37auto compute_parent_facets(std::span<const std::int32_t> simplex_set)
39 static_assert(tdim == 2 or tdim == 3);
40 assert(simplex_set.size() % (tdim + 1) == 0);
42 = std::conditional_t<tdim == 2, std::array<std::int8_t, 12>,
43 std::array<std::int8_t, 32>>;
51 constexpr std::array<std::array<int, 3>, 3> facet_table_2d{
52 {{1, 2, 3}, {0, 2, 4}, {0, 1, 5}}};
54 constexpr std::array<std::array<int, 6>, 4> facet_table_3d{
60 const int ncells = simplex_set.size() / (tdim + 1);
61 for (
int fpi = 0; fpi < (tdim + 1); ++fpi)
64 for (
int cc = 0; cc < ncells; ++cc)
66 for (
int fci = 0; fci < (tdim + 1); ++fci)
69 std::array<int, tdim> cf, set_output;
71 int num_common_vertices;
72 if constexpr (tdim == 2)
74 for (
int j = 0; j < tdim; ++j)
75 cf[j] = simplex_set[cc * 3 + facet_table_2d[fci][j]];
77 std::ranges::sort(cf);
78 auto [last1, last2, it_last] = std::ranges::set_intersection(
79 facet_table_2d[fpi], cf, set_output.begin());
80 num_common_vertices = std::distance(set_output.begin(), it_last);
84 for (
int j = 0; j < tdim; ++j)
85 cf[j] = simplex_set[cc * 4 + facet_table_3d[fci][j]];
87 std::ranges::sort(cf);
88 auto [last1, last2, it_last] = std::ranges::set_intersection(
89 facet_table_3d[fpi], cf, set_output.begin());
90 num_common_vertices = std::distance(set_output.begin(), it_last);
93 if (num_common_vertices == tdim)
124std::pair<std::array<std::int32_t, 32>, std::size_t>
125get_simplices(std::span<const std::int64_t> indices,
126 std::span<const std::int32_t> longest_edge,
int tdim,
132 std::span<std::int8_t> marked_edges,
134 std::span<const std::int32_t> long_edge);
145template <std::
floating_po
int T>
146std::pair<std::vector<std::int32_t>, std::vector<std::int8_t>>
149 const int tdim = mesh.topology()->dim();
151 mesh.topology_mutable()->create_entities(1);
152 mesh.topology_mutable()->create_entities(2);
153 mesh.topology_mutable()->create_connectivity(2, 1);
154 mesh.topology_mutable()->create_connectivity(1, tdim);
155 mesh.topology_mutable()->create_connectivity(tdim, 2);
157 std::int64_t num_faces = mesh.topology()->index_map(2)->size_local()
158 + mesh.topology()->index_map(2)->num_ghosts();
161 std::vector<std::int32_t> long_edge(num_faces);
162 std::vector<std::int8_t> edge_ratio_ok;
166 const T min_ratio = std::sqrt(2.0) / 2.0;
168 edge_ratio_ok.resize(num_faces);
170 auto x_dofmap = mesh.geometry().dofmap();
172 auto c_to_v = mesh.topology()->connectivity(tdim, 0);
174 auto e_to_c = mesh.topology()->connectivity(1, tdim);
176 auto e_to_v = mesh.topology()->connectivity(1, 0);
180 auto map_e = mesh.topology()->index_map(1);
182 std::vector<T> edge_length(map_e->size_local() + map_e->num_ghosts());
183 for (std::size_t e = 0; e < edge_length.size(); ++e)
186 auto cells = e_to_c->links(e);
187 assert(!cells.empty());
188 auto cell_vertices = c_to_v->links(cells.front());
189 auto edge_vertices = e_to_v->links(e);
192 auto it0 = std::find(cell_vertices.begin(), cell_vertices.end(),
194 assert(it0 != cell_vertices.end());
195 const std::size_t local0 = std::distance(cell_vertices.begin(), it0);
196 auto it1 = std::find(cell_vertices.begin(), cell_vertices.end(),
198 assert(it1 != cell_vertices.end());
199 const std::size_t local1 = std::distance(cell_vertices.begin(), it1);
201 auto x_dofs = MDSPAN_IMPL_STANDARD_NAMESPACE::submdspan(
202 x_dofmap, cells.front(), MDSPAN_IMPL_STANDARD_NAMESPACE::full_extent);
203 std::span<const T, 3> x0(mesh.geometry().x().data() + 3 * x_dofs[local0],
205 std::span<const T, 3> x1(mesh.geometry().x().data() + 3 * x_dofs[local1],
209 edge_length[e] = std::sqrt(std::transform_reduce(
210 x0.begin(), x0.end(), x1.begin(), 0.0, std::plus<>(),
211 [](
auto x0,
auto x1) { return (x0 - x1) * (x0 - x1); }));
215 auto f_to_v = mesh.topology()->connectivity(2, 0);
217 auto f_to_e = mesh.topology()->connectivity(2, 1);
219 const std::vector global_indices
220 = mesh.topology()->index_map(0)->global_indices();
221 for (
int f = 0; f < f_to_v->num_nodes(); ++f)
223 auto face_edges = f_to_e->links(f);
225 std::int32_t imax = 0;
227 T min_len = std::numeric_limits<T>::max();
229 for (
int i = 0; i < 3; ++i)
231 const T e_len = edge_length[face_edges[i]];
232 min_len = std::min(e_len, min_len);
238 else if (tdim == 3 and e_len == max_len)
243 auto vertices = f_to_v->links(f);
244 const int vmax = vertices[imax];
245 const int vi = vertices[i];
246 if (global_indices[vi] > global_indices[vmax])
253 edge_ratio_ok[f] = (min_len / max_len >= min_ratio);
255 long_edge[f] = face_edges[imax];
258 return std::pair(std::move(long_edge), std::move(edge_ratio_ok));
285template <std::
floating_po
int T>
286std::tuple<graph::AdjacencyList<std::int64_t>, std::vector<T>,
287 std::array<std::size_t, 2>, std::optional<std::vector<std::int32_t>>,
288 std::optional<std::vector<std::int8_t>>>
289compute_refinement(MPI_Comm neighbor_comm,
290 std::span<const std::int8_t> marked_edges,
293 std::span<const std::int32_t> long_edge,
294 std::span<const std::int8_t> edge_ratio_ok,
Option option)
296 int tdim = mesh.topology()->dim();
297 int num_cell_edges = tdim * 3 - 3;
298 int num_cell_vertices = tdim + 1;
304 const auto [new_vertex_map, new_vertex_coords, xshape]
307 std::optional<std::vector<std::int32_t>>
parent_cell(std::nullopt);
308 if (compute_parent_cell)
311 std::optional<std::vector<std::int8_t>>
parent_facet(std::nullopt);
315 std::vector<std::int64_t> indices(num_cell_vertices + num_cell_edges);
316 std::vector<std::int32_t> simplex_set;
318 auto map_c = mesh.topology()->index_map(tdim);
320 auto c_to_v = mesh.topology()->connectivity(tdim, 0);
322 auto c_to_e = mesh.topology()->connectivity(tdim, 1);
324 auto c_to_f = mesh.topology()->connectivity(tdim, 2);
327 std::int32_t num_new_vertices_local = std::count(
328 marked_edges.begin(),
329 marked_edges.begin() + mesh.topology()->index_map(1)->size_local(),
true);
331 std::vector<std::int64_t> global_indices
332 =
adjust_indices(*mesh.topology()->index_map(0), num_new_vertices_local);
334 const std::int32_t num_cells = map_c->size_local();
337 std::vector<std::int64_t> cell_topology;
338 for (
int c = 0; c < num_cells; ++c)
344 auto vertices = c_to_v->links(c);
345 for (std::size_t v = 0; v < vertices.size(); ++v)
346 indices[v] = global_indices[vertices[v]];
349 auto edges = c_to_e->links(c);
350 bool no_edge_marked =
true;
351 for (std::size_t ei = 0; ei < edges.size(); ++ei)
353 if (marked_edges[edges[ei]])
355 no_edge_marked =
false;
356 auto it = new_vertex_map.find(edges[ei]);
357 assert(it != new_vertex_map.end());
358 indices[num_cell_vertices + ei] = it->second;
361 indices[num_cell_vertices + ei] = -1;
367 for (
auto v : vertices)
368 cell_topology.push_back(global_indices[v]);
370 if (compute_parent_cell)
385 std::vector<std::int32_t> longest_edge;
386 for (
auto f : c_to_f->links(c))
387 longest_edge.push_back(long_edge[f]);
390 for (std::int32_t& p : longest_edge)
392 for (std::size_t ej = 0; ej < edges.size(); ++ej)
402 const bool uniform = (tdim == 2) ? edge_ratio_ok[c] :
false;
403 const auto [simplex_set_b, simplex_set_size]
404 = get_simplices(indices, longest_edge, tdim, uniform);
405 std::span<const std::int32_t> simplex_set(simplex_set_b.data(),
409 const std::int32_t ncells = simplex_set.size() / num_cell_vertices;
410 if (compute_parent_cell)
412 for (std::int32_t i = 0; i < ncells; ++i)
420 auto npf = compute_parent_facets<3>(simplex_set);
422 std::next(npf.begin(), simplex_set.size()));
426 auto npf = compute_parent_facets<2>(simplex_set);
428 std::next(npf.begin(), simplex_set.size()));
433 for (std::int32_t v : simplex_set)
434 cell_topology.push_back(indices[v]);
438 assert(cell_topology.size() % num_cell_vertices == 0);
439 std::vector<std::int32_t> offsets(
440 cell_topology.size() / num_cell_vertices + 1, 0);
441 for (std::size_t i = 0; i < offsets.size() - 1; ++i)
442 offsets[i + 1] = offsets[i] + num_cell_vertices;
445 return {std::move(cell_adj), std::move(new_vertex_coords), xshape,
459template <std::
floating_po
int T>
460std::tuple<graph::AdjacencyList<std::int64_t>, std::vector<T>,
461 std::array<std::size_t, 2>, std::optional<std::vector<std::int32_t>>,
462 std::optional<std::vector<std::int8_t>>>
464 std::optional<std::span<const std::int32_t>> edges,
468 auto topology = mesh.topology();
471 if (topology->cell_type() != mesh::CellType::triangle
472 and topology->cell_type() != mesh::CellType::tetrahedron)
474 throw std::runtime_error(
"Cell type not supported");
477 auto map_e = topology->index_map(1);
479 throw std::runtime_error(
"Edges must be initialised");
486 std::vector<int> ranks(edge_ranks.
array().begin(), edge_ranks.
array().end());
487 std::ranges::sort(ranks);
488 auto [unique_end, range_end] = std::ranges::unique(ranks);
489 ranks.erase(unique_end, range_end);
492 std::ranges::transform(edge_ranks.
array(), edge_ranks.
array().begin(),
495 auto it = std::ranges::lower_bound(ranks, r);
496 assert(it != ranks.end() and *it == r);
497 return std::distance(ranks.begin(), it);
501 std::vector<std::int8_t> marked_edges(
502 map_e->size_local() + map_e->num_ghosts(), !edges.has_value());
503 std::vector<std::vector<std::int32_t>> marked_for_update(ranks.size());
505 if (edges.has_value())
507 for (
auto edge : edges.value())
509 if (!marked_edges[edge])
511 marked_edges[edge] =
true;
514 for (
int rank : edge_ranks.
links(edge))
515 marked_for_update[rank].push_back(edge);
521 MPI_Dist_graph_create_adjacent(mesh.comm(), ranks.size(), ranks.data(),
522 MPI_UNWEIGHTED, ranks.size(), ranks.data(),
523 MPI_UNWEIGHTED, MPI_INFO_NULL,
false, &comm);
530 const auto [long_edge, edge_ratio_ok] = impl::face_long_edge(mesh);
531 impl::enforce_rules(comm, edge_ranks, marked_edges, *topology, long_edge);
534 = impl::compute_refinement(comm, marked_edges, edge_ranks, mesh,
535 long_edge, edge_ratio_ok, option);
536 MPI_Comm_free(&comm);
538 return {std::move(cell_adj), std::move(new_vertex_coords), xshape,