5#ifndef DUNE_ISTL_REPARTITION_HH
6#define DUNE_ISTL_REPARTITION_HH
50#if HAVE_PARMETIS && defined(REALTYPEWIDTH)
56#if HAVE_PARMETIS && defined(IDXTYPEWIDTH)
58#elif HAVE_PARMETIS && defined(HAVE_SCOTCH_NUM_TYPE)
59 using idx_t = SCOTCH_Num;
82 template<
class G,
class T1,
class T2>
86 typedef typename IndexSet::LocalIndex::Attribute Attribute;
88 IndexSet& indexSet = oocomm.indexSet();
91 std::size_t sum=0, needed = graph.noVertices()-indexSet.size();
95 for(
int i=0; i<oocomm.communicator().
size(); ++i)
104 auto end = indexSet.
end();
105 for(
auto it = indexSet.begin(); it !=
end; ++it)
111 maxgi=oocomm.communicator().
max(maxgi);
114 for(
int i=0; i<oocomm.communicator().
rank(); ++i)
115 maxgi=maxgi+neededall[i];
120 indexSet.beginResize();
122 for(
auto vertex = graph.begin(), vend=graph.end(); vertex != vend; ++vertex) {
123 const typename IndexSet::IndexPair*
pair=lookup.
pair(*vertex);
131 indexSet.endResize();
135 oocomm.freeGlobalLookup();
136 oocomm.buildGlobalLookup();
146 class ParmetisDuneIndexMap
149 template<
class Graph,
class OOComm>
150 ParmetisDuneIndexMap(
const Graph& graph,
const OOComm& com);
151 int toParmetis(
int i)
const
153 return duneToParmetis[i];
155 int toLocalParmetis(
int i)
const
157 return duneToParmetis[i]-base_;
161 return duneToParmetis[i];
163 int toDune(
int i)
const
165 return parmetisToDune[i];
169 return parmetisToDune.size();
184 template<
class G,
class OOComm>
185 ParmetisDuneIndexMap::ParmetisDuneIndexMap(
const G& graph,
const OOComm& oocomm)
186 : duneToParmetis(graph.noVertices(), -1), vtxDist_(oocomm.
communicator().
size()+1)
188 int npes=oocomm.communicator().size(), mype=oocomm.communicator().rank();
190 typedef typename OOComm::OwnerSet OwnerSet;
193 auto end = oocomm.indexSet().end();
195 if (OwnerSet::contains(
index->local().attribute())) {
199 parmetisToDune.resize(numOfOwnVtx);
202 MPI_Allgather(&numOfOwnVtx, 1, MPI_INT, &(globalNumOfVtx[0]), 1, MPI_INT, oocomm.communicator());
206 for(
int i=0; i<npes; i++) {
208 base += globalNumOfVtx[i];
210 vtxDist_[i+1] = vtxDist_[i] + globalNumOfVtx[i];
216 std::cout << oocomm.communicator().rank()<<
" vtxDist: ";
217 for(
int i=0; i<= npes; ++i)
226 auto vend = graph.end();
227 for(
auto vertex = graph.begin(); vertex != vend; ++vertex) {
228 const typename OOComm::ParallelIndexSet::IndexPair*
index=oocomm.globalLookup().pair(*vertex);
230 if (OwnerSet::contains(
index->local().attribute())) {
232 parmetisToDune[base-base_]=
index->local();
233 duneToParmetis[
index->local()] = base++;
243 std::cout <<oocomm.communicator().rank()<<
": before ";
248 oocomm.copyOwnerToAll(duneToParmetis,duneToParmetis);
250 std::cout <<oocomm.communicator().rank()<<
": after ";
265 template<
class Flags,
class IS>
270 for(
auto i=idxset.begin(),
end=idxset.end(); i!=
end; ++i)
271 if(Flags::contains(i->local().attribute()))
272 ++sizes[toPart[i->local()]];
276 interfaces()[i->first].first.reserve(i->second);
279 for(
auto i=idxset.begin(),
end=idxset.end(); i!=
end; ++i)
280 if(Flags::contains(i->local().attribute()))
281 interfaces()[toPart[i->local()]].first.add(i->local());
292 template<
typename TG>
296 for(
auto idx=indices.begin(); idx!= indices.end(); ++idx) {
321 MPI_Pack(&s, 1, MPITraits<std::size_t>::getType(), sendBuf, buffersize, &pos, comm);
322 MPI_Pack(&(ownerVec[0]), s, MPITraits<GI>::getType(), sendBuf, buffersize, &pos, comm);
323 s = overlapVec.
