void make_paermanent_eval_points()
Mark eval_point_data_ as permanent.
Definition: field_value_cache.hh:303

GenericAssemblyBase
Definition: generic_assembly.hh:55

GenericAssemblyBase::element_cache_map_
ElementCacheMap element_cache_map_
ElementCacheMap according to EvalPoints.
Definition: generic_assembly.hh:159

GenericAssemblyBase::~GenericAssemblyBase
virtual ~GenericAssemblyBase()
Definition: generic_assembly.hh:148

GenericAssemblyBase::eval_points_
std::shared_ptr< EvalPoints > eval_points_
EvalPoints object shared by all integrals.
Definition: generic_assembly.hh:158

GenericAssemblyBase::eval_points
std::shared_ptr< EvalPoints > eval_points() const
Getter to EvalPoints object.
Definition: generic_assembly.hh:152

GenericAssemblyBase::integrals_
AssemblyIntegrals integrals_
Holds integral objects.
Definition: generic_assembly.hh:157

GenericAssemblyBase::GenericAssemblyBase
GenericAssemblyBase()
Definition: generic_assembly.hh:146

GenericAssemblyBase::assemble
virtual void assemble(std::shared_ptr< DOFHandlerMultiDim > dh)=0

GenericAssembly
Generic class of assemblation.
Definition: generic_assembly.hh:174

GenericAssembly::fe_values_
PatchFEValues< 3 > fe_values_
Common FEValues object over all dimensions.
Definition: generic_assembly.hh:495

GenericAssembly::multidim_assembly_
MixedPtr< DimAssembly, 1 > multidim_assembly_
Assembly object.
Definition: generic_assembly.hh:497

GenericAssembly::edge_integral_data_
RevertableList< EdgeIntegralData > edge_integral_data_
Holds data for computing edge integrals.
Definition: generic_assembly.hh:513

GenericAssembly::assemble_integrals
void assemble_integrals()
Call assemblations when patch is filled.
Definition: generic_assembly.hh:293

GenericAssembly::assemble
void assemble(std::shared_ptr< DOFHandlerMultiDim > dh) override
General assemble methods.
Definition: generic_assembly.hh:225

GenericAssembly::GenericAssembly
GenericAssembly(typename DimAssembly< 1 >::EqFields *eq_fields, typename DimAssembly< 1 >::EqData *eq_data, DOFHandlerMultiDim *dh)
Constructor.
Definition: generic_assembly.hh:191

GenericAssembly::patch_reinit
void patch_reinit()
Definition: generic_assembly.hh:351

GenericAssembly::min_edge_sides_
unsigned int min_edge_sides_
Definition: generic_assembly.hh:508

GenericAssembly::add_boundary_integral
void add_boundary_integral(const DHCellSide &bdr_side)
Add data of boundary integral to appropriate data structure.
Definition: generic_assembly.hh:472

GenericAssembly::cache_map
const ElementCacheMap & cache_map() const
Return ElementCacheMap.
Definition: generic_assembly.hh:273

GenericAssembly::add_volume_integral
void add_volume_integral(const DHCellAccessor &cell)
Add data of volume integral to appropriate data structure.
Definition: generic_assembly.hh:423

GenericAssembly::table_sizes_
std::vector< std::vector< uint > > table_sizes_
Definition: generic_assembly.hh:525

GenericAssembly::add_edge_integral
void add_edge_integral(const DHCellSide &cell_side)
Add data of edge integral to appropriate data structure.
Definition: generic_assembly.hh:438

GenericAssembly::boundary_integral_data_
RevertableList< BoundaryIntegralData > boundary_integral_data_
Holds data for computing boundary integrals.
Definition: generic_assembly.hh:515

GenericAssembly::active_integrals_
int active_integrals_
Holds mask of active integrals.
Definition: generic_assembly.hh:500

GenericAssembly::initialize
void initialize()
Common part of GenericAssemblz constructors.
Definition: generic_assembly.hh:279

GenericAssembly::coupling_integral_data_
RevertableList< CouplingIntegralData > coupling_integral_data_
Holds data for computing couplings integrals.
Definition: generic_assembly.hh:514

GenericAssembly::set_min_edge_sides
void set_min_edge_sides(unsigned int val)
Definition: generic_assembly.hh:210

GenericAssembly::reallocate_cache
void reallocate_cache()
Calls cache_reallocate method on.
Definition: generic_assembly.hh:489

GenericAssembly::GenericAssembly
GenericAssembly(typename DimAssembly< 1 >::EqFields *eq_fields, typename DimAssembly< 1 >::EqData *eq_data)
Constructor.
Definition: generic_assembly.hh:177

GenericAssembly::use_patch_fe_values_
bool use_patch_fe_values_
Flag holds if common fe_values_ object is used in multidim_assembly_.
Definition: generic_assembly.hh:496

