void MetisPartitioner::partition_range(MeshBase & mesh,
MeshBase::element_iterator beg,
MeshBase::element_iterator end,
unsigned int n_pieces)
{
libmesh_assert_greater (n_pieces, 0);
// We don't yet support distributed meshes with this Partitioner
if (!mesh.is_serial())
libmesh_not_implemented();
// Check for an easy return
if (n_pieces == 1)
{
this->single_partition_range (beg, end);
return;
}
// What to do if the Metis library IS NOT present
#ifndef LIBMESH_HAVE_METIS
libmesh_here();
libMesh::err << "ERROR: The library has been built without" << std::endl
<< "Metis support. Using a space-filling curve" << std::endl
<< "partitioner instead!" << std::endl;
SFCPartitioner sfcp;
sfcp.partition_range (mesh, beg, end, n_pieces);
// What to do if the Metis library IS present
#else
LOG_SCOPE("partition_range()", "MetisPartitioner");
const dof_id_type n_range_elem = std::distance(beg, end);
// Metis will only consider the elements in the range.
// We need to map the range element ids into a
// contiguous range. Further, we want the unique range indexing to be
// independent of the element ordering, otherwise a circular dependency
// can result in which the partitioning depends on the ordering which
// depends on the partitioning...
vectormap<dof_id_type, dof_id_type> global_index_map;
global_index_map.reserve (n_range_elem);
{
std::vector<dof_id_type> global_index;
MeshCommunication().find_global_indices (mesh.comm(),
MeshTools::create_bounding_box(mesh),
beg, end, global_index);
libmesh_assert_equal_to (global_index.size(), n_range_elem);
MeshBase::element_iterator it = beg;
for (std::size_t cnt=0; it != end; ++it)
{
const Elem * elem = *it;
global_index_map.insert (std::make_pair(elem->id(), global_index[cnt++]));
}
libmesh_assert_equal_to (global_index_map.size(), n_range_elem);
}
// If we have boundary elements in this mesh, we want to account for
// the connectivity between them and interior elements. We can find
// interior elements from boundary elements, but we need to build up
// a lookup map to do the reverse.
typedef std::unordered_multimap<const Elem *, const Elem *> map_type;
map_type interior_to_boundary_map;
{
MeshBase::element_iterator it = beg;
for (; it != end; ++it)
{
const Elem * elem = *it;
// If we don't have an interior_parent then there's nothing
// to look us up.
if ((elem->dim() >= LIBMESH_DIM) ||
!elem->interior_parent())
continue;
// get all relevant interior elements
std::set<const Elem *> neighbor_set;
elem->find_interior_neighbors(neighbor_set);
std::set<const Elem *>::iterator n_it = neighbor_set.begin();
for (; n_it != neighbor_set.end(); ++n_it)
{
// FIXME - non-const versions of the std::set<const Elem
// *> returning methods would be nice
Elem * neighbor = const_cast<Elem *>(*n_it);
#if defined(LIBMESH_HAVE_UNORDERED_MULTIMAP) || \
defined(LIBMESH_HAVE_TR1_UNORDERED_MULTIMAP) || \
defined(LIBMESH_HAVE_HASH_MULTIMAP) || \
defined(LIBMESH_HAVE_EXT_HASH_MULTIMAP)
interior_to_boundary_map.insert(std::make_pair(neighbor, elem));
#else
interior_to_boundary_map.insert(interior_to_boundary_map.begin(),
std::make_pair(neighbor, elem));
#endif
}
}
}
// Data structure that Metis will fill up on processor 0 and broadcast.
std::vector<Metis::idx_t> part(n_range_elem);
// Invoke METIS, but only on processor 0.
// Then broadcast the resulting decomposition
if (mesh.processor_id() == 0)
{
// Data structures and parameters needed only on processor 0 by Metis.
