Reference documentation for deal.II version 9.4.0

Namespaces  
namespace  internal 
Enumerations  
enum  Coupling { none , always , nonzero } 
Functions  
template<int dim, int spacedim>  
void  map_dofs_to_support_points (const hp::MappingCollection< dim, spacedim > &mapping, const DoFHandler< dim, spacedim > &dof_handler, std::vector< Point< spacedim > > &support_points, const ComponentMask &mask) 
template<int dim, int spacedim>  
void  map_dofs_to_support_points (const hp::MappingCollection< dim, spacedim > &mapping, const DoFHandler< dim, spacedim > &dof_handler, std::map< types::global_dof_index, Point< spacedim > > &support_points, const ComponentMask &mask) 
template<int dim, int spacedim, typename number >  
void  make_periodicity_constraints (const DoFHandler< dim, spacedim > &dof_handler, const types::boundary_id b_id1, const types::boundary_id b_id2, const unsigned int direction, ::AffineConstraints< number > &constraints, const ComponentMask &component_mask, const number periodicity_factor) 
DoF couplings  
template<int dim, int spacedim>  
void  convert_couplings_to_blocks (const DoFHandler< dim, spacedim > &dof_handler, const Table< 2, Coupling > &table_by_component, std::vector< Table< 2, Coupling > > &tables_by_block) 
template<int dim, int spacedim>  
Table< 2, Coupling >  dof_couplings_from_component_couplings (const FiniteElement< dim, spacedim > &fe, const Table< 2, Coupling > &component_couplings) 
template<int dim, int spacedim>  
std::vector< Table< 2, Coupling > >  dof_couplings_from_component_couplings (const hp::FECollection< dim, spacedim > &fe, const Table< 2, Coupling > &component_couplings) 
Sparsity pattern generation  
template<int dim, int spacedim, typename SparsityPatternType , typename number = double>  
void  make_sparsity_pattern (const DoFHandler< dim, spacedim > &dof_handler, SparsityPatternType &sparsity_pattern, const AffineConstraints< number > &constraints=AffineConstraints< number >(), const bool keep_constrained_dofs=true, const types::subdomain_id subdomain_id=numbers::invalid_subdomain_id) 
template<int dim, int spacedim, typename SparsityPatternType , typename number = double>  
void  make_sparsity_pattern (const DoFHandler< dim, spacedim > &dof_handler, const Table< 2, Coupling > &coupling, SparsityPatternType &sparsity_pattern, const AffineConstraints< number > &constraints=AffineConstraints< number >(), const bool keep_constrained_dofs=true, const types::subdomain_id subdomain_id=numbers::invalid_subdomain_id) 
template<int dim, int spacedim, typename SparsityPatternType >  
void  make_sparsity_pattern (const DoFHandler< dim, spacedim > &dof_row, const DoFHandler< dim, spacedim > &dof_col, SparsityPatternType &sparsity) 
template<int dim, int spacedim, typename SparsityPatternType >  
void  make_flux_sparsity_pattern (const DoFHandler< dim, spacedim > &dof_handler, SparsityPatternType &sparsity_pattern) 
template<int dim, int spacedim, typename SparsityPatternType , typename number >  
void  make_flux_sparsity_pattern (const DoFHandler< dim, spacedim > &dof_handler, SparsityPatternType &sparsity_pattern, const AffineConstraints< number > &constraints, const bool keep_constrained_dofs=true, const types::subdomain_id subdomain_id=numbers::invalid_subdomain_id) 
template<int dim, int spacedim, typename SparsityPatternType >  
void  make_flux_sparsity_pattern (const DoFHandler< dim, spacedim > &dof, SparsityPatternType &sparsity, const Table< 2, Coupling > &cell_integrals_mask, const Table< 2, Coupling > &face_integrals_mask, const types::subdomain_id subdomain_id=numbers::invalid_subdomain_id) 
template<int dim, int spacedim, typename SparsityPatternType , typename number >  
void  make_flux_sparsity_pattern (const DoFHandler< dim, spacedim > &dof, SparsityPatternType &sparsity, const AffineConstraints< number > &constraints, const bool keep_constrained_dofs, const Table< 2, Coupling > &couplings, const Table< 2, Coupling > &face_couplings, const types::subdomain_id subdomain_id, const std::function< bool(const typename DoFHandler< dim, spacedim >::active_cell_iterator &, const unsigned int)> &face_has_flux_coupling=&internal::always_couple_on_faces< dim, spacedim >) 
template<int dim, int spacedim, typename SparsityPatternType >  
void  make_boundary_sparsity_pattern (const DoFHandler< dim, spacedim > &dof, const std::vector< types::global_dof_index > &dof_to_boundary_mapping, SparsityPatternType &sparsity_pattern) 
template<int dim, int spacedim, typename SparsityPatternType , typename number >  
void  make_boundary_sparsity_pattern (const DoFHandler< dim, spacedim > &dof, const std::map< types::boundary_id, const Function< spacedim, number > * > &boundary_ids, const std::vector< types::global_dof_index > &dof_to_boundary_mapping, SparsityPatternType &sparsity) 
Hanging nodes and other constraints  
template<int dim, int spacedim, typename number >  
void  make_hanging_node_constraints (const DoFHandler< dim, spacedim > &dof_handler, AffineConstraints< number > &constraints) 
template<int dim, int spacedim>  
void  compute_intergrid_constraints (const DoFHandler< dim, spacedim > &coarse_grid, const unsigned int coarse_component, const DoFHandler< dim, spacedim > &fine_grid, const unsigned int fine_component, const InterGridMap< DoFHandler< dim, spacedim > > &coarse_to_fine_grid_map, AffineConstraints< double > &constraints) 
template<int dim, int spacedim>  
void  compute_intergrid_transfer_representation (const DoFHandler< dim, spacedim > &coarse_grid, const unsigned int coarse_component, const DoFHandler< dim, spacedim > &fine_grid, const unsigned int fine_component, const InterGridMap< DoFHandler< dim, spacedim > > &coarse_to_fine_grid_map, std::vector< std::map< types::global_dof_index, float > > &transfer_representation) 
Periodic boundary conditions  
template<typename FaceIterator , typename number >  
void  make_periodicity_constraints (const FaceIterator &face_1, const typename identity< FaceIterator >::type &face_2, AffineConstraints< number > &constraints, const ComponentMask &component_mask=ComponentMask(), const bool face_orientation=true, const bool face_flip=false, const bool face_rotation=false, const FullMatrix< double > &matrix=FullMatrix< double >(), const std::vector< unsigned int > &first_vector_components=std::vector< unsigned int >(), const number periodicity_factor=1.) 
template<int dim, int spacedim, typename number >  
void  make_periodicity_constraints (const std::vector< GridTools::PeriodicFacePair< typename DoFHandler< dim, spacedim >::cell_iterator > > &periodic_faces, AffineConstraints< number > &constraints, const ComponentMask &component_mask=ComponentMask(), const std::vector< unsigned int > &first_vector_components=std::vector< unsigned int >(), const number periodicity_factor=1.) 
template<typename DoFHandlerType , typename number >  
void  make_periodicity_constraints (const std::vector< GridTools::PeriodicFacePair< typename DoFHandlerType::cell_iterator > > &periodic_faces, AffineConstraints< number > &constraints, const ComponentMask &component_mask=ComponentMask(), const std::vector< unsigned int > &first_vector_components=std::vector< unsigned int >(), const number periodicity_factor=1.) 
template<int dim, int spacedim, typename number >  
void  make_periodicity_constraints (const DoFHandler< dim, spacedim > &dof_handler, const types::boundary_id b_id1, const types::boundary_id b_id2, const unsigned int direction, AffineConstraints< number > &constraints, const ComponentMask &component_mask=ComponentMask(), const number periodicity_factor=1.) 
template<int dim, int spacedim, typename number >  
void  make_periodicity_constraints (const DoFHandler< dim, spacedim > &dof_handler, const types::boundary_id b_id, const unsigned int direction, AffineConstraints< number > &constraints, const ComponentMask &component_mask=ComponentMask(), const number periodicity_factor=1.) 
Identifying subsets of degrees of freedom with particular properties  
template<int dim, int spacedim>  
IndexSet  extract_hanging_node_dofs (const DoFHandler< dim, spacedim > &dof_handler) 
template<int dim, int spacedim>  
IndexSet  extract_dofs (const DoFHandler< dim, spacedim > &dof_handler, const ComponentMask &component_mask) 
template<int dim, int spacedim>  
IndexSet  extract_dofs (const DoFHandler< dim, spacedim > &dof_handler, const BlockMask &block_mask) 
template<int dim, int spacedim>  
void  extract_level_dofs (const unsigned int level, const DoFHandler< dim, spacedim > &dof, const ComponentMask &component_mask, std::vector< bool > &selected_dofs) 
template<int dim, int spacedim>  
void  extract_level_dofs (const unsigned int level, const DoFHandler< dim, spacedim > &dof, const BlockMask &component_mask, std::vector< bool > &selected_dofs) 
template<int dim, int spacedim>  
void  extract_boundary_dofs (const DoFHandler< dim, spacedim > &dof_handler, const ComponentMask &component_mask, std::vector< bool > &selected_dofs, const std::set< types::boundary_id > &boundary_ids={}) 
template<int dim, int spacedim>  
IndexSet  extract_boundary_dofs (const DoFHandler< dim, spacedim > &dof_handler, const ComponentMask &component_mask=ComponentMask(), const std::set< types::boundary_id > &boundary_ids={}) 
template<int dim, int spacedim>  
void  extract_boundary_dofs (const DoFHandler< dim, spacedim > &dof_handler, const ComponentMask &component_mask, IndexSet &selected_dofs, const std::set< types::boundary_id > &boundary_ids={}) 
template<int dim, int spacedim>  
void  extract_dofs_with_support_on_boundary (const DoFHandler< dim, spacedim > &dof_handler, const ComponentMask &component_mask, std::vector< bool > &selected_dofs, const std::set< types::boundary_id > &boundary_ids=std::set< types::boundary_id >()) 
template<int dim, int spacedim, typename number = double>  
IndexSet  extract_dofs_with_support_contained_within (const DoFHandler< dim, spacedim > &dof_handler, const std::function< bool(const typename DoFHandler< dim, spacedim >::active_cell_iterator &)> &predicate, const AffineConstraints< number > &constraints=AffineConstraints< number >()) 
template<int dim, int spacedim>  
void  extract_constant_modes (const DoFHandler< dim, spacedim > &dof_handler, const ComponentMask &component_mask, std::vector< std::vector< bool > > &constant_modes) 
Parallelization and domain decomposition  
template<int dim, int spacedim>  
void  extract_subdomain_dofs (const DoFHandler< dim, spacedim > &dof_handler, const types::subdomain_id subdomain_id, std::vector< bool > &selected_dofs) 
template<int dim, int spacedim>  
IndexSet  extract_locally_active_dofs (const DoFHandler< dim, spacedim > &dof_handler) 
template<int dim, int spacedim>  
void  extract_locally_active_dofs (const DoFHandler< dim, spacedim > &dof_handler, IndexSet &dof_set) 
template<int dim, int spacedim>  
IndexSet  extract_locally_active_level_dofs (const DoFHandler< dim, spacedim > &dof_handler, const unsigned int level) 
template<int dim, int spacedim>  
void  extract_locally_active_level_dofs (const DoFHandler< dim, spacedim > &dof_handler, IndexSet &dof_set, const unsigned int level) 
template<int dim, int spacedim>  
IndexSet  extract_locally_relevant_dofs (const DoFHandler< dim, spacedim > &dof_handler) 
template<int dim, int spacedim>  
void  extract_locally_relevant_dofs (const DoFHandler< dim, spacedim > &dof_handler, IndexSet &dof_set) 
template<int dim, int spacedim>  
std::vector< IndexSet >  locally_owned_dofs_per_component (const DoFHandler< dim, spacedim > &dof_handler, const ComponentMask &components=ComponentMask()) 
template<int dim, int spacedim>  
std::vector< IndexSet >  locally_owned_dofs_per_subdomain (const DoFHandler< dim, spacedim > &dof_handler) 
template<int dim, int spacedim>  
std::vector< IndexSet >  locally_relevant_dofs_per_subdomain (const DoFHandler< dim, spacedim > &dof_handler) 
template<int dim, int spacedim>  
IndexSet  extract_locally_relevant_level_dofs (const DoFHandler< dim, spacedim > &dof_handler, const unsigned int level) 
template<int dim, int spacedim>  
void  extract_locally_relevant_level_dofs (const DoFHandler< dim, spacedim > &dof_handler, const unsigned int level, IndexSet &dof_set) 
template<int dim, int spacedim>  
void  get_subdomain_association (const DoFHandler< dim, spacedim > &dof_handler, std::vector< types::subdomain_id > &subdomain) 
template<int dim, int spacedim>  
unsigned int  count_dofs_with_subdomain_association (const DoFHandler< dim, spacedim > &dof_handler, const types::subdomain_id subdomain) 
template<int dim, int spacedim>  
void  count_dofs_with_subdomain_association (const DoFHandler< dim, spacedim > &dof_handler, const types::subdomain_id subdomain, std::vector< unsigned int > &n_dofs_on_subdomain) 
template<int dim, int spacedim>  
IndexSet  dof_indices_with_subdomain_association (const DoFHandler< dim, spacedim > &dof_handler, const types::subdomain_id subdomain) 
DoF indices on patches of cells  
Create structures containing a large set of degrees of freedom for small patches of cells. The resulting objects can be used in RelaxationBlockSOR and related classes to implement Schwarz preconditioners and smoothers, where the subdomains consist of small numbers of cells only.  
template<int dim, int spacedim>  
std::vector< types::global_dof_index >  get_dofs_on_patch (const std::vector< typename DoFHandler< dim, spacedim >::active_cell_iterator > &patch) 
template<typename DoFHandlerType >  
std::vector< types::global_dof_index >  get_dofs_on_patch (const std::vector< typename DoFHandlerType::active_cell_iterator > &patch) 
template<int dim, int spacedim>  
void  make_cell_patches (SparsityPattern &block_list, const DoFHandler< dim, spacedim > &dof_handler, const unsigned int level, const std::vector< bool > &selected_dofs={}, const types::global_dof_index offset=0) 
template<int dim, int spacedim>  
std::vector< unsigned int >  make_vertex_patches (SparsityPattern &block_list, const DoFHandler< dim, spacedim > &dof_handler, const unsigned int level, const bool interior_dofs_only, const bool boundary_patches=false, const bool level_boundary_patches=false, const bool single_cell_patches=false, const bool invert_vertex_mapping=false) 
template<int dim, int spacedim>  
std::vector< unsigned int >  make_vertex_patches (SparsityPattern &block_list, const DoFHandler< dim, spacedim > &dof_handler, const unsigned int level, const BlockMask &exclude_boundary_dofs=BlockMask(), const bool boundary_patches=false, const bool level_boundary_patches=false, const bool single_cell_patches=false, const bool invert_vertex_mapping=false) 
template<int dim, int spacedim>  
void  make_child_patches (SparsityPattern &block_list, const DoFHandler< dim, spacedim > &dof_handler, const unsigned int level, const bool interior_dofs_only, const bool boundary_dofs=false) 
template<int dim, int spacedim>  
void  make_single_patch (SparsityPattern &block_list, const DoFHandler< dim, spacedim > &dof_handler, const unsigned int level, const bool interior_dofs_only=false) 
Counting degrees of freedom and related functions  
template<int dim, int spacedim>  
std::vector< types::global_dof_index >  count_dofs_per_fe_component (const DoFHandler< dim, spacedim > &dof_handler, const bool vector_valued_once=false, const std::vector< unsigned int > &target_component={}) 
template<int dim, int spacedim>  
std::vector< types::global_dof_index >  count_dofs_per_fe_block (const DoFHandler< dim, spacedim > &dof, const std::vector< unsigned int > &target_block=std::vector< unsigned int >()) 
template<int dim, int spacedim>  
void  get_active_fe_indices (const DoFHandler< dim, spacedim > &dof_handler, std::vector< unsigned int > &active_fe_indices) 
template<int dim, int spacedim>  
unsigned int  count_dofs_on_patch (const std::vector< typename DoFHandler< dim, spacedim >::active_cell_iterator > &patch) 
template<typename DoFHandlerType >  
unsigned int  count_dofs_on_patch (const std::vector< typename DoFHandlerType::active_cell_iterator > &patch) 
Functions that return different DoF mappings  
template<int dim, int spacedim>  
void  map_dof_to_boundary_indices (const DoFHandler< dim, spacedim > &dof_handler, std::vector< types::global_dof_index > &mapping) 
template<int dim, int spacedim>  
void  map_dof_to_boundary_indices (const DoFHandler< dim, spacedim > &dof_handler, const std::set< types::boundary_id > &boundary_ids, std::vector< types::global_dof_index > &mapping) 
template<int dim, int spacedim>  
void  map_dofs_to_support_points (const Mapping< dim, spacedim > &mapping, const DoFHandler< dim, spacedim > &dof_handler, std::vector< Point< spacedim > > &support_points, const ComponentMask &mask=ComponentMask()) 
template<int dim, int spacedim>  
void  map_dofs_to_support_points (const ::hp::MappingCollection< dim, spacedim > &mapping, const DoFHandler< dim, spacedim > &dof_handler, std::vector< Point< spacedim > > &support_points, const ComponentMask &mask=ComponentMask()) 
template<int dim, int spacedim>  
void  map_dofs_to_support_points (const Mapping< dim, spacedim > &mapping, const DoFHandler< dim, spacedim > &dof_handler, std::map< types::global_dof_index, Point< spacedim > > &support_points, const ComponentMask &mask=ComponentMask()) 
template<int dim, int spacedim>  
void  map_dofs_to_support_points (const ::hp::MappingCollection< dim, spacedim > &mapping, const DoFHandler< dim, spacedim > &dof_handler, std::map< types::global_dof_index, Point< spacedim > > &support_points, const ComponentMask &mask=ComponentMask()) 
template<int dim, int spacedim, class Comp >  
void  map_support_points_to_dofs (const Mapping< dim, spacedim > &mapping, const DoFHandler< dim, spacedim > &dof_handler, std::map< Point< spacedim >, types::global_dof_index, Comp > &point_to_index_map) 
Miscellaneous  
template<int dim, int spacedim, typename Number >  
void  distribute_cell_to_dof_vector (const DoFHandler< dim, spacedim > &dof_handler, const Vector< Number > &cell_data, Vector< double > &dof_data, const unsigned int component=0) 
template<int spacedim>  
void  write_gnuplot_dof_support_point_info (std::ostream &out, const std::map< types::global_dof_index, Point< spacedim > > &support_points) 
template<int dim, int spacedim, typename number >  
void  make_zero_boundary_constraints (const DoFHandler< dim, spacedim > &dof, const types::boundary_id boundary_id, AffineConstraints< number > &zero_boundary_constraints, const ComponentMask &component_mask=ComponentMask()) 
template<int dim, int spacedim, typename number >  
void  make_zero_boundary_constraints (const DoFHandler< dim, spacedim > &dof, AffineConstraints< number > &zero_boundary_constraints, const ComponentMask &component_mask=ComponentMask()) 
Exceptions  
static ::ExceptionBase &  ExcFiniteElementsDontMatch () 
static ::ExceptionBase &  ExcGridNotCoarser () 
static ::ExceptionBase &  ExcGridsDontMatch () 
static ::ExceptionBase &  ExcNoFESelected () 
static ::ExceptionBase &  ExcInvalidBoundaryIndicator () 
This is a collection of functions operating on, and manipulating the numbers of degrees of freedom. The documentation of the member functions will provide more information, but for functions that exist in multiple versions, there are sections in this global documentation stating some commonalities.
When assembling system matrices, the entries are usually of the form \(a_{ij} = a(\phi_i, \phi_j)\), where \(a\) is a bilinear functional, often an integral. When using sparse matrices, we therefore only need to reserve space for those \(a_{ij}\) only, which are nonzero, which is the same as to say that the basis functions \(\phi_i\) and \(\phi_j\) have a nonempty intersection of their support. Since the support of basis functions is bound only on cells on which they are located or to which they are adjacent, to determine the sparsity pattern it is sufficient to loop over all cells and connect all basis functions on each cell with all other basis functions on that cell. There may be finite elements for which not all basis functions on a cell connect with each other, but no use of this case is made since no examples where this occurs are known to the author.
When projecting the traces of functions to the boundary or parts thereof, one needs to build matrices and vectors that act only on those degrees of freedom that are located on the boundary, rather than on all degrees of freedom. One could do that by simply building matrices in which the entries for all interior DoFs are zero, but such matrices are always very rank deficient and not very practical to work with.
What is needed instead in this case is a numbering of the boundary degrees of freedom, i.e. we should enumerate all the degrees of freedom that are sitting on the boundary, and exclude all other (interior) degrees of freedom. The map_dof_to_boundary_indices() function does exactly this: it provides a vector with as many entries as there are degrees of freedom on the whole domain, with each entry being the number in the numbering of the boundary or numbers::invalid_dof_index if the dof is not on the boundary.
With this vector, one can get, for any given degree of freedom, a unique number among those DoFs that sit on the boundary; or, if your DoF was interior to the domain, the result would be numbers::invalid_dof_index. We need this mapping, for example, to build the mass matrix on the boundary (for this, see make_boundary_sparsity_pattern() function, the corresponding section below, as well as the MatrixCreator namespace documentation).
Actually, there are two map_dof_to_boundary_indices() functions, one producing a numbering for all boundary degrees of freedom and one producing a numbering for only parts of the boundary, namely those parts for which the boundary indicator is listed in a set of indicators given to the function. The latter case is needed if, for example, we would only want to project the boundary values for the Dirichlet part of the boundary. You then give the function a list of boundary indicators referring to Dirichlet parts on which the projection is to be performed. The parts of the boundary on which you want to project need not be contiguous; however, it is not guaranteed that the indices of each of the boundary parts are continuous, i.e. the indices of degrees of freedom on different parts may be intermixed.
Degrees of freedom on the boundary but not on one of the specified boundary parts are given the index numbers::invalid_dof_index, as if they were in the interior. If no boundary indicator was given or if no face of a cell has a boundary indicator contained in the given list, the vector of new indices consists solely of numbers::invalid_dof_index.
(As a side note, for corner cases: The question what a degree of freedom on the boundary is, is not so easy. It should really be a degree of freedom of which the respective basis function has nonzero values on the boundary. At least for Lagrange elements this definition is equal to the statement that the offpoint, or what deal.II calls support_point, of the shape function, i.e. the point where the function assumes its nominal value (for Lagrange elements this is the point where it has the function value 1), is located on the boundary. We do not check this directly, the criterion is rather defined through the information the finite element class gives: the FiniteElement class defines the numbers of basis functions per vertex, per line, and so on and the basis functions are numbered after this information; a basis function is to be considered to be on the face of a cell (and thus on the boundary if the cell is at the boundary) according to it belonging to a vertex, line, etc but not to the interior of the cell. The finite element uses the same cellwise numbering so that we can say that if a degree of freedom was numbered as one of the dofs on lines, we assume that it is located on the line. Where the offpoint actually is, is a secret of the finite element (well, you can ask it, but we don't do it here) and not relevant in this context.)
In some cases, one wants to only work with DoFs that sit on the boundary. One application is, for example, if rather than interpolating non homogeneous boundary values, one would like to project them. For this, we need two things: a way to identify nodes that are located on (parts of) the boundary, and a way to build matrices out of only degrees of freedom that are on the boundary (i.e. much smaller matrices, in which we do not even build the large zero block that stems from the fact that most degrees of freedom have no support on the boundary of the domain). The first of these tasks is done by the map_dof_to_boundary_indices() function (described above).
The second part requires us first to build a sparsity pattern for the couplings between boundary nodes, and then to actually build the components of this matrix. While actually computing the entries of these small boundary matrices is discussed in the MatrixCreator namespace, the creation of the sparsity pattern is done by the create_boundary_sparsity_pattern() function. For its work, it needs to have a numbering of all those degrees of freedom that are on those parts of the boundary that we are interested in. You can get this from the map_dof_to_boundary_indices() function. It then builds the sparsity pattern corresponding to integrals like \(\int_\Gamma \varphi_{b2d(i)} \varphi_{b2d(j)} dx\), where \(i\) and \(j\) are indices into the matrix, and \(b2d(i)\) is the global DoF number of a degree of freedom sitting on a boundary (i.e., \(b2d\) is the inverse of the mapping returned by map_dof_to_boundary_indices() function).
enum DoFTools::Coupling 
The flags used in tables by certain make_*_pattern
functions to describe whether two components of the solution couple in the bilinear forms corresponding to cell or face terms. An example of using these flags is shown in the introduction of step46.
In the descriptions of the individual elements below, remember that these flags are used as elements of tables of size FiniteElement::n_components times FiniteElement::n_components where each element indicates whether two components do or do not couple.
Enumerator  