size();
324 MPI_Pack(&s, 1, MPITraits<std::size_t>::getType(), sendBuf, buffersize, &pos, comm);
325 for(
auto i=overlapVec.
begin(),
end= overlapVec.
end(); i !=
end; ++i)
326 MPI_Pack(
const_cast<GI*
>(&(*i)), 1, MPITraits<GI>::getType(), sendBuf, buffersize, &pos, comm);
329 MPI_Pack(&s, 1, MPITraits<std::size_t>::getType(), sendBuf, buffersize, &pos, comm);
331 for(
auto i=neighbors.
begin(),
end= neighbors.
end(); i !=
end; ++i)
332 MPI_Pack(
const_cast<int*
>(&(*i)), 1, MPI_INT, sendBuf, buffersize, &pos, comm);
348 MPI_Unpack(recvBuf, bufferSize, &pos, &
size, 1, MPITraits<std::size_t>::getType(), comm);
349 inf.reserveSpaceForReceiveInterface(from,
size);
353 MPI_Unpack(recvBuf, bufferSize, &pos, &gi, 1, MPITraits<GI>::getType(), comm);
357 MPI_Unpack(recvBuf, bufferSize, &pos, &
size, 1, MPITraits<std::size_t>::getType(), comm);
362 MPI_Unpack(recvBuf, bufferSize, &pos, &gi, 1, MPITraits<GI>::getType(), comm);
363 ipos=overlapVec.
insert(ipos, gi);
366 MPI_Unpack(recvBuf, bufferSize, &pos, &
size, 1, MPITraits<std::size_t>::getType(), comm);
371 MPI_Unpack(recvBuf, bufferSize, &pos, &n, 1, MPI_INT, comm);
372 npos=neighbors.
insert(npos, n);
390 void getDomain(
const MPI_Comm& comm, T *part,
int numOfOwnVtx,
int nparts,
int *myDomain,
std::vector<int> &domainMapping) {
392 MPI_Comm_size(comm, &npes);
393 MPI_Comm_rank(comm, &mype);
401 domainMapping.
assign(domainMapping.
size(), -1);
404 for (
int i = 0; i < numOfOwnVtx; i++) {
411 int *buf =
new int[nparts];
412 for (
int i = 0; i < nparts; i++) {
414 domainMatrix[mype*nparts+i] = domain[i];
417 int src = (mype-1+npes)%npes;
418 int dest = (mype+1)%npes;
420 for (
int i = 0; i < npes-1; i++) {
421 MPI_Sendrecv_replace(buf, nparts, MPI_INT, dest, 0, src, 0, comm, &status);
423 pe = ((mype-1-i)+npes)%npes;
424 for(
int j = 0; j < nparts; j++) {
426 domainMatrix[pe*nparts+j] = buf[j];
434 int maxOccurance = 0;
438 for (
int i = 0; i < nparts; i++) {
439 for (
int j = 0; j < npes; j++) {
441 if (assigned[j]==0) {
442 if (maxOccurance < domainMatrix[j*nparts+i]) {
443 maxOccurance = domainMatrix[j*nparts+i];
451 domainMapping[i] = pe;
468 for(
auto udomain = unassigned.
begin(),
469 end = unassigned.
end(); udomain !=
end; ++udomain)
472 assert(next_free != assigned.end());
473 domainMapping[*udomain] = next_free-assigned.
begin();
481 bool operator()(
const T& t1,
const T& t2)
const
503 if(ownerVec.
size()>0)
505 auto old=ownerVec.
begin();
506 for(
auto i=old+1,
end=ownerVec.
end(); i !=
end; old=i++)
508 if(i->first==old->first)
510 std::cerr<<
"Value at index "<<old-ownerVec.
begin()<<
" is the same as at index "
511 <<i-ownerVec.
begin()<<
" ["<<old->first<<
","<<old->second<<
"]==["
512 <<i->first<<
","<<i->second<<
"]"<<
std::endl;
520 auto v=ownerVec.
begin(), vend=ownerVec.
end();
521 for(
auto s=overlapSet.
begin(), send=overlapSet.