// std::vector<Metis::idx_t> options(5);
std::vector<Metis::idx_t> vwgt(n_range_elem);
Metis::idx_t
n = static_cast<Metis::idx_t>(n_range_elem), // number of "nodes" (elements) in the graph
// wgtflag = 2, // weights on vertices only, none on edges
// numflag = 0, // C-style 0-based numbering
nparts = static_cast<Metis::idx_t>(n_pieces), // number of subdomains to create
edgecut = 0; // the numbers of edges cut by the resulting partition
// Set the options
// options[0] = 0; // use default options
// build the graph
METIS_CSR_Graph<Metis::idx_t> csr_graph;
csr_graph.offsets.resize(n_range_elem + 1, 0);
// Local scope for these
{
// build the graph in CSR format. Note that
// the edges in the graph will correspond to
// face neighbors
#ifdef LIBMESH_ENABLE_AMR
std::vector<const Elem *> neighbors_offspring;
#endif
#ifndef NDEBUG
std::size_t graph_size=0;
#endif
// (1) first pass - get the row sizes for each element by counting the number
// of face neighbors. Also populate the vwght array if necessary
MeshBase::element_iterator it = beg;
for (; it != end; ++it)
{
const Elem * elem = *it;
const dof_id_type elem_global_index =
global_index_map[elem->id()];
libmesh_assert_less (elem_global_index, vwgt.size());
// maybe there is a better weight?
// The weight is used to define what a balanced graph is
if (!_weights)
vwgt[elem_global_index] = elem->n_nodes();
else
vwgt[elem_global_index] = static_cast<Metis::idx_t>((*_weights)[elem->id()]);
unsigned int num_neighbors = 0;
// Loop over the element's neighbors. An element
// adjacency corresponds to a face neighbor
for (auto neighbor : elem->neighbor_ptr_range())
{
if (neighbor != libmesh_nullptr)
{
// If the neighbor is active, but is not in the
// range of elements being partitioned, treat it
// as a NULL neighbor.
if (neighbor->active() && !global_index_map.count(neighbor->id()))
continue;
// If the neighbor is active treat it
// as a connection
if (neighbor->active())
num_neighbors++;
#ifdef LIBMESH_ENABLE_AMR
// Otherwise we need to find all of the
// neighbor's children that are connected to
// us and add them
else
{
// The side of the neighbor to which
// we are connected
const unsigned int ns =
neighbor->which_neighbor_am_i (elem);
libmesh_assert_less (ns, neighbor->n_neighbors());
// Get all the active children (& grandchildren, etc...)
// of the neighbor.
// FIXME - this is the wrong thing, since we
// should be getting the active family tree on
// our side only. But adding too many graph
// links may cause hanging nodes to tend to be
// on partition interiors, which would reduce
// communication overhead for constraint
// equations, so we'll leave it.
neighbor->active_family_tree (neighbors_offspring);
// Get all the neighbor's children that
// live on that side and are thus connected
// to us
for (std::size_t nc=0; nc<neighbors_offspring.size(); nc++)
{
const Elem * child =
neighbors_offspring[nc];
// Skip neighbor offspring which are not in the range of elements being partitioned.
if (!global_index_map.count(child->id()))
continue;
// This does not assume a level-1 mesh.
// Note that since children have sides numbered
// coincident with the parent then this is a sufficient test.
if (child->neighbor_ptr(ns) == elem)
{
libmesh_assert (child->active());
num_neighbors++;
}
}
}
#endif /* ifdef LIBMESH_ENABLE_AMR */
}
}
// Check for any interior neighbors
if ((elem->dim() < LIBMESH_DIM) && elem->interior_parent())
{
// get all relevant interior elements
std::set<const Elem *> neighbor_set;
elem->find_interior_neighbors(neighbor_set);
num_neighbors += neighbor_set.size();
}
// Check for any boundary neighbors
typedef map_type::iterator map_it_type;
std::pair<map_it_type, map_it_type>
bounds = interior_to_boundary_map.equal_range(elem);
num_neighbors += std::distance(bounds.first, bounds.second);
csr_graph.prep_n_nonzeros(elem_global_index, num_neighbors);
#ifndef NDEBUG
graph_size += num_neighbors;
#endif
}
csr_graph.prepare_for_use();
// (2) second pass - fill the compressed adjacency array
it = beg;
for (; it != end; ++it)
{
const Elem * elem = *it;
const dof_id_type elem_global_index =
global_index_map[elem->id()];
unsigned int connection=0;
// Loop over the element's neighbors. An element
// adjacency corresponds to a face neighbor
for (auto neighbor : elem->neighbor_ptr_range())
{
if (neighbor != libmesh_nullptr)
{
// If the neighbor is active, but is not in the
// range of elements being partitioned, treat it
// as a NULL neighbor.
if (neighbor->active() && !global_index_map.count(neighbor->id()))
continue;
// If the neighbor is active treat it
// as a connection
if (neighbor->active())
csr_graph(elem_global_index, connection++) = global_index_map[neighbor->id()];
#ifdef LIBMESH_ENABLE_AMR
// Otherwise we need to find all of the
// neighbor's children that are connected to
// us and add them
else
{
// The side of the neighbor to which
// we are connected
const unsigned int ns =
neighbor->which_neighbor_am_i (elem);
libmesh_assert_less (ns, neighbor->n_neighbors());
// Get all the active children (& grandchildren, etc...)