none  Two components do not couple. 
always  Two components do couple. 
nonzero  Two components couple only if their shape functions are both nonzero on a given face. This flag is only used when computing integrals over faces of cells, e.g., in DoFTools::make_flux_sparsity_pattern(). Use Coupling::always in general cases where gradients etc. occur on face integrals. 
Definition at line 226 of file dof_tools.h.
void DoFTools::convert_couplings_to_blocks  (  const DoFHandler< dim, spacedim > &  dof_handler, 
const Table< 2, Coupling > &  table_by_component,  
std::vector< Table< 2, Coupling > > &  tables_by_block  
) 
Map a coupling table from the user friendly organization by components to the organization by blocks.
The return vector will be initialized to the correct length inside this function.
Definition at line 2380 of file dof_tools.cc.
Table< 2, Coupling > DoFTools::dof_couplings_from_component_couplings  (  const FiniteElement< dim, spacedim > &  fe, 
const Table< 2, Coupling > &  component_couplings  
) 
Given a finite element and a table how the vector components of it couple with each other, compute and return a table that describes how the individual shape functions couple with each other.
Definition at line 697 of file dof_tools_sparsity.cc.
std::vector< Table< 2, Coupling > > DoFTools::dof_couplings_from_component_couplings  (  const hp::FECollection< dim, spacedim > &  fe, 
const Table< 2, Coupling > &  component_couplings  
) 
Same function as above for a collection of finite elements, returning a collection of tables.
The function currently treats DoFTools::Couplings::nonzero the same as DoFTools::Couplings::always .
Definition at line 738 of file dof_tools_sparsity.cc.
void DoFTools::make_periodicity_constraints  (  const FaceIterator &  face_1, 
const typename identity< FaceIterator >::type &  face_2,  
AffineConstraints< number > &  constraints,  
const ComponentMask &  component_mask = ComponentMask() , 

const bool  face_orientation = true , 

const bool  face_flip = false , 

const bool  face_rotation = false , 

const FullMatrix< double > &  matrix = FullMatrix<double>() , 

const std::vector< unsigned int > &  first_vector_components = std::vector<unsigned int>() , 

const number  periodicity_factor = 1. 

) 
Insert the (algebraic) constraints due to periodic boundary conditions into an AffineConstraints object constraints
.
Given a pair of not necessarily active boundary faces face_1
and face_2
, this functions constrains all DoFs associated with the boundary described by face_1
to the respective DoFs of the boundary described by face_2
. More precisely:
If face_1
and face_2
are both active faces it adds the DoFs of face_1
to the list of constrained DoFs in constraints
and adds entries to constrain them to the corresponding values of the DoFs on face_2
. This happens on a purely algebraic level, meaning, the global DoF with (local face) index i
on face_1
gets constraint to the DoF with (local face) index i
on face_2
(possibly corrected for orientation, see below).
Otherwise, if face_1
and face_2
are not active faces, this function loops recursively over the children of face_1
and face_2
. If only one of the two faces is active, then we recursively iterate over the children of the nonactive ones and make sure that the solution function on the refined side equals that on the nonrefined face in much the same way as we enforce hanging node constraints at places where differently refined cells come together. (However, unlike hanging nodes, we do not enforce the requirement that there be only a difference of one refinement level between the two sides of the domain you would like to be periodic).
This routine only constrains DoFs that are not already constrained. If this routine encounters a DoF that already is constrained (for instance by Dirichlet boundary conditions), the old setting of the constraint (dofs the entry is constrained to, inhomogeneities) is kept and nothing happens.
The flags in the component_mask
(see GlossComponentMask) denote which components of the finite element space shall be constrained with periodic boundary conditions. If it is left as specified by the default value all components are constrained. If it is different from the default value, it is assumed that the number of entries equals the number of components of the finite element. This can be used to enforce periodicity in only one variable in a system of equations.
face_orientation
, face_flip
and face_rotation
describe an orientation that should be applied to face_1
prior to matching and constraining DoFs. This has nothing to do with the actual orientation of the given faces in their respective cells (which for boundary faces is always the default) but instead how you want to see periodicity to be enforced. For example, by using these flags, you can enforce a condition of the kind \(u(0,y)=u(1,1y)\) (i.e., a Moebius band) or in 3d a twisted torus. More precisely, these flags match local face DoF indices in the following manner:
In 2d: face_orientation
must always be true
, face_rotation
is always false
, and face_flip has the meaning of line_flip
; this implies e.g. for Q1
:
And similarly for the case of Q1 in 3d:
Optionally a matrix matrix
along with a std::vector first_vector_components
can be specified that describes how DoFs on face_1
should be modified prior to constraining to the DoFs of face_2
. Here, two declarations are possible: If the std::vector first_vector_components
is non empty the matrix is interpreted as a dim
\(\times\) dim
rotation matrix that is applied to all vector valued blocks listed in first_vector_components
of the FESystem. If first_vector_components
is empty the matrix is interpreted as an interpolation matrix with size no_face_dofs \(\times\) no_face_dofs.
This function makes sure that identity constraints don't create cycles in constraints
.
periodicity_factor
can be used to implement Bloch periodic conditions (a.k.a. phase shift periodic conditions) of the form \(\psi(\mathbf{r})=e^{i\mathbf{k}\cdot\mathbf{r}}u(\mathbf{r})\) where \(u\) is periodic with the same periodicity as the crystal lattice and \(\mathbf{k}\) is the wavevector, see https://en.wikipedia.org/wiki/Bloch_wave. The solution at face_2
is equal to the solution at face_1
times periodicity_factor
. For example, if the solution at face_1
is \(\psi(0)\) and \(\mathbf{d}\) is the corresponding point on face_2
, then the solution at face_2
should be \(\psi(d) = \psi(0)e^{i \mathbf{k}\cdot \mathbf{d}}\). This condition can be implemented using \(\mathrm{periodicity\_factor}=e^{i \mathbf{k}\cdot \mathbf{d}}\).
Detailed information can be found in the see Glossary entry on periodic boundary conditions.
Definition at line 2289 of file dof_tools_constraints.cc.
void DoFTools::make_periodicity_constraints  (  const std::vector< GridTools::PeriodicFacePair< typename DoFHandler< dim, spacedim >::cell_iterator > > &  periodic_faces, 
AffineConstraints< number > &  constraints,  
const ComponentMask &  component_mask = ComponentMask() , 

const std::vector< unsigned int > &  first_vector_components = std::vector<unsigned int>() , 

const number  periodicity_factor = 1. 

) 
Insert the (algebraic) constraints due to periodic boundary conditions into an AffineConstraints object constraints
.
This is the main high level interface for above low level variant of make_periodicity_constraints(). It takes a std::vector periodic_faces
as argument and applies above make_periodicity_constraints() on each entry. periodic_faces
can be created by GridTools::collect_periodic_faces.
Definition at line 2533 of file dof_tools_constraints.cc.
void DoFTools::make_periodicity_constraints  (  const std::vector< GridTools::PeriodicFacePair< typename DoFHandlerType::cell_iterator > > &  periodic_faces, 
AffineConstraints< number > &  constraints,  
const ComponentMask &  component_mask = ComponentMask() , 

const std::vector< unsigned int > &  first_vector_components = std::vector< unsigned int >() , 

const number  periodicity_factor = 1. 

) 
The same as above.
void DoFTools::make_periodicity_constraints  (  const DoFHandler< dim, spacedim > &  dof_handler, 
const types::boundary_id  b_id1,  
const types::boundary_id  b_id2,  
const unsigned int  direction,  
AffineConstraints< number > &  constraints,  
const ComponentMask &  component_mask = ComponentMask() , 

const number  periodicity_factor = 1. 

) 
Insert the (algebraic) constraints due to periodic boundary conditions into a AffineConstraints constraints
.
This function serves as a high level interface for the make_periodicity_constraints() function.
Define a 'first' boundary as all boundary faces having boundary_id b_id1
and a 'second' boundary consisting of all faces belonging to b_id2
.
This function tries to match all faces belonging to the first boundary with faces belonging to the second boundary with the help of orthogonal_equality(). More precisely, faces with coordinates only differing in the direction
component are identified.
If this matching is successful it constrains all DoFs associated with the 'first' boundary to the respective DoFs of the 'second' boundary respecting the relative orientation of the two faces.
void DoFTools::make_periodicity_constraints  (  const DoFHandler< dim, spacedim > &  dof_handler, 
const types::boundary_id  b_id,  
const unsigned int  direction,  
AffineConstraints< number > &  constraints,  
const ComponentMask &  component_mask = ComponentMask() , 

const number  periodicity_factor = 1. 

) 
This compatibility version of make_periodicity_constraints only works on grids with cells in standard orientation.
Instead of defining a 'first' and 'second' boundary with the help of two boundary_ids this function defines a 'left' boundary as all faces with local face index 2*dimension
and boundary indicator b_id
and, similarly, a 'right' boundary consisting of all face with local face index 2*dimension+1
and boundary indicator b_id
. Faces with coordinates only differing in the direction
component are identified.
Definition at line 2607 of file dof_tools_constraints.cc.
IndexSet DoFTools::extract_hanging_node_dofs  (  const DoFHandler< dim, spacedim > &  dof_handler  ) 
Return an IndexSet describing all dofs that will be constrained by interface constraints, i.e. all hanging nodes.
In case of a parallel::shared::Triangulation or a parallel::distributed::Triangulation only locally relevant dofs are considered.
Definition at line 1012 of file dof_tools.cc.
IndexSet DoFTools::extract_dofs  (  const DoFHandler< dim, spacedim > &  dof_handler, 
const ComponentMask &  component_mask  
) 
Extract the (locally owned) indices of the degrees of freedom belonging to certain vector components of a vectorvalued finite element. The component_mask
defines which components or blocks of an FESystem or vectorvalued element are to be extracted from the DoFHandler dof
. The entries in the output object then correspond to degrees of freedom belonging to these components.
If the finite element under consideration is not primitive, i.e., some or all of its shape functions are nonzero in more than one vector component (which holds, for example, for FE_Nedelec or FE_RaviartThomas elements), then shape functions cannot be associated with a single vector component. In this case, if one shape vector component of this element is flagged in component_mask
(see GlossComponentMask), then this is equivalent to selecting all vector components corresponding to this nonprimitive base element.
[in]  dof_handler  The DoFHandler whose enumerated degrees of freedom are to be filtered by this function. 
[in]  component_mask  A mask that states which components you want to select. The size of this mask must be compatible with the number of components in the FiniteElement used by the dof_handler . See the glossary entry on component masks for more information. 
Definition at line 390 of file dof_tools.cc.
IndexSet DoFTools::extract_dofs  (  const DoFHandler< dim, spacedim > &  dof_handler, 
const BlockMask &  block_mask  
) 
This function is the equivalent to the DoFTools::extract_dofs() functions above except that the selection of which degrees of freedom to extract is not done based on components (see GlossComponent) but instead based on whether they are part of a particular block (see GlossBlock). Consequently, the second argument is not a ComponentMask but a BlockMask object.
[in]  dof_handler  The DoFHandler whose enumerated degrees of freedom are to be filtered by this function. 
[in]  block_mask  A mask that states which blocks you want to select. The size of this mask must be compatible with the number of blocks in the FiniteElement used by the dof_handler . See the glossary entry on block masks for more information. 
Definition at line 431 of file dof_tools.cc.
void DoFTools::extract_level_dofs  (  const unsigned int  level, 
const DoFHandler< dim, spacedim > &  dof,  
const ComponentMask &  component_mask,  
std::vector< bool > &  selected_dofs  
) 
Do the same thing as the corresponding extract_dofs() function for one level of a multigrid DoF numbering.
Definition at line 477 of file dof_tools.cc.
void DoFTools::extract_level_dofs  (  const unsigned int  level, 
const DoFHandler< dim, spacedim > &  dof,  
const BlockMask &  component_mask,  
std::vector< bool > &  selected_dofs  
) 
Do the same thing as the corresponding extract_dofs() function for one level of a multigrid DoF numbering.
Definition at line 533 of file dof_tools.cc.
void DoFTools::extract_boundary_dofs  (  const DoFHandler< dim, spacedim > &  dof_handler, 
const ComponentMask &  component_mask,  
std::vector< bool > &  selected_dofs,  
const std::set< types::boundary_id > &  boundary_ids = {} 

) 
Extract all degrees of freedom which are at the boundary and belong to specified components of the solution. The function returns its results in the last nondefaultvalued parameter which contains true
if a degree of freedom is at the boundary and belongs to one of the selected components, and false
otherwise.
By specifying the boundary_ids
variable, you can select which boundary indicators the faces have to have on which the degrees of freedom are located that shall be extracted. If it is an empty list, then all boundary indicators are accepted.
The size of component_mask
(see GlossComponentMask) shall equal the number of components in the finite element used by dof
. The size of selected_dofs
shall equal dof_handler.n_dofs()
. Previous contents of this array are overwritten.
Using the usual convention, if a shape function is nonzero in more than one component (i.e. it is nonprimitive), then the element in the component mask is used that corresponds to the first nonzero components. Elements in the mask corresponding to later components are ignored.
selected_dofs
has to have a length equal to all global degrees of freedom. Consequently, this does not scale to very large problems, and this is also why the function is deprecated. If you need the functionality of this function for parallel triangulations, then you need to use the other DoFTools::extract_boundary_dofs() function that returns its information via an IndexSet object.[in]  dof_handler  The object that describes which degrees of freedom live on which cell. 
[in]  component_mask  A mask denoting the vector components of the finite element that should be considered (see also GlossComponentMask). 
[out]  selected_dofs  A vector of booleans that is returned and for which an element will be true if the corresponding index is a degree of freedom that is located on the boundary (and correspond to the selected vector components and boundary indicators, depending on the values of the component_mask and boundary_ids arguments). 
[in]  boundary_ids  If empty, this function extracts the indices of the degrees of freedom for all parts of the boundary. If it is a non empty list, then the function only considers boundary faces with the boundary indicators listed in this argument. 
Definition at line 549 of file dof_tools.cc.
IndexSet DoFTools::extract_boundary_dofs  (  const DoFHandler< dim, spacedim > &  dof_handler, 
const ComponentMask &  component_mask = ComponentMask() , 

const std::set< types::boundary_id > &  boundary_ids = {} 

) 
Extract all degrees of freedom which are at the boundary and belong to specified components of the solution. The function returns its results in the form of an IndexSet that contains those entries that correspond to these selected degrees of freedom, i.e., which are at the boundary and belong to one of the selected components.
By specifying the boundary_ids
variable, you can select which boundary indicators the faces have to have on which the degrees of freedom are located that shall be extracted. If it is an empty list (the default), then all boundary indicators are accepted.
This function is used in step11 and step15, for example.
[in]  dof_handler  The object that describes which degrees of freedom live on which cell. 
[in]  component_mask  A mask denoting the vector components of the finite element that should be considered (see also GlossComponentMask). If left at the default, the component mask indicates that all vector components of the finite element should be considered. 
[in]  boundary_ids  If empty, this function extracts the indices of the degrees of freedom for all parts of the boundary. If it is a nonempty list, then the function only considers boundary faces with the boundary indicators listed in this argument. 
component_mask
and boundary_ids
arguments).Definition at line 590 of file dof_tools.cc.
void DoFTools::extract_boundary_dofs  (  const DoFHandler< dim, spacedim > &  dof_handler, 
const ComponentMask &  component_mask,  
IndexSet &  selected_dofs,  
const std::set< types::boundary_id > &  boundary_ids = {} 

) 
The same as the previous function, except that it returns its information via the third argument.
Definition at line 576 of file dof_tools.cc.
void DoFTools::extract_dofs_with_support_on_boundary  (  const DoFHandler< dim, spacedim > &  dof_handler, 
const ComponentMask &  component_mask,  
std::vector< bool > &  selected_dofs,  
const std::set< types::boundary_id > &  boundary_ids = std::set<types::boundary_id>() 

) 
This function is similar to the extract_boundary_dofs() function but it extracts those degrees of freedom whose shape functions are nonzero on at least part of the selected boundary. For continuous elements, this is exactly the set of shape functions whose degrees of freedom are defined on boundary faces. On the other hand, if the finite element in used is a discontinuous element, all degrees of freedom are defined in the inside of cells and consequently none would be boundary degrees of freedom. Several of those would have shape functions that are nonzero on the boundary, however. This function therefore extracts all those for which the FiniteElement::has_support_on_face function says that it is nonzero on any face on one of the selected boundary parts.
Definition at line 718 of file dof_tools.cc.
IndexSet DoFTools::extract_dofs_with_support_contained_within  (  const DoFHandler< dim, spacedim > &  dof_handler, 
const std::function< bool(const typename DoFHandler< dim, spacedim >::active_cell_iterator &)> &  predicate,  
const AffineConstraints< number > &  constraints = AffineConstraints<number>() 

) 
Extract all indices of shape functions such that their support is entirely contained within the cells for which the predicate
is true
. The result is returned as an IndexSet.
Consider the following FE space where predicate returns true
for all cells on the left half of the domain:
This functions will return the union of all DoF indices on those cells minus DoF 11, 13, 2 and 0; the result will be [9,10], 12, [14,38]
. In the image above the returned DoFs are separated from the rest by the red line
Essentially, the question this functions answers is the following: Given a subdomain with associated DoFs, what is the largest subset of these DoFs that are allowed to be nonzero such that after calling AffineConstraints::distribute() the resulting solution vector will have support only within the given domain. Here, constraints
is the AffineConstraints container containing hanging nodes constraints.
In case of parallel::distributed::Triangulation predicate
will be called only for locally owned and ghost cells. The resulting index set may contain DoFs that are associated with the locally owned or ghost cells, but are not owned by the current MPI core.
Definition at line 800 of file dof_tools.cc.
void DoFTools::extract_constant_modes  (  const DoFHandler< dim, spacedim > &  dof_handler, 
const ComponentMask &  component_mask,  
std::vector< std::vector< bool > > &  constant_modes  
) 
Extract a vector that represents the constant modes of the DoFHandler for the components chosen by component_mask
(see GlossComponentMask). The constant modes on a discretization are the null space of a Laplace operator on the selected components with Neumann boundary conditions applied. The null space is a necessary ingredient for obtaining a good AMG preconditioner when using the class TrilinosWrappers::PreconditionAMG. Since the ML AMG package only works on algebraic properties of the respective matrix, it has no chance to detect whether the matrix comes from a scalar or a vector valued problem. However, a near null space supplies exactly the needed information about the components' placement of vector components within the matrix. The null space (or rather, the constant modes) is provided by the finite element underlying the given DoFHandler and for most elements, the null space will consist of as many vectors as there are true
arguments in component_mask
(see GlossComponentMask), each of which will be one in one vector component and zero in all others. However, the representation of the constant function for e.g. FE_DGP is different (the first component on each element one, all other components zero), and some scalar elements may even have two constant modes (FE_Q_DG0). Therefore, we store this object in a vector of vectors, where the outer vector contains the collection of the actual constant modes on the DoFHandler. Each inner vector has as many components as there are (locally owned) degrees of freedom in the selected components. Note that any matrix associated with this null space must have been constructed using the same component_mask
argument, since the numbering of DoFs is done relative to the selected dofs, not to all dofs.
The main reason for this program is the use of the null space with the AMG preconditioner.
This function is used in step31, step32, and step42, for example.
Definition at line 1255 of file dof_tools.cc.
void DoFTools::extract_subdomain_dofs  (  const DoFHandler< dim, spacedim > &  dof_handler, 
const types::subdomain_id  subdomain_id,  
std::vector< bool > &  selected_dofs  
) 
Flag all those degrees of freedom which are on cells with the given subdomain id. Note that DoFs on faces can belong to cells with differing subdomain ids, so the sets of flagged degrees of freedom are not mutually exclusive for different subdomain ids.
If you want to get a unique association of degree of freedom with subdomains, use the get_subdomain_association
function.
Definition at line 1021 of file dof_tools.cc.
IndexSet DoFTools::extract_locally_active_dofs  (  const DoFHandler< dim, spacedim > &  dof_handler  ) 
Extract the set of global DoF indices that are active on the current DoFHandler. For regular DoFHandlers, these are all DoF indices, but for DoFHandler objects built on parallel::distributed::Triangulation this set is a superset of DoFHandler::locally_owned_dofs() and contains all DoF indices that live on all locally owned cells (including on the interface to ghost cells). However, it does not contain the DoF indices that are exclusively defined on ghost or artificial cells (see the glossary).
The degrees of freedom identified by this function equal those obtained from the dof_indices_with_subdomain_association() function when called with the locally owned subdomain id.
Definition at line 1052 of file dof_tools.cc.
void DoFTools::extract_locally_active_dofs  (  const DoFHandler< dim, spacedim > &  dof_handler, 
IndexSet &  dof_set  
) 
Extract the set of global DoF indices that are active on the current DoFHandler. For regular DoFHandlers, these are all DoF indices, but for DoFHandler objects built on parallel::distributed::Triangulation this set is a superset of DoFHandler::locally_owned_dofs() and contains all DoF indices that live on all locally owned cells (including on the interface to ghost cells). However, it does not contain the DoF indices that are exclusively defined on ghost or artificial cells (see the glossary).
The degrees of freedom identified by this function equal those obtained from the dof_indices_with_subdomain_association() function when called with the locally owned subdomain id.
Definition at line 1085 of file dof_tools.cc.
IndexSet DoFTools::extract_locally_active_level_dofs  (  const DoFHandler< dim, spacedim > &  dof_handler, 
const unsigned int  level  
) 
Same function as above but for a certain (multigrid)level. This function returns all DoF indices that live on all locally owned cells (including on the interface to ghost cells) on the given level.
Definition at line 1095 of file dof_tools.cc.
void DoFTools::extract_locally_active_level_dofs  (  const DoFHandler< dim, spacedim > &  dof_handler, 
IndexSet &  dof_set,  
const unsigned int  level  
) 
Same function as above but for a certain (multigrid)level. This function returns all DoF indices that live on all locally owned cells (including on the interface to ghost cells) on the given level.
Definition at line 1132 of file dof_tools.cc.
IndexSet DoFTools::extract_locally_relevant_dofs  (  const DoFHandler< dim, spacedim > &  dof_handler  ) 
Extract the set of global DoF indices that are active on the current DoFHandler. For regular DoFHandlers, these are all DoF indices, but for DoFHandler objects built on parallel::distributed::Triangulation this set is the union of DoFHandler::locally_owned_dofs() and the DoF indices on all ghost cells. In essence, it is the DoF indices on all cells that are not artificial (see the glossary).
Definition at line 1144 of file dof_tools.cc.
void DoFTools::extract_locally_relevant_dofs  (  const DoFHandler< dim, spacedim > &  dof_handler, 
IndexSet &  dof_set  
) 
Extract the set of global DoF indices that are active on the current DoFHandler. For regular DoFHandlers, these are all DoF indices, but for DoFHandler objects built on parallel::distributed::Triangulation this set is the union of DoFHandler::locally_owned_dofs() and the DoF indices on all ghost cells. In essence, it is the DoF indices on all cells that are not artificial (see the glossary).
Definition at line 1184 of file dof_tools.cc.
std::vector< IndexSet > DoFTools::locally_owned_dofs_per_component  (  const DoFHandler< dim, spacedim > &  dof_handler, 
const ComponentMask &  components = ComponentMask() 