end(); s!=send;)
523 while(v!=vend && v->first<*s) ++v;
524 if(v!=vend && v->first==*s) {
529 overlapSet.
erase(tmp);
549 template<
class OwnerSet,
class Graph,
class IS,
class GI>
551 typename Graph::VertexDescriptor vtx,
const IS& indexSet,
553 for(
auto edge=g.beginEdges(vtx),
end=g.endEdges(vtx); edge!=
end; ++edge)
555 const typename IS::IndexPair* pindex = indexSet.pair(edge.target());
557 if(part[pindex->local()]!=toPe || !OwnerSet::contains(pindex->local().attribute()))
560 neighbor.
insert(pindex->global());
561 neighborProcs.
insert(part[pindex->local()]);
566 template<
class T,
class I>
572 template<
class T,
class I>
583 redist.reserveSpaceForReceiveInterface(proc, ownerVec.
size());
604 template<
class OwnerSet,
class G,
class IS,
class T,
class GI>
605 void getOwnerOverlapVec(
const G& graph,
std::vector<int>& part, IS& indexSet,
607 RedistributeInterface& redist,
std::set<int>& neighborProcs) {
610 if(OwnerSet::contains(
index->local().attribute()))
612 if(part[
index->local()]==toPe)
614 getNeighbor<OwnerSet>(graph, part,
index->local(), indexSet,
615 toPe, overlapSet, neighborProcs);
616 my_push_back(ownerVec,
index->global(), toPe);
620 reserve(ownerVec, redist, toPe);
631 template<
class F,
class IS>
632 inline bool isOwner(IS& indexSet,
int index) {
634 const typename IS::IndexPair* pindex=indexSet.pair(
index);
637 return F::contains(pindex->local().attribute());
641 class BaseEdgeFunctor
644 BaseEdgeFunctor(Metis::idx_t* adj,
const ParmetisDuneIndexMap& data)
645 : i_(), adj_(adj), data_(
data)
653 adj_[i_] = data_.toParmetis(edge.target());
664 const ParmetisDuneIndexMap& data_;
669 :
public BaseEdgeFunctor
671 EdgeFunctor(Metis::idx_t* adj,
const ParmetisDuneIndexMap& data,
std::size_t)
672 : BaseEdgeFunctor(adj,
data)
675 Metis::idx_t* getWeights()
682 template<
class G,
class V,
class E,
class VM,
class EM>
683 class EdgeFunctor<
Dune::Amg::PropertiesGraph<G,V,E,VM,EM> >
684 :
public BaseEdgeFunctor
687 EdgeFunctor(Metis::idx_t* adj,
const ParmetisDuneIndexMap& data,
std::size_t s)
688 : BaseEdgeFunctor(adj,
data)
690 weight_=
new Metis::idx_t[s];
696 weight_[
index()]=edge.properties().depends() ? 3 : 1;
697 BaseEdgeFunctor::operator()(edge);
699 Metis::idx_t* getWeights()
708 Metis::idx_t* weight_;
726 template<
class F,
class G,
class IS,
class EW>
727 void getAdjArrays(G& graph, IS& indexSet, Metis::idx_t *xadj,
731 auto vend = graph.end();
733 for(
auto vertex = graph.begin(); vertex != vend; ++vertex) {
734 if (isOwner<F>(indexSet,*vertex)) {
736 auto eend = vertex.end();
737 xadj[j] = ew.index();
739 for(
auto edge = vertex.begin(); edge != eend; ++edge) {
744 xadj[j] = ew.index();
748 template<
class G,
class T1,
class T2>
752 RedistributeInterface& redistInf,
755#ifndef METIS_VER_MAJOR
759 void METIS_PartGraphKway(
int *nvtxs, Metis::idx_t *xadj, Metis::idx_t *adjncy, Metis::idx_t *vwgt,
760 Metis::idx_t *adjwgt,
int *wgtflag,
int *numflag,
int *nparts,
761 int *options,
int *edgecut, Metis::idx_t *part);
763 void METIS_PartGraphRecursive(
int *nvtxs, Metis::idx_t *xadj, Metis::idx_t *adjncy, Metis::idx_t *vwgt,
764 Metis::idx_t *adjwgt,
int *wgtflag,
int *numflag,
int *nparts,
765 int *options,
int *edgecut, Metis::idx_t *part);
770 template<
class S,
class T>
773 for(T *cur=array, *
end=array+l; cur!=
end; ++cur)
777 template<
class S,
class T>
779 T* adjncy,
bool checkSymmetry)
785 if(
static_cast<S
>(xadj[vtx])>noEdges || signbit(xadj[vtx])) {
786 std::cerr <<
"Check graph: xadj["<<vtx<<
"]="<<xadj[vtx]<<
" (>"
790 if(
static_cast<S
>(xadj[vtx+1])>noEdges || signbit(xadj[vtx+1])) {
791 std::cerr <<
"Check graph: xadj["<<vtx+1<<
"]="<<xadj[vtx+1]<<
" (>"
797 if(signbit(adjncy[i]) || ((
std::size_t)adjncy[i])>gnoVtx) {
798 std::cerr<<
" Edge "<<adjncy[i]<<
" out of range ["<<0<<
","<<noVtx<<
")"
808 for(
Metis::idx_t j=xadj[target]; j< xadj[target+1]; ++j)
821 template<
class M,
class T1,
class T2>
828 if(verbose && oocomm.communicator().