// of the neighbor.
neighbor->active_family_tree (neighbors_offspring);
// Get all the neighbor's children that
// live on that side and are thus connected
// to us
for (std::size_t nc=0; nc<neighbors_offspring.size(); nc++)
{
const Elem * child =
neighbors_offspring[nc];
// Skip neighbor offspring which are not in the range of elements being partitioned.
if (!global_index_map.count(child->id()))
continue;
// This does not assume a level-1 mesh.
// Note that since children have sides numbered
// coincident with the parent then this is a sufficient test.
if (child->neighbor_ptr(ns) == elem)
{
libmesh_assert (child->active());
csr_graph(elem_global_index, connection++) = global_index_map[child->id()];
}
}
}
#endif /* ifdef LIBMESH_ENABLE_AMR */
}
}
if ((elem->dim() < LIBMESH_DIM) &&
elem->interior_parent())
{
// get all relevant interior elements
std::set<const Elem *> neighbor_set;
elem->find_interior_neighbors(neighbor_set);
std::set<const Elem *>::iterator n_it = neighbor_set.begin();
for (; n_it != neighbor_set.end(); ++n_it)
{
const Elem * neighbor = *n_it;
// Not all interior neighbors are necessarily in
// the same Mesh (hence not in the global_index_map).
// This will be the case when partitioning a
// BoundaryMesh, whose elements all have
// interior_parents() that belong to some other
// Mesh.
const Elem * queried_elem = mesh.query_elem_ptr(neighbor->id());
// Compare the neighbor and the queried_elem
// pointers, make sure they are the same.
if (queried_elem && queried_elem == neighbor)
{
vectormap<dof_id_type, dof_id_type>::iterator global_index_map_it =
global_index_map.find(neighbor->id());
// If the interior_neighbor is in the Mesh but
// not in the global_index_map, we have other issues.
if (global_index_map_it == global_index_map.end())
libmesh_error_msg("Interior neighbor with id " << neighbor->id() << " not found in global_index_map.");
else
csr_graph(elem_global_index, connection++) = global_index_map_it->second;
}
}
}
// Check for any boundary neighbors
for (const auto & pr : as_range(interior_to_boundary_map.equal_range(elem)))
{
const Elem * neighbor = pr.second;
csr_graph(elem_global_index, connection++) =
global_index_map[neighbor->id()];
}
}
// We create a non-empty vals for a disconnected graph, to
// work around a segfault from METIS.
libmesh_assert_equal_to (csr_graph.vals.size(),
std::max(graph_size, std::size_t(1)));
} // done building the graph
Metis::idx_t ncon = 1;
// Select which type of partitioning to create
// Use recursive if the number of partitions is less than or equal to 8
if (n_pieces <= 8)
Metis::METIS_PartGraphRecursive(&n,
&ncon,
&csr_graph.offsets[0],
&csr_graph.vals[0],
&vwgt[0],
libmesh_nullptr,
libmesh_nullptr,
&nparts,
libmesh_nullptr,
libmesh_nullptr,
libmesh_nullptr,
&edgecut,
&part[0]);
// Otherwise use kway
else
Metis::METIS_PartGraphKway(&n,
&ncon,
&csr_graph.offsets[0],
&csr_graph.vals[0],
&vwgt[0],
libmesh_nullptr,
libmesh_nullptr,
&nparts,
libmesh_nullptr,
libmesh_nullptr,
libmesh_nullptr,
&edgecut,
&part[0]);
} // end processor 0 part
// Broadcast the resulting partition
mesh.comm().broadcast(part);
// Assign the returned processor ids. The part array contains
// the processor id for each active element, but in terms of
// the contiguous indexing we defined above
{
MeshBase::element_iterator it = beg;
for (; it!=end; ++it)
{
Elem * elem = *it;
libmesh_assert (global_index_map.count(elem->id()));
const dof_id_type elem_global_index =
global_index_map[elem->id()];
libmesh_assert_less (elem_global_index, part.size());
const processor_id_type elem_procid =
static_cast<processor_id_type>(part[elem_global_index]);
elem->processor_id() = elem_procid;
}
}
#endif
}