) 
Extract the set of locally owned DoF indices for each component within the mask that are owned by the current processor. For components disabled by the mask, an empty IndexSet is returned. For a scalar DoFHandler built on a sequential triangulation, the return vector contains a single complete IndexSet with all DoF indices. If the mask contains all components (which also corresponds to the default value), then the union of the returned index sets equlas what DoFHandler::locally_owned_dofs() returns.
Definition at line 443 of file dof_tools.cc.
std::vector< IndexSet > DoFTools::locally_owned_dofs_per_subdomain  (  const DoFHandler< dim, spacedim > &  dof_handler  ) 
For each processor, determine the set of locally owned degrees of freedom as an IndexSet. This function then returns a vector of index sets, where the vector has size equal to the number of MPI processes that participate in the DoF handler object.
The function can be used for objects of type Triangulation or parallel::shared::Triangulation. It will not work for objects of type parallel::distributed::Triangulation since for such triangulations we do not have information about all cells of the triangulation available locally, and consequently can not say anything definitive about the degrees of freedom active on other processors' locally owned cells.
Definition at line 1383 of file dof_tools.cc.
std::vector< IndexSet > DoFTools::locally_relevant_dofs_per_subdomain  (  const DoFHandler< dim, spacedim > &  dof_handler  ) 
For each processor, determine the set of locally relevant degrees of freedom as an IndexSet. This function then returns a vector of index sets, where the vector has size equal to the number of MPI processes that participate in the DoF handler object.
The function can be used for objects of type Triangulation or parallel::shared::Triangulation. It will not work for objects of type parallel::distributed::Triangulation since for such triangulations we do not have information about all cells of the triangulation available locally, and consequently can not say anything definitive about the degrees of freedom active on other processors' locally owned cells.
Definition at line 1478 of file dof_tools.cc.
IndexSet DoFTools::extract_locally_relevant_level_dofs  (  const DoFHandler< dim, spacedim > &  dof_handler, 
const unsigned int  level  
) 
Same as extract_locally_relevant_dofs() but for multigrid DoFs for the given level
.
Definition at line 1194 of file dof_tools.cc.
void DoFTools::extract_locally_relevant_level_dofs  (  const DoFHandler< dim, spacedim > &  dof_handler, 
const unsigned int  level,  
IndexSet &  dof_set  
) 
Same as extract_locally_relevant_dofs() but for multigrid DoFs for the given level
.
Definition at line 1243 of file dof_tools.cc.
void DoFTools::get_subdomain_association  (  const DoFHandler< dim, spacedim > &  dof_handler, 
std::vector< types::subdomain_id > &  subdomain  
) 
For each degree of freedom, return in the output array to which subdomain (as given by the cell>subdomain_id()
function) it belongs. The output array is supposed to have the right size already when calling this function.
Note that degrees of freedom associated with faces, edges, and vertices may be associated with multiple subdomains if they are sitting on partition boundaries. In these cases, we assign them to the process with the smaller subdomain id. This may lead to different numbers of degrees of freedom in partitions, even if the number of cells is perfectly equidistributed. While this is regrettable, it is not a problem in practice since the number of degrees of freedom on partition boundaries is asymptotically vanishing as we refine the mesh as long as the number of partitions is kept constant.
This function returns the association of each DoF with one subdomain. If you are looking for the association of each cell with a subdomain, either query the cell>subdomain_id()
function, or use the GridTools::get_subdomain_association
function.
Note that this function is of questionable use for DoFHandler objects built on parallel::distributed::Triangulation since in that case ownership of individual degrees of freedom by MPI processes is controlled by the DoF handler object, not based on some geometric algorithm in conjunction with subdomain id. In particular, the degrees of freedom identified by the functions in this namespace as associated with a subdomain are not the same the DoFHandler class identifies as those it owns.
Definition at line 1554 of file dof_tools.cc.
unsigned int DoFTools::count_dofs_with_subdomain_association  (  const DoFHandler< dim, spacedim > &  dof_handler, 
const types::subdomain_id  subdomain  
) 
Count how many degrees of freedom are uniquely associated with the given subdomain
index.
Note that there may be rare cases where cells with the given subdomain
index exist, but none of its degrees of freedom are actually associated with it. In that case, the returned value will be zero.
This function will generate an exception if there are no cells with the given subdomain
index.
This function returns the number of DoFs associated with one subdomain. If you are looking for the association of cells with this subdomain, use the GridTools::count_cells_with_subdomain_association
function.
Note that this function is of questionable use for DoFHandler objects built on parallel::distributed::Triangulation since in that case ownership of individual degrees of freedom by MPI processes is controlled by the DoF handler object, not based on some geometric algorithm in conjunction with subdomain id. In particular, the degrees of freedom identified by the functions in this namespace as associated with a subdomain are not the same the DoFHandler class identifies as those it owns.
Definition at line 1644 of file dof_tools.cc.
void DoFTools::count_dofs_with_subdomain_association  (  const DoFHandler< dim, spacedim > &  dof_handler, 
const types::subdomain_id  subdomain,  
std::vector< unsigned int > &  n_dofs_on_subdomain  
) 
Count how many degrees of freedom are uniquely associated with the given subdomain
index.
This function does what the previous one does except that it splits the result among the vector components of the finite element in use by the DoFHandler object. The last argument (which must have a length equal to the number of vector components) will therefore store how many degrees of freedom of each vector component are associated with the given subdomain.
Note that this function is of questionable use for DoFHandler objects built on parallel::distributed::Triangulation since in that case ownership of individual degrees of freedom by MPI processes is controlled by the DoF handler object, not based on some geometric algorithm in conjunction with subdomain id. In particular, the degrees of freedom identified by the functions in this namespace as associated with a subdomain are not the same the DoFHandler class identifies as those it owns.
Definition at line 1717 of file dof_tools.cc.
IndexSet DoFTools::dof_indices_with_subdomain_association  (  const DoFHandler< dim, spacedim > &  dof_handler, 
const types::subdomain_id  subdomain  
) 
Return a set of indices that denotes the degrees of freedom that live on the given subdomain, i.e. that are on cells owned by the current processor. Note that this includes the ones that this subdomain "owns" (i.e. the ones for which get_subdomain_association() returns a value equal to the subdomain given here and that are selected by the DoFHandler::locally_owned_dofs() function) but also all of those that sit on the boundary between the given subdomain and other subdomain. In essence, degrees of freedom that sit on boundaries between subdomain will be in the index sets returned by this function for more than one subdomain.
Note that this function is of questionable use for DoFHandler objects built on parallel::distributed::Triangulation since in that case ownership of individual degrees of freedom by MPI processes is controlled by the DoF handler object, not based on some geometric algorithm in conjunction with subdomain id. In particular, the degrees of freedom identified by the functions in this namespace as associated with a subdomain are not the same the DoFHandler class identifies as those it owns.
Definition at line 1661 of file dof_tools.cc.
std::vector< types::global_dof_index > DoFTools::get_dofs_on_patch  (  const std::vector< typename DoFHandler< dim, spacedim >::active_cell_iterator > &  patch  ) 
Return the set of degrees of freedom that live on a set of cells (i.e., a patch) described by the argument.
Patches are often used in defining error estimators that require the solution of a local problem on the patch surrounding each of the cells of the mesh. You can get a list of cells that form the patch around a given cell using GridTools::get_patch_around_cell(). While DoFTools::count_dofs_on_patch() can be used to determine the size of these local problems, so that one can assemble the local system and then solve it, it is still necessary to provide a mapping between the global indices of the degrees of freedom that live on the patch and a local enumeration. This function provides such a local enumeration by returning the set of degrees of freedom that live on the patch.
Since this set is returned in the form of a std::vector, one can also think of it as a mapping
where i
is an index into the returned vector (i.e., a the local index of a degree of freedom on the patch) and global_dof_index
is the global index of a degree of freedom located on the patch. The array returned has size equal to DoFTools::count_dofs_on_patch().
patch  A collection of cells within an object of type DoFHandler<dim, spacedim>::active_cell_iterator 
Definition at line 2782 of file dof_tools.cc.
std::vector< types::global_dof_index > DoFTools::get_dofs_on_patch  (  const std::vector< typename DoFHandlerType::active_cell_iterator > &  patch  ) 
The same as above.
void DoFTools::make_cell_patches  (  SparsityPattern &  block_list, 
const DoFHandler< dim, spacedim > &  dof_handler,  
const unsigned int  level,  
const std::vector< bool > &  selected_dofs = {} , 

const types::global_dof_index  offset = 0 

) 
Creates a sparsity pattern, which lists the degrees of freedom associated to each cell on the given level. This pattern can be used in RelaxationBlock classes as block list for additive and multiplicative Schwarz methods.
The row index in this pattern is the cell index resulting from standard iteration through a level of the Triangulation. For a parallel::distributed::Triangulation, only locally owned cells are entered.
The sparsity pattern is resized in this function to contain as many rows as there are locally owned cells on a given level, as many columns as there are degrees of freedom on this level.
selected_dofs
is a vector indexed by the local degrees of freedom on a cell. If it is used, only such dofs are entered into the block list which are selected. This allows for instance the exclusion of components or of dofs on the boundary.
Definition at line 2433 of file dof_tools.cc.
std::vector< unsigned int > DoFTools::make_vertex_patches  (  SparsityPattern &  block_list, 
const DoFHandler< dim, spacedim > &  dof_handler,  
const unsigned int  level,  
const bool  interior_dofs_only,  
const bool  boundary_patches = false , 

const bool  level_boundary_patches = false , 

const bool  single_cell_patches = false , 

const bool  invert_vertex_mapping = false 

) 
Create an incidence matrix that for every vertex on a given level of a multilevel DoFHandler flags which degrees of freedom are associated with the adjacent cells. This data structure is a matrix with as many rows as there are vertices on a given level, as many columns as there are degrees of freedom on this level, and entries that are either true or false. This data structure is conveniently represented by a SparsityPattern object. The sparsity pattern may be empty when entering this function and will be reinitialized to the correct size.
The function has some boolean arguments (listed below) controlling details of the generated patches. The default settings are those for ArnoldFalkWinther type smoothers for divergence and curl conforming finite elements with essential boundary conditions. Other applications are possible, in particular changing boundary_patches
for non essential boundary conditions.
This function returns the vertex_mapping
, that contains the mapping from the vertex indices to the block indices of the block_list
. For vertices that do not lead to a vertex patch, the entry in vertex_mapping
contains the value invalid_unsigned_int
. If invert_vertex_mapping
is set to true
, then the vertex_mapping
is inverted such that it contains the mapping from the block indices to the corresponding vertex indices.
block_list
: the SparsityPattern into which the patches will be stored.dof_handler
: the multilevel dof handler providing the topology operated on.interior_dofs_only
: for each patch of cells around a vertex, collect only the interior degrees of freedom of the patch and disregard those on the boundary of the patch. This is for instance the setting for smoothers of ArnoldFalkWinther type.boundary_patches
: include patches around vertices at the boundary of the domain. If not, only patches around interior vertices will be generated.level_boundary_patches
: same for refinement edges towards coarser cells.single_cell_patches
: if not true, patches containing a single cell are eliminated.invert_vertex_mapping
: if true, then the return value contains one vertex index for each block; if false, then the return value contains one block index or invalid_unsigned_int
for each vertex. Definition at line 2581 of file dof_tools.cc.
std::vector< unsigned int > DoFTools::make_vertex_patches  (  SparsityPattern &  block_list, 
const DoFHandler< dim, spacedim > &  dof_handler,  
const unsigned int  level,  
const BlockMask &  exclude_boundary_dofs = BlockMask() , 

const bool  boundary_patches = false , 

const bool  level_boundary_patches = false , 

const bool  single_cell_patches = false , 

const bool  invert_vertex_mapping = false 

) 
Same as above but allows boundary dofs on blocks to be excluded individually.
This is helpful if you want to use, for example, Taylor Hood elements as it allows you to not include the boundary DoFs for the velocity block on the patches while also letting you include the boundary DoFs for the pressure block.
For each patch of cells around a vertex, collect all of the interior degrees of freedom of the patch and disregard those on the boundary of the patch if the boolean value for the corresponding block in the BlockMask of exclude_boundary_dofs
is false.
Definition at line 2604 of file dof_tools.cc.
void DoFTools::make_child_patches  (  SparsityPattern &  block_list, 
const DoFHandler< dim, spacedim > &  dof_handler,  
const unsigned int  level,  
const bool  interior_dofs_only,  
const bool  boundary_dofs = false 

) 
Create an incidence matrix that for every cell on a given level of a multilevel DoFHandler flags which degrees of freedom are associated with children of this cell. This data structure is conveniently represented by a SparsityPattern object.
The function thus creates a sparsity pattern which in each row (with rows corresponding to the cells on this level) lists the degrees of freedom associated to the cells that are the children of this cell. The DoF indices used here are level dof indices of a multilevel hierarchy, i.e., they may be associated with children that are not themselves active. The sparsity pattern may be empty when entering this function and will be reinitialized to the correct size.
The function has some boolean arguments (listed below) controlling details of the generated patches. The default settings are those for ArnoldFalkWinther type smoothers for divergence and curl conforming finite elements with essential boundary conditions. Other applications are possible, in particular changing boundary_dofs
for non essential boundary conditions.
block_list
: the SparsityPattern into which the patches will be stored.dof_handler
: The multilevel dof handler providing the topology operated on.interior_dofs_only
: for each patch of cells around a vertex, collect only the interior degrees of freedom of the patch and disregard those on the boundary of the patch. This is for instance the setting for smoothers of ArnoldFalkWinther type.boundary_dofs
: include degrees of freedom, which would have excluded by interior_dofs_only
, but are lying on the boundary of the domain, and thus need smoothing. This parameter has no effect if interior_dofs_only
is false. Definition at line 2518 of file dof_tools.cc.
void DoFTools::make_single_patch  (  SparsityPattern &  block_list, 
const DoFHandler< dim, spacedim > &  dof_handler,  
const unsigned int  level,  
const bool  interior_dofs_only = false 

) 
Create a block list with only a single patch, which in turn contains all degrees of freedom on the given level.
This function is mostly a closure on level 0 for functions like make_child_patches() and make_vertex_patches(), which may produce an empty patch list.
block_list
: the SparsityPattern into which the patches will be stored.dof_handler
: The multilevel dof handler providing the topology operated on.level
The grid level used for building the list.interior_dofs_only
: if true, exclude degrees of freedom on the boundary of the domain. Definition at line 2476 of file dof_tools.cc.
std::vector< types::global_dof_index > DoFTools::count_dofs_per_fe_component  (  const DoFHandler< dim, spacedim > &  dof_handler, 
const bool  vector_valued_once = false , 

const std::vector< unsigned int > &  target_component = {} 

) 
Count how many degrees of freedom out of the total number belong to each component. If the number of components the finite element has is one (i.e. you only have one scalar variable), then the number in this component obviously equals the total number of degrees of freedom. Otherwise, the sum of the DoFs in all the components needs to equal the total number.
However, the last statement does not hold true if the finite element is not primitive, i.e. some or all of its shape functions are nonzero in more than one vector component. This applies, for example, to the Nedelec or RaviartThomas elements. In this case, a degree of freedom is counted in each component in which it is nonzero, so that the sum mentioned above is greater than the total number of degrees of freedom.
This behavior can be switched off by the optional parameter vector_valued_once
. If this is true
, the number of components of a nonprimitive vector valued element is collected only in the first component. All other components will have a count of zero.
The additional optional argument target_component
allows for a re sorting and grouping of components. To this end, it contains for each component the component number it shall be counted as. Having the same number entered several times sums up several components as the same. One of the applications of this argument is when you want to form block matrices and vectors, but want to pack several components into the same block (for example, when you have dim
velocities and one pressure, to put all velocities into one block, and the pressure into another).
The result is returned in dofs_per_component
. Note that the size of dofs_per_component
needs to be enough to hold all the indices specified in target_component
. If this is not the case, an assertion is thrown. The indices not targeted by target_components are left untouched.
Definition at line 1888 of file dof_tools.cc.
std::vector< types::global_dof_index > DoFTools::count_dofs_per_fe_block  (  const DoFHandler< dim, spacedim > &  dof, 
const std::vector< unsigned int > &  target_block = std::vector<unsigned int>() 