rank()==0)
829 std::cout<<
"Repartitioning from "<<oocomm.communicator().
size()
832 int rank = oocomm.communicator().
rank();
834 int* part =
new int[1];
847 int noNeighbours = oocomm.remoteIndices().
neighbours();
849 for(
auto n= oocomm.remoteIndices().
begin(); n != oocomm.remoteIndices().
end();
870 for(
int i=0; i<oocomm.communicator().
size(); ++i)
872 vtxdist[oocomm.communicator().
size()]=oocomm.communicator().
size();
875 xadj[1]=noNeighbours;
916 for(
auto n= oocomm.remoteIndices().
begin(); n != oocomm.remoteIndices().
end();
918 if(n->first != rank) {
927 vtxdist[oocomm.communicator().
size()],
928 noNeighbours, xadj, adjncy,
false));
937 for(
int i=0; i<nparts; ++i)
938 tpwgts[i]=1.0/nparts;
939 MPI_Comm comm=oocomm.communicator();
955 oocomm.communicator().
barrier();
956 if(verbose && oocomm.communicator().
rank()==0)
960#ifdef PARALLEL_PARTITION
968 ParMETIS_V3_PartKway(vtxdist, xadj, adjncy,
969 vwgt, adjwgt, &wgtflag,
970 &numflag, &ncon, &nparts, tpwgts, &ubvec,
options, &edgecut, part,
972 if(verbose && oocomm.communicator().
rank()==0)
979 noedges =
new int[oocomm.communicator().
size()];
982 MPI_Allgather(&noNeighbours,1,MPI_INT,noedges,1, MPI_INT,oocomm.communicator());
984 if(verbose && oocomm.communicator().
rank()==0)
1000 std::size_t localNoVtx=vtxdist[rank+1]-vtxdist[rank];
1002 std::size_t gxadjlen = vtxdist[oocomm.communicator().
size()]-vtxdist[0]+oocomm.communicator().
size();
1008 displ =
new int[oocomm.communicator().
size()];
1009 xdispl =
new int[oocomm.communicator().
size()];
1010 noxs =
new int[oocomm.communicator().
size()];
1011 vdispl =
new int[oocomm.communicator().
size()];
1012 novs =
new int[oocomm.communicator().
size()];
1014 for(
int i=0; i < oocomm.communicator().
size(); ++i) {
1015 noxs[i]=vtxdist[i+1]-vtxdist[i]+1;
1016 novs[i]=vtxdist[i+1]-vtxdist[i];
1021 for(
int *xcurr = xdispl, *vcurr = vdispl, *
end=vdispl+oocomm.communicator().
size();
1022 vcurr!=
end; ++vcurr, ++xcurr, ++so, ++offset) {
1024 *xcurr = offset + *so;
1030 for(
int *curr=noedges, *
end=noedges+oocomm.communicator().
size()-1;
1031 curr!=
end; ++curr) {
1042 for(
int *curr=noedges, *
end=noedges+oocomm.communicator().
size();
1047 Dune::dinfo<<
"gxadjlen: "<<gxadjlen<<
" noVertices: "<<noVertices
1058 if(verbose && oocomm.communicator().
rank()==0)
1077 if(verbose && oocomm.communicator().
rank()==0)
1090 for(
int i=1; i<oocomm.communicator().
size(); ++i) {
1092 int lprev = vtxdist[i]-vtxdist[i-1];
1093 int l = vtxdist[i+1]-vtxdist[i];
1095 assert((start+l+offset)-gxadj<=
static_cast<Metis::idx_t>(gxadjlen));
1111 if(verbose && oocomm.communicator().
rank()==0)
1116 gxadj, gadjncy,
true));
1119 if(verbose && oocomm.communicator().
rank()==0)
1122#if METIS_VER_MAJOR >= 5
1125 METIS_SetDefaultOptions(moptions);
1126 moptions[METIS_OPTION_NUMBERING] = numflag;
1127 METIS_PartGraphRecursive(&noVertices, &ncon, gxadj, gadjncy, gvwgt, NULL, gadjwgt,
1128 &nparts, NULL, NULL, moptions, &edgecut, gpart);
1130 int options[5] = {0, 1, 1, 3, 3};
1132 METIS_PartGraphRecursive(&noVertices, gxadj, gadjncy, gvwgt, gadjwgt, &wgtflag,
1133 &numflag, &nparts,
options, &edgecut, gpart);
1136 if(verbose && oocomm.communicator().
rank()==0)
1181 oocomm.copyOwnerToAll(realpart, realpart);
1183 if(verbose && oocomm.communicator().
rank()==0)
1188 oocomm.buildGlobalLookup(
mat.N());
1191 if(verbose && oocomm.communicator().
rank()==0)
1196 int noNeighbours=oocomm.remoteIndices().
neighbours();
1197 noNeighbours = oocomm.communicator().
sum(noNeighbours)
1198 / oocomm.communicator().
size();
1199 if(oocomm.communicator().
rank()==0)
1204 if(verbose && oocomm.communicator().
rank()==0)
1227 template<
class G,
class T1,
class T2>
1235 MPI_Comm comm=oocomm.communicator();
1236 oocomm.buildGlobalLookup(graph.noVertices());
1239 if(verbose && oocomm.communicator().
rank()==0)
1247 double t1=0.0, t2=0.0, t3=0.0, t4=0.0, tSum=0.0;
1252 int mype = oocomm.communicator().
rank();
1275 typedef typename OOComm::OwnerSet OwnerSet;
1280 ParmetisDuneIndexMap indexMap(graph,oocomm);
1282 for(
std::size_t i=0; i < indexMap.numOfOwnVtx(); ++i)
1286 if(oocomm.communicator().
rank()==0 && nparts>1)
1287 std::cerr<<
"ParMETIS not activated. Will repartition to 1 domain instead of requested "
1297 EdgeFunctor<G> ef(adjncy, indexMap, graph.noEdges());
1298 getAdjArrays<OwnerSet>(graph, oocomm.globalLookup(), xadj, ef);
1307 for(
int i=0; i<nparts; ++i)
1308 tpwgts[i]=1.0/nparts;
1317 wgtflag = (ef.getWeights()!=NULL) ? 1 : 0;
1326 std::cout<<
"Testing ParMETIS_V3_PartKway with options[1-2] = {"
1328 <<ncon<<
", Nparts: "<<nparts<<
std::endl;
1339 oocomm.communicator().
barrier();
1340 if(oocomm.communicator().
rank()==0)
1348 ParMETIS_V3_PartKway(indexMap.vtxDist(), xadj, adjncy,
1349 NULL, ef.getWeights(), &wgtflag,
1350 &numflag, &ncon, &nparts, tpwgts, ubvec,
options, &edgecut, part, &
const_cast<MPI_Comm&
>(comm));
1366 for(
int i=0; i < indexMap.vtxDist()[mype+1]-indexMap.vtxDist()[mype]; ++i) {
1370 std::cout<<
"Testing ParMETIS_V3_PartKway with options[1-2] = {"
1372 <<ncon<<
", Nparts: "<<nparts<<
std::endl;
1383 oocomm.communicator().
barrier();
1384 if(oocomm.communicator().
rank()==0)
1392 for(
std::size_t i=0; i<indexMap.numOfOwnVtx(); ++i)
1404 getDomain(comm, part, indexMap.numOfOwnVtx(), nparts, &myDomain, domainMapping);
1411 for(
auto j : range(nparts)) {
1412 std::cout<<
" do: "<<j<<
" pe: "<<domainMapping[j]<<
" ";
1425 if(OwnerSet::contains(
index->local().attribute())) {
1426 setPartition[
index->local()]=domainMapping[part[i++]];
1430 oocomm.copyOwnerToAll(setPartition, setPartition);
1433 if (SolverCategory::category(oocomm) ==
1434 static_cast<int>(SolverCategory::nonoverlapping))
1435 oocomm.copyCopyToAll(setPartition, setPartition);
1439 oocomm.communicator().
barrier();
1440 if(oocomm.communicator().
rank()==0)
1448 template<
class G,
class T1,
class T2>
1456 typedef typename OOComm::OwnerSet OwnerSet;
1487 int npes = oocomm.communicator().
size();
1496 int mype = oocomm.communicator().
rank();
1500 for(
auto i=setPartition.
begin(), iend = setPartition.
end(); i!=iend; ++i)
1503 noSendTo = tsendTo.
size();
1504 sendTo =
new int[noSendTo];
1506 for(
auto i=tsendTo.
begin(); i != tsendTo.
end(); ++i, ++idx)
1511 int* gnoSend=
new int[oocomm.communicator().
size()];
1512 int* gsendToDispl =
new int[oocomm.communicator().
size()+1];
1514 MPI_Allgather(&noSendTo, 1, MPI_INT, gnoSend, 1,
1515 MPI_INT, oocomm.communicator());
1518 int totalNoRecv = 0;
1519 for(
int i=0; i<npes; ++i)
1520 totalNoRecv += gnoSend[i];
1522 int *gsendTo =
new int[totalNoRecv];
1526 for(
int i=0; i<npes; ++i)
1527 gsendToDispl[i+1]=gsendToDispl[i]+gnoSend[i];
1530 MPI_Allgatherv(sendTo, noSendTo, MPI_INT, gsendTo, gnoSend, gsendToDispl,
1531 MPI_INT, oocomm.communicator());
1534 for(
int proc=0; proc < npes; ++proc)
1535 for(
int i=gsendToDispl[proc]; i < gsendToDispl[proc+1]; ++i)
1536 if(gsendTo[i]==mype)
1539 bool existentOnNextLevel = recvFrom.
size()>0;
1543 delete[] gsendToDispl;
1548 if(recvFrom.
size()) {
1550 for(
auto i=recvFrom.
begin(); i!= recvFrom.
end(); ++i) {
1557 for(
int i=0; i<noSendTo; i++) {
1564 if(oocomm.communicator().
rank()==0)
1565 std::cout<<
" Communicating the receive information took "<<
1580 typedef typename OOComm::ParallelIndexSet::GlobalIndex GI;
1584 GlobalVector sendOwnerVec;
1591 char **sendBuffers=
new char*[noSendTo];
1592 MPI_Request *requests =
new MPI_Request[noSendTo];
1595 for(
int i=0; i < noSendTo; ++i) {
1597 sendOwnerVec.
clear();
1598 sendOverlapSet.
clear();
1602 getOwnerOverlapVec<OwnerSet>(graph, setPartition, oocomm.globalLookup(),
1603 mype, sendTo[i], sendOwnerVec, sendOverlapSet, redistInf,
1615 buffersize += tsize;
1617 buffersize += tsize;
1618 MPI_Pack_size(neighbors.
size(), MPI_INT, oocomm.communicator(), &tsize);
1619 buffersize += tsize;
1621 sendBuffers[i] =
new char[buffersize];
1624 std::cout<<mype<<
" sending "<<sendOwnerVec.size()<<
" owner and "<<
1625 sendOverlapSet.
size()<<
" overlap to "<<sendTo[i]<<
" buffersize="<<buffersize<<
std::endl;
1627 createSendBuf(sendOwnerVec, sendOverlapSet, neighbors, sendBuffers[i], buffersize, oocomm.communicator());
1628 MPI_Issend(sendBuffers[i], buffersize, MPI_PACKED, sendTo[i], 99, oocomm.communicator(), requests+i);
1632 oocomm.communicator().
barrier();
1633 if(oocomm.communicator().
rank()==0)
1640 int noRecv = recvFrom.
size();
1641 int oldbuffersize=0;
1646 MPI_Probe(MPI_ANY_SOURCE, 99, oocomm.communicator(), &stat);
1648 MPI_Get_count(&stat, MPI_PACKED, &buffersize);
1650 if(oldbuffersize<buffersize) {
1653 recvBuf =
new char[buffersize];
1654 oldbuffersize = buffersize;
1656 MPI_Recv(recvBuf, buffersize, MPI_PACKED, stat.MPI_SOURCE, 99, oocomm.communicator(), &stat);
1657 saveRecvBuf(recvBuf, buffersize, myOwnerVec, myOverlapSet, myNeighbors, redistInf,
1658 stat.MPI_SOURCE, oocomm.communicator());
1667 MPI_Status *statuses =
new MPI_Status[noSendTo];
1668 int send = MPI_Waitall(noSendTo, requests, statuses);
1671 if(send==MPI_ERR_IN_STATUS) {
1674 for(
int i=0; i< noSendTo; i++)
1675 if(statuses[i].MPI_ERROR!=MPI_SUCCESS) {
1678 MPI_Error_string(statuses[i].MPI_ERROR,
message, &messageLength);
1679 std::cerr<<
" source="<<statuses[i].MPI_SOURCE<<
" message: ";
1680 for(
int j = 0; j < messageLength; j++)
1687 oocomm.communicator().
barrier();
1688 if(oocomm.communicator().
rank()==0)
1689 std::cout<<
" Receiving and saving took "<<
1694 for(
int i=0; i < noSendTo; ++i)
1695 delete[] sendBuffers[i];
1697 delete[] sendBuffers;
1712 if (!existentOnNextLevel) {
1714 color= MPI_UNDEFINED;
1716 MPI_Comm outputComm;
1718 MPI_Comm_split(oocomm.communicator(), color, oocomm.communicator().
rank(), &outputComm);
1719 outcomm = std::make_shared<OOComm>(outputComm,SolverCategory::category(oocomm),
true);
1722 int newrank=outcomm->communicator().rank();
1723 int *newranks=
new int[oocomm.communicator().
size()];
1727 typename OOComm::ParallelIndexSet& outputIndexSet = outcomm->indexSet();
1729 MPI_Allgather(&newrank, 1, MPI_INT, newranks, 1,
1730 MPI_INT, oocomm.communicator());
1734 for(
auto i=myNeighbors.
begin(),
end=myNeighbors.
end();
1736 assert(newranks[*i]>=0);
1742 for(
auto i=myNeighbors.
begin(),
end=myNeighbors.
end();
1748 myNeighbors.
clear();
1751 oocomm.communicator().
barrier();
1752 if(oocomm.communicator().
rank()==0)
1753 std::cout<<
" Calculating new neighbours ("<<tneighbors.
size()<<
") took "<<
1759 outputIndexSet.beginResize();
1767 using LocalIndexT =
typename OOComm::ParallelIndexSet::LocalIndex;
1768 for(
auto g=myOwnerVec.
begin(),
end =myOwnerVec.
end(); g!=
end; ++g, ++i ) {
1769 outputIndexSet.add(g->first,LocalIndexT(i, OwnerOverlapCopyAttributeSet::owner,
true));
1774 oocomm.communicator().
barrier();
1775 if(oocomm.communicator().
rank()==0)
1776 std::cout<<
" Adding owner indices took "<<
1786 mergeVec(myOwnerVec, myOverlapSet);
1790 myOwnerVec.
swap(myOwnerVec);
1793 oocomm.communicator().
barrier();
1794 if(oocomm.communicator().
rank()==0)
1802 for(
auto g=myOverlapSet.
begin(),
end=myOverlapSet.
end(); g!=
end; ++g, i++) {
1803 outputIndexSet.add(*g,LocalIndexT(i, OwnerOverlapCopyAttributeSet::copy,
true));
1805 myOverlapSet.
clear();
1806 outputIndexSet.endResize();
1808#ifdef DUNE_ISTL_WITH_CHECKING
1810 auto end = outputIndexSet.end();
1812 if (OwnerSet::contains(
index->local().attribute())) {
1816 numOfOwnVtx = oocomm.communicator().
sum(numOfOwnVtx);
1824 [](
const auto& v1,
const auto& v2){ return v1.global() < v2.global();});
1827 oocomm.communicator().
barrier();
1828 if(oocomm.communicator().