GenericAssembly::add_coupling_integral
void add_coupling_integral(const DHCellAccessor &cell, const DHCellSide &ngh_side, bool add_low)
Add data of coupling integral to appropriate data structure.
Definition: generic_assembly.hh:453

GenericAssembly::add_integrals_of_computing_step
void add_integrals_of_computing_step(DHCellAccessor cell)
Definition: generic_assembly.hh:393

GenericAssembly::multidim_assembly
MixedPtr< DimAssembly, 1 > multidim_assembly() const
Getter to set of assembly objects.
Definition: generic_assembly.hh:206

GenericAssembly::bulk_integral_data_
RevertableList< BulkIntegralData > bulk_integral_data_
Holds data for computing bulk integrals.
Definition: generic_assembly.hh:512

MixedPtr< DimAssembly, 1 >

PatchFEValues< 3 >

PatchFEValues::resize_tables
void resize_tables(std::vector< std::vector< uint > > dim_sizes)
Resize tables of patch_point_vals_.
Definition: patch_fe_values.hh:1014

PatchFEValues::reinit_patch
void reinit_patch()
Reinit data.
Definition: patch_fe_values.hh:966

PatchFEValues::reset
void reset()
Reset PatchpointValues structures.
Definition: patch_fe_values.hh:948

RangeConvert< DHEdgeSide, DHCellSide >

RangeConvert::begin
IterConvert< ObjectIn, ObjectOut > begin()
Iterator to begin item of range.
Definition: range_wrapper.hh:44

RegionIdx::idx
unsigned int idx() const
Returns a global index of the region.
Definition: region.hh:81

std::vector
Definition: doxy_dummy_defs.hh:7

eval_points.hh

eval_subset.hh

fe_values.hh
Class FEValues calculates finite element data on the actual cells such as shape function values,...

field_value_cache.hh

make_iter
Iter< Object > make_iter(Object obj)
Definition: general_iterator.hh:85

ActiveIntegrals
ActiveIntegrals
Allow set mask of active integrals.
Definition: generic_assembly.hh:33

coupling
@ coupling
Definition: generic_assembly.hh:37

boundary
@ boundary
Definition: generic_assembly.hh:38

no_intg
@ no_intg
Definition: generic_assembly.hh:34

bulk
@ bulk
Definition: generic_assembly.hh:35

edge
@ edge
Definition: generic_assembly.hh:36

uint
unsigned int uint
Definition: mh_dofhandler.hh:101

IntDim
unsigned int IntDim
A dimension index type.
Definition: mixed.hh:19

fmt::internal::get
T & get()

std
Definition: doxy_dummy_defs.hh:6

patch_fe_values.hh
Class FEValues calculates finite element data on the actual cells such as shape function values,...

quadrature_lib.hh
Definitions of particular quadrature rules on simplices.

revertable_list.hh

AssemblyIntegrals
Set of all used integral necessary in assemblation.
Definition: generic_assembly.hh:43

AssemblyIntegrals::bulk_
std::array< std::shared_ptr< BulkIntegral >, 3 > bulk_
Bulk integrals of elements of dimensions 1, 2, 3.
Definition: generic_assembly.hh:44

AssemblyIntegrals::coupling_
std::array< std::shared_ptr< CouplingIntegral >, 2 > coupling_
Coupling integrals between elements of dimensions 1-2, 2-3.
Definition: generic_assembly.hh:46

AssemblyIntegrals::boundary_
std::array< std::shared_ptr< BoundaryIntegral >, 3 > boundary_
Boundary integrals betwwen elements of dimensions 1, 2, 3 and boundaries.
Definition: generic_assembly.hh:47

AssemblyIntegrals::edge_
std::array< std::shared_ptr< EdgeIntegral >, 3 > edge_
Edge integrals between elements of dimensions 1, 2, 3.
Definition: generic_assembly.hh:45

GenericAssemblyBase::BoundaryIntegralData
Definition: generic_assembly.hh:128

GenericAssemblyBase::BoundaryIntegralData::side_subset_index
unsigned int side_subset_index
Index (order) of subset on side of bulk element in EvalPoints object.
Definition: generic_assembly.hh:143

GenericAssemblyBase::BoundaryIntegralData::BoundaryIntegralData
BoundaryIntegralData(unsigned int bdr_idx, DHCellSide dhside, unsigned int side_idx)
Constructor with data mebers initialization.
Definition: generic_assembly.hh:133

GenericAssemblyBase::BoundaryIntegralData::BoundaryIntegralData
BoundaryIntegralData()
Default constructor.
Definition: generic_assembly.hh:130

GenericAssemblyBase::BoundaryIntegralData::BoundaryIntegralData
BoundaryIntegralData(const BoundaryIntegralData &other)
Copy constructor.
Definition: generic_assembly.hh:137

GenericAssemblyBase::BoundaryIntegralData::bdr_subset_index
unsigned int bdr_subset_index
Index (order) of subset on boundary element in EvalPoints object.
Definition: generic_assembly.hh:141

GenericAssemblyBase::BoundaryIntegralData::side
DHCellSide side
Specified cell side (bulk element)
Definition: generic_assembly.hh:142

GenericAssemblyBase::BulkIntegralData
Definition: generic_assembly.hh:62

GenericAssemblyBase::BulkIntegralData::BulkIntegralData
BulkIntegralData(DHCellAccessor dhcell, unsigned int subset_idx)
Constructor with data mebers initialization.
Definition: generic_assembly.hh:67

GenericAssemblyBase::BulkIntegralData::cell
DHCellAccessor cell
Specified cell (element)
Definition: generic_assembly.hh:74

GenericAssemblyBase::BulkIntegralData::subset_index
unsigned int subset_index
Index (order) of subset in EvalPoints object.
Definition: generic_assembly.hh:75

GenericAssemblyBase::BulkIntegralData::BulkIntegralData
BulkIntegralData(const BulkIntegralData &other)
Copy constructor.
Definition: generic_assembly.hh:71

GenericAssemblyBase::BulkIntegralData::BulkIntegralData
BulkIntegralData()
Default constructor.
Definition: generic_assembly.hh:64

GenericAssemblyBase::CouplingIntegralData
Definition: generic_assembly.hh:105

GenericAssemblyBase::CouplingIntegralData::cell
DHCellAccessor cell
Definition: generic_assembly.hh:117

GenericAssemblyBase::CouplingIntegralData::bulk_subset_index
unsigned int bulk_subset_index
Index (order) of lower dim subset in EvalPoints object.
Definition: generic_assembly.hh:118

GenericAssemblyBase::CouplingIntegralData::CouplingIntegralData
CouplingIntegralData(DHCellAccessor dhcell, unsigned int bulk_idx, DHCellSide dhside, unsigned int side_idx)
Constructor with data mebers initialization.
Definition: generic_assembly.hh:110

GenericAssemblyBase::CouplingIntegralData::side_subset_index
unsigned int side_subset_index
Index (order) of higher dim subset in EvalPoints object.
Definition: generic_assembly.hh:120

GenericAssemblyBase::CouplingIntegralData::CouplingIntegralData
CouplingIntegralData(const CouplingIntegralData &other)
Copy constructor.
Definition: generic_assembly.hh:114

GenericAssemblyBase::CouplingIntegralData::CouplingIntegralData
CouplingIntegralData()
Default constructor.
Definition: generic_assembly.hh:107

GenericAssemblyBase::CouplingIntegralData::side
DHCellSide side
Specified cell side (higher dim element)
Definition: generic_assembly.hh:119

GenericAssemblyBase::EdgeIntegralData
Definition: generic_assembly.hh:83

GenericAssemblyBase::EdgeIntegralData::EdgeIntegralData
EdgeIntegralData(const EdgeIntegralData &other)
Copy constructor.
Definition: generic_assembly.hh:89

GenericAssemblyBase::EdgeIntegralData::edge_side_range
RangeConvert< DHEdgeSide, DHCellSide > edge_side_range
Specified cell side (element)
Definition: generic_assembly.hh:96

GenericAssemblyBase::EdgeIntegralData::subset_index
unsigned int subset_index
Index (order) of subset in EvalPoints object.
Definition: generic_assembly.hh:97

GenericAssemblyBase::EdgeIntegralData::EdgeIntegralData
EdgeIntegralData(RangeConvert< DHEdgeSide, DHCellSide > range, unsigned int subset_idx)
Constructor with data mebers initialization.
Definition: generic_assembly.hh:93

GenericAssemblyBase::EdgeIntegralData::EdgeIntegralData
EdgeIntegralData()
Default constructor.
Definition: generic_assembly.hh:85

RevertableList< BulkIntegralData >

RevertableList::revert_temporary
std::size_t revert_temporary()
Erase temporary part of data.
Definition: revertable_list.hh:134

RevertableList::make_permanent
std::size_t make_permanent()
Finalize temporary part of data.
Definition: revertable_list.hh:127

RevertableList::reset
void reset()
Clear the list.
Definition: revertable_list.hh:142

RevertableList::emplace_back
std::size_t emplace_back(Args &&... args)
Definition: revertable_list.hh:114

RevertableList::permanent_size
std::size_t permanent_size() const
Return permanent size of list.
Definition: revertable_list.hh:71

sys_profiler.hh

END_TIMER
#define END_TIMER(tag)
Ends a timer with specified tag.
Definition: sys_profiler.hh:149

START_TIMER
#define START_TIMER(tag)
Starts a timer with specified tag.
Definition: sys_profiler.hh:115