) 
Count the degrees of freedom in each block. This function is similar to count_dofs_per_component(), with the difference that the counting is done by blocks. See blocks in the glossary for details. Again the vectors are assumed to have the correct size before calling this function. If this is not the case, an assertion is thrown.
This function is used in the step22, step31, and step32 tutorial programs, among others.
Definition at line 1980 of file dof_tools.cc.
void DoFTools::get_active_fe_indices  (  const DoFHandler< dim, spacedim > &  dof_handler, 
std::vector< unsigned int > &  active_fe_indices  
) 
For each active cell of a DoFHandler, extract the active finite element index and fill the vector given as second argument. This vector is assumed to have as many entries as there are active cells.
For DoFHandler objects without hpcapabilities given as first argument, the returned vector will consist of only zeros, indicating that all cells use the same finite element. In hpmode, the values may be different, though.
Definition at line 1371 of file dof_tools.cc.
unsigned int DoFTools::count_dofs_on_patch  (  const std::vector< typename DoFHandler< dim, spacedim >::active_cell_iterator > &  patch  ) 
Count how many degrees of freedom live on a set of cells (i.e., a patch) described by the argument.
Patches are often used in defining error estimators that require the solution of a local problem on the patch surrounding each of the cells of the mesh. You can get a list of cells that form the patch around a given cell using GridTools::get_patch_around_cell(). This function is then useful in setting up the size of the linear system used to solve the local problem on the patch around a cell. The function DoFTools::get_dofs_on_patch() will then help to make the connection between global degrees of freedom and the local ones.
patch  A collection of cells within an object of type DoFHandler<dim, spacedim> 
Definition at line 2751 of file dof_tools.cc.
unsigned int DoFTools::count_dofs_on_patch  (  const std::vector< typename DoFHandlerType::active_cell_iterator > &  patch  ) 
The same as above.
void DoFTools::map_dof_to_boundary_indices  (  const DoFHandler< dim, spacedim > &  dof_handler, 
std::vector< types::global_dof_index > &  mapping  
) 
Create a mapping from degree of freedom indices to the index of that degree of freedom on the boundary. After this operation, mapping[dof]
gives the index of the degree of freedom with global number dof
in the list of degrees of freedom on the boundary. If the degree of freedom requested is not on the boundary, the value of mapping[dof]
is numbers::invalid_dof_index. This function is mainly used when setting up matrices and vectors on the boundary from the trial functions, which have global numbers, while the matrices and vectors use numbers of the trial functions local to the boundary.
Prior content of mapping
is deleted.
Definition at line 2069 of file dof_tools.cc.
void DoFTools::map_dof_to_boundary_indices  (  const DoFHandler< dim, spacedim > &  dof_handler, 
const std::set< types::boundary_id > &  boundary_ids,  
std::vector< types::global_dof_index > &  mapping  
) 
Same as the previous function, except that only those parts of the boundary are considered for which the boundary indicator is listed in the second argument.
See the general doc of this class for more information.
Definition at line 2108 of file dof_tools.cc.
void DoFTools::map_dofs_to_support_points  (  const Mapping< dim, spacedim > &  mapping, 
const DoFHandler< dim, spacedim > &  dof_handler,  
std::vector< Point< spacedim > > &  support_points,  
const ComponentMask &  mask = ComponentMask() 

) 
Return a list of support points (see this glossary entry) for all the degrees of freedom handled by this DoF handler object. This function, of course, only works if the finite element object used by the DoF handler object actually provides support points, i.e. no edge elements or the like. Otherwise, an exception is thrown.
[in]  mapping  The mapping from the reference cell to the real cell on which DoFs are defined. 
[in]  dof_handler  The object that describes which DoF indices live on which cell of the triangulation. 
[in,out]  support_points  A vector that stores the corresponding location of the dofs in real space coordinates. Previous content of this object is deleted in this function. 
[in]  mask  An optional component mask that restricts the components from which the support points are extracted. 
Definition at line 2251 of file dof_tools.cc.
void DoFTools::map_dofs_to_support_points  (  const ::hp::MappingCollection< dim, spacedim > &  mapping, 
const DoFHandler< dim, spacedim > &  dof_handler,  
std::vector< Point< spacedim > > &  support_points,  
const ComponentMask &  mask = ComponentMask() 

) 
Same as the previous function but for the hpcase.
void DoFTools::map_dofs_to_support_points  (  const Mapping< dim, spacedim > &  mapping, 
const DoFHandler< dim, spacedim > &  dof_handler,  
std::map< types::global_dof_index, Point< spacedim > > &  support_points,  
const ComponentMask &  mask = ComponentMask() 

) 
This function is a version of the above map_dofs_to_support_points function that doesn't simply return a vector of support points (see this glossary entry) with one entry for each global degree of freedom, but instead a map that maps from the DoFs index to its location. The point of this function is that it is also usable in cases where the DoFHandler is based on a parallel::TriangulationBase object (or any of the classes derived from parallel::TriangulationBase). In such cases, each processor will not be able to determine the support point location of all DoFs, and worse no processor may be able to hold a vector that would contain the locations of all DoFs even if they were known. As a consequence, this function constructs a map from those DoFs for which we can know the locations (namely, those DoFs that are locally relevant (see locally relevant DoFs) to their locations.
For nondistributed triangulations, the map returned as support_points
is of course dense, i.e., every DoF is to be found in it.
[in]  mapping  The mapping from the reference cell to the real cell on which DoFs are defined. 
[in]  dof_handler  The object that describes which DoF indices live on which cell of the triangulation. 
[in,out]  support_points  A map that for every locally relevant DoF index contains the corresponding location in real space coordinates. Previous content of this object is deleted in this function. 
[in]  mask  An optional component mask that restricts the components from which the support points are extracted. 
Definition at line 2302 of file dof_tools.cc.
void DoFTools::map_dofs_to_support_points  (  const ::hp::MappingCollection< dim, spacedim > &  mapping, 
const DoFHandler< dim, spacedim > &  dof_handler,  
std::map< types::global_dof_index, Point< spacedim > > &  support_points,  
const ComponentMask &  mask = ComponentMask() 

) 
Same as the previous function but for the hpcase.
void DoFTools::map_support_points_to_dofs  (  const Mapping< dim, spacedim > &  mapping, 
const DoFHandler< dim, spacedim > &  dof_handler,  
std::map< Point< spacedim >, types::global_dof_index, Comp > &  point_to_index_map  
) 
This is the opposite function to the one above. It generates a map where the keys are the support points of the degrees of freedom, while the values are the DoF indices. For a definition of support points, see this glossary entry.
Since there is no natural order in the space of points (except for the 1d case), you have to provide a map with an explicitly specified comparator object. This function is therefore templatized on the comparator object. Previous content of the map object is deleted in this function.
Just as with the function above, it is assumed that the finite element in use here actually supports the notion of support points of all its components.
void DoFTools::distribute_cell_to_dof_vector  (  const DoFHandler< dim, spacedim > &  dof_handler, 
const Vector< Number > &  cell_data,  
Vector< double > &  dof_data,  
const unsigned int  component = 0 

) 
Take a vector of values which live on cells (e.g. an error per cell) and distribute it to the dofs in such a way that a finite element field results, which can then be further processed, e.g. for output. You should note that the resulting field will not be continuous at hanging nodes. This can, however, easily be arranged by calling the appropriate distribute
function of an AffineConstraints object created for this DoFHandler object, after the vector has been fully assembled.
It is assumed that the number of elements in cell_data
equals the number of active cells and that the number of elements in dof_data
equals dof_handler.n_dofs()
.
Note that the input vector may be a vector of any data type as long as it is convertible to double
. The output vector, being a data vector on a DoF handler, always consists of elements of type double
.
In case the finite element used by this DoFHandler consists of more than one component, you need to specify which component in the output vector should be used to store the finite element field in; the default is zero (no other value is allowed if the finite element consists only of one component). All other components of the vector remain untouched, i.e. their contents are not changed.
This function cannot be used if the finite element in use has shape functions that are nonzero in more than one vector component (in deal.II speak: they are nonprimitive).
Definition at line 306 of file dof_tools.cc.
void DoFTools::write_gnuplot_dof_support_point_info  (  std::ostream &  out, 
const std::map< types::global_dof_index, Point< spacedim > > &  support_points  
) 
Generate text output readable by gnuplot with point data based on the given map support_points
. For each support point location, a string label containing a list of all DoFs from the map is generated. The map can be generated with a call to map_dofs_to_support_points() and is useful to visualize location and global numbering of unknowns.
An example for the format of each line in the output is:
where x, y, and z (present only in corresponding dimension) are the coordinates of the support point, followed by a list of DoF numbers.
The points with labels can be plotted as follows in gnuplot:
Examples (this also includes the grid written separately using GridOut):
To generate the mesh and the support point information in a single gnuplot file, use code similar to
and from within gnuplot execute the following command:
Alternatively, the following gnuplot script will generate a png file when executed as gnuplot gnuplot.gpl
on the command line:
Definition at line 2341 of file dof_tools.cc.
void DoFTools::map_dofs_to_support_points  (  const hp::MappingCollection< dim, spacedim > &  mapping, 
const DoFHandler< dim, spacedim > &  dof_handler,  
std::vector< Point< spacedim > > &  support_points,  
const ComponentMask &  mask  
) 
Definition at line 2277 of file dof_tools.cc.
void DoFTools::map_dofs_to_support_points  (  const hp::MappingCollection< dim, spacedim > &  mapping, 
const DoFHandler< dim, spacedim > &  dof_handler,  
std::map< types::global_dof_index, Point< spacedim > > &  support_points,  
const ComponentMask &  mask  
) 
Definition at line 2323 of file dof_tools.cc.
void DoFTools::make_periodicity_constraints  (  const DoFHandler< dim, spacedim > &  dof_handler, 
const types::boundary_id  b_id1,  
const types::boundary_id  b_id2,  
const unsigned int  direction,  
::AffineConstraints< number > &  constraints,  
const ComponentMask &  component_mask,  
const number  periodicity_factor  
) 
Definition at line 2574 of file dof_tools_constraints.cc.