rank()==0)
1829 std::cout<<
" Adding overlap indices took "<<
1835 if(color != MPI_UNDEFINED) {
1836 outcomm->remoteIndices().setNeighbours(tneighbors);
1837 outcomm->remoteIndices().template rebuild<true>();
1845 oocomm.communicator().
barrier();
1846 if(oocomm.communicator().
rank()==0)
1854 tSum = t1 + t2 + t3 + t4;
1856 <<mype<<
": WTime for step 1): "<<t1
1864 return color!=MPI_UNDEFINED;
1868 template<
class G,
class P,
class T1,
class T2,
class R>
1869 bool graphRepartition(
const G& graph, P& oocomm,
int nparts,
1874 if(nparts!=oocomm.size())
1875 DUNE_THROW(NotImplemented,
"only available for MPI programs");
1879 template<
class G,
class P,
class T1,
class T2,
class R>
1885 if(nparts!=oocomm.size())
1886 DUNE_THROW(NotImplemented,
"only available for MPI programs");
Provides classes for building the matrix graph.
int globalOwnerVertices
Definition repartition.hh:175
Dune::ParameterTree options
Classes providing communication interfaces for overlapping Schwarz methods.
Matrix & mat
Definition matrixmatrix.hh:347
float real_t
Definition repartition.hh:53
std::size_t idx_t
Definition repartition.hh:63
reference operator[](size_type i)
static constexpr size_type M()
std::ptrdiff_t index() const
void message(const std::string &msg)
virtual void operator()()=0
void repairLocalIndexPointers(std::map< int, SLList< std::pair< typename T::GlobalIndex, typename T::LocalIndex::Attribute >, A > > &globalMap, RemoteIndices< T, A1 > &remoteIndices, const T &indexSet)
const_iterator end() const
const InformationMap & interfaces() const
MPI_Comm communicator() const
const IndexPair * pair(const std::size_t &local) const
void storeGlobalIndicesOfRemoteIndices(std::map< int, SLList< std::pair< typename T::GlobalIndex, typename T::LocalIndex::Attribute >, A > > &globalMap, const RemoteIndices< T, A1 > &remoteIndices)
const_iterator begin() const
bool buildCommunication(const G &graph, std::vector< int > &realparts, Dune::OwnerOverlapCopyCommunication< T1, T2 > &oocomm, std::shared_ptr< Dune::OwnerOverlapCopyCommunication< T1, T2 > > &outcomm, RedistributeInterface &redistInf, bool verbose=false)
Definition repartition.hh:1449
void fillIndexSetHoles(const G &graph, Dune::OwnerOverlapCopyCommunication< T1, T2 > &oocomm)
Fills the holes in an index set.
Definition repartition.hh:83
bool commGraphRepartition(const M &mat, Dune::OwnerOverlapCopyCommunication< T1, T2 > &oocomm, Metis::idx_t nparts, std::shared_ptr< Dune::OwnerOverlapCopyCommunication< T1, T2 > > &outcomm, RedistributeInterface &redistInf, bool verbose=false)
Definition repartition.hh:822
void print_carray(S &os, T *array, std::size_t l)
Definition repartition.hh:771
bool isValidGraph(std::size_t noVtx, std::size_t gnoVtx, S noEdges, T *xadj, T *adjncy, bool checkSymmetry)
Definition repartition.hh:778
bool graphRepartition(const G &graph, Dune::OwnerOverlapCopyCommunication< T1, T2 > &oocomm, Metis::idx_t nparts, std::shared_ptr< Dune::OwnerOverlapCopyCommunication< T1, T2 > > &outcomm, RedistributeInterface &redistInf, bool verbose=false)
execute a graph repartition for a giving graph and indexset.
Definition repartition.hh:1228
double elapsed() const noexcept
@ owner
Definition owneroverlapcopy.hh:61
The (undirected) graph of a matrix.
Definition graph.hh:51
Definition repartition.hh:260
void reserveSpaceForReceiveInterface(int proc, int size)
Definition repartition.hh:284
void buildReceiveInterface(std::vector< std::pair< TG, int > > &indices)
Definition repartition.hh:293
void setCommunicator(MPI_Comm comm)
Definition repartition.hh:261
void buildSendInterface(const std::vector< int > &toPart, const IS &idxset)
Definition repartition.hh:266
void addReceiveIndex(int proc, std::size_t idx)
Definition repartition.hh:288