opm-simulators/opm/simulators/linalg/domesticoverlapfrombcrsmatrix.hh
2019-09-16 09:48:55 +02:00

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19 KiB
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// -*- mode: C++; tab-width: 4; indent-tabs-mode: nil; c-basic-offset: 4 -*-
// vi: set et ts=4 sw=4 sts=4:
/*
This file is part of the Open Porous Media project (OPM).
OPM is free software: you can redistribute it and/or modify
it under the terms of the GNU General Public License as published by
the Free Software Foundation, either version 2 of the License, or
(at your option) any later version.
OPM is distributed in the hope that it will be useful,
but WITHOUT ANY WARRANTY; without even the implied warranty of
MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
GNU General Public License for more details.
You should have received a copy of the GNU General Public License
along with OPM. If not, see <http://www.gnu.org/licenses/>.
Consult the COPYING file in the top-level source directory of this
module for the precise wording of the license and the list of
copyright holders.
*/
/*!
* \file
* \copydoc Opm::Linear::DomesticOverlapFromBCRSMatrix
*/
#ifndef EWOMS_DOMESTIC_OVERLAP_FROM_BCRS_MATRIX_HH
#define EWOMS_DOMESTIC_OVERLAP_FROM_BCRS_MATRIX_HH
#include "foreignoverlapfrombcrsmatrix.hh"
#include "blacklist.hh"
#include "globalindices.hh"
#include <opm/models/parallel/mpibuffer.hh>
#include <algorithm>
#include <limits>
#include <set>
#include <map>
#include <vector>
namespace Opm {
namespace Linear {
/*!
* \brief This class creates and manages the foreign overlap given an
* initial list of border indices and a BCRS matrix.
*
* The foreign overlap are all (row) indices which overlap with the
* some of the current process's local indices.
*/
class DomesticOverlapFromBCRSMatrix
{
typedef Opm::Linear::ForeignOverlapFromBCRSMatrix ForeignOverlap;
typedef Opm::Linear::GlobalIndices<ForeignOverlap> GlobalIndices;
public:
// overlaps should never be copied!
DomesticOverlapFromBCRSMatrix(const DomesticOverlapFromBCRSMatrix&) = delete;
/*!
* \brief Constructs the foreign overlap given a BCRS matrix and
* an initial list of border indices.
*/
template <class BCRSMatrix>
DomesticOverlapFromBCRSMatrix(const BCRSMatrix& A,
const BorderList& borderList,
const BlackList& blackList,
unsigned overlapSize)
: foreignOverlap_(A, borderList, blackList, overlapSize)
, blackList_(blackList)
, globalIndices_(foreignOverlap_)
{
myRank_ = 0;
worldSize_ = 1;
#if HAVE_MPI
int tmp;
MPI_Comm_rank(MPI_COMM_WORLD, &tmp);
myRank_ = static_cast<ProcessRank>(tmp);
MPI_Comm_size(MPI_COMM_WORLD, &tmp);
worldSize_ = static_cast<unsigned>(tmp);
#endif // HAVE_MPI
buildDomesticOverlap_();
updateMasterRanks_();
blackList_.updateNativeToDomesticMap(*this);
setupDebugMapping_();
}
void check() const
{
#ifndef NDEBUG
// check consistency of global indices
for (unsigned domIdx = 0; domIdx < numDomestic(); ++domIdx) {
assert(globalToDomestic(domesticToGlobal(domIdx)) == static_cast<Index>(domIdx));
}
#endif // NDEBUG
// send the foreign overlap for which we are master to the
// peers
std::map<int, MpiBuffer<unsigned> *> sizeBufferMap;
auto peerIt = peerSet_.begin();
const auto& peerEndIt = peerSet_.end();
for (; peerIt != peerEndIt; ++peerIt) {
auto& buffer = *(new MpiBuffer<unsigned>(1));
sizeBufferMap[*peerIt] = &buffer;
buffer[0] = foreignOverlap_.foreignOverlapWithPeer(*peerIt).size();
buffer.send(*peerIt);
}
peerIt = peerSet_.begin();
for (; peerIt != peerEndIt; ++peerIt) {
MpiBuffer<unsigned> rcvBuffer(1);
rcvBuffer.receive(*peerIt);
assert(rcvBuffer[0] == domesticOverlapWithPeer_.find(*peerIt)->second.size());
}
peerIt = peerSet_.begin();
for (; peerIt != peerEndIt; ++peerIt) {
sizeBufferMap[*peerIt]->wait();
delete sizeBufferMap[*peerIt];
}
}
/*!
* \brief Returns the rank of the current process.
*/
ProcessRank myRank() const
{ return myRank_; }
/*!
* \brief Returns the number of processes in the global MPI communicator.
*/
unsigned worldSize() const
{ return worldSize_; }
/*!
* \brief Return the set of process ranks which share an overlap
* with the current process.
*/
const PeerSet& peerSet() const
{ return peerSet_; }
/*!
* \brief Returns true iff a domestic index is a border index.
*/
bool isBorder(Index domesticIdx) const
{
return isLocal(domesticIdx)
&& foreignOverlap_.isBorder(mapExternalToInternal_(domesticIdx));
}
/*!
* \brief Returns true iff a domestic index is on the border with
* a given peer process.
*/
bool isBorderWith(Index domesticIdx, ProcessRank peerRank) const
{
return isLocal(domesticIdx)
&& foreignOverlap_.isBorderWith(mapExternalToInternal_(domesticIdx),
peerRank);
}
/*!
* \brief Returns the number of indices on the front within a given
* peer rank's grid partition.
*/
size_t numFront(ProcessRank peerRank) const
{ return foreignOverlap_.numFront(peerRank); }
/*!
* \brief Returns true iff a domestic index is on the front.
*/
bool isFront(Index domesticIdx) const
{
if (isLocal(domesticIdx))
return false;
Index internalDomesticIdx = mapExternalToInternal_(domesticIdx);
// check wether the border distance of the domestic overlap is
// maximal for the index
const auto& domOverlap = domesticOverlapByIndex_[internalDomesticIdx];
return domOverlap.size() > 0
&& domOverlap.begin()->second == foreignOverlap_.overlapSize();
}
/*!
* \brief Returns the object which represents the black-listed native indices.
*/
const BlackList& blackList() const
{ return blackList_; }
/*!
* \brief Returns the number of processes which "see" a given
* index.
*/
size_t numPeers(Index domesticIdx) const
{ return domesticOverlapByIndex_[mapExternalToInternal_(domesticIdx)].size(); }
/*!
* \brief Returns the size of the overlap region
*/
unsigned overlapSize() const
{ return foreignOverlap_.overlapSize(); }
/*!
* \brief Returns the number native indices
*
* I.e. the number of indices of the "raw" grid partition of the
* local process (including the indices in ghost and overlap
* elements).
*/
size_t numNative() const
{ return foreignOverlap_.numNative(); }
/*!
* \brief Returns the number local indices
*
* I.e. indices in the interior or on the border of the process'
* domain.
*/
size_t numLocal() const
{ return foreignOverlap_.numLocal(); }
/*!
* \brief Returns the number domestic indices.
*
* The domestic indices are defined as the process' local indices
* plus its domestic overlap (i.e. indices for which it is not
* neither master nor are on the process border).
*/
size_t numDomestic() const
{ return globalIndices_.numDomestic(); }
/*!
* \brief Return true if a domestic index is local for the process
*
* I.e. the entity for this index is in the interior or on the
* border of the process' domain.
*/
bool isLocal(Index domesticIdx) const
{ return mapExternalToInternal_(domesticIdx) < static_cast<Index>(numLocal()); }
/*!
* \brief Return true iff the current process is the master of a
* given domestic index.
*/
bool iAmMasterOf(Index domesticIdx) const
{
if (!isLocal(domesticIdx))
return false;
return foreignOverlap_.iAmMasterOf(mapExternalToInternal_(domesticIdx));
}
/*!
* \brief Return the rank of a master process for a domestic index
*/
ProcessRank masterRank(Index domesticIdx) const
{ return masterRank_[static_cast<unsigned>(mapExternalToInternal_(domesticIdx))]; }
/*!
* \brief Print the foreign overlap for debugging purposes.
*/
void print() const
{ globalIndices_.print(); }
/*!
* \brief Returns a domestic index given a global one
*/
Index globalToDomestic(Index globalIdx) const
{
Index internalIdx = globalIndices_.globalToDomestic(globalIdx);
if (internalIdx < 0)
return -1;
return mapInternalToExternal_(internalIdx);
}
/*!
* \brief Returns a global index given a domestic one
*/
Index domesticToGlobal(Index domIdx) const
{ return globalIndices_.domesticToGlobal(mapExternalToInternal_(domIdx)); }
/*!
* \brief Returns a native index given a domestic one
*/
Index domesticToNative(Index domIdx) const
{
Index internalIdx = mapExternalToInternal_(domIdx);
if (internalIdx >= static_cast<Index>(numLocal()))
return -1;
return foreignOverlap_.localToNative(internalIdx);
}
/*!
* \brief Returns a domestic index given a native one
*/
Index nativeToDomestic(Index nativeIdx) const
{
Index localIdx = foreignOverlap_.nativeToLocal(nativeIdx);
if (localIdx < 0)
return localIdx;
return mapInternalToExternal_(localIdx);
}
/*!
* \brief Returns true if a given domestic index is either in the
* foreign or in the domestic overlap.
*/
bool isInOverlap(Index domesticIdx) const
{
return !this->isLocal(domesticIdx)
|| this->foreignOverlap_.isInOverlap(mapExternalToInternal_(domesticIdx));
}
/*!
* \brief Returns true if a given domestic index is a front index
* for a peer rank.
*/
bool isFrontFor(ProcessRank peerRank, Index domesticIdx) const
{
Index internalIdx = mapExternalToInternal_(domesticIdx);
return this->foreignOverlap_.isFrontFor(peerRank, internalIdx);
}
/*!
* \brief Returns true iff a domestic index is seen by a peer rank.
*/
bool peerHasIndex(int peerRank, Index domesticIdx) const
{
return foreignOverlap_.peerHasIndex(peerRank,
mapExternalToInternal_(domesticIdx));
}
/*!
* \brief Returns number of indices which are contained in the
* foreign overlap with a peer.
*/
size_t foreignOverlapSize(ProcessRank peerRank) const
{ return foreignOverlap_.foreignOverlapWithPeer(peerRank).size(); }
/*!
* \brief Returns the domestic index given an offset in the
* foreign overlap of a peer process with the local
* process.
*/
Index foreignOverlapOffsetToDomesticIdx(ProcessRank peerRank, unsigned overlapOffset) const
{
Index internalIdx =
foreignOverlap_.foreignOverlapWithPeer(peerRank)[overlapOffset].index;
return mapInternalToExternal_(internalIdx);
}
/*!
* \brief Returns number of indices which are contained in the
* domestic overlap with a peer.
*/
size_t domesticOverlapSize(ProcessRank peerRank) const
{ return domesticOverlapWithPeer_.at(peerRank).size(); }
/*!
* \brief Returns the domestic index given an offset in the
* domestic overlap of a peer process with the local
* process.
*/
Index domesticOverlapOffsetToDomesticIdx(ProcessRank peerRank, Index overlapOffset) const
{
Index internalIdx = domesticOverlapWithPeer_.at(peerRank)[overlapOffset];
return mapInternalToExternal_(internalIdx);
}
protected:
void buildDomesticOverlap_()
{
// copy the set of peers from the foreign overlap
peerSet_ = foreignOverlap_.peerSet();
// resize the array which stores the number of peers for
// each entry.
domesticOverlapByIndex_.resize(numLocal());
borderDistance_.resize(numLocal(), 0);
PeerSet::const_iterator peerIt;
PeerSet::const_iterator peerEndIt = peerSet_.end();
// send the overlap indices to all peer processes
peerIt = peerSet_.begin();
for (; peerIt != peerEndIt; ++peerIt) {
ProcessRank peerRank = *peerIt;
sendIndicesToPeer_(peerRank);
}
// receive our overlap from the processes to all peer processes
peerIt = peerSet_.begin();
for (; peerIt != peerEndIt; ++peerIt) {
ProcessRank peerRank = *peerIt;
receiveIndicesFromPeer_(peerRank);
}
// wait until all send operations complete
peerIt = peerSet_.begin();
for (; peerIt != peerEndIt; ++peerIt) {
ProcessRank peerRank = *peerIt;
waitSendIndices_(peerRank);
}
}
void updateMasterRanks_()
{
size_t nLocal = numLocal();
size_t nDomestic = numDomestic();
masterRank_.resize(nDomestic);
// take the master ranks for the local indices from the
// foreign overlap
for (unsigned i = 0; i < nLocal; ++i) {
masterRank_[i] = foreignOverlap_.masterRank(static_cast<Index>(i));
}
// for non-local indices, initially use INT_MAX as their master
// rank
for (size_t i = nLocal; i < nDomestic; ++i)
masterRank_[i] = std::numeric_limits<ProcessRank>::max();
// for the non-local indices, take the peer process for which
// a given local index is in the interior
auto peerIt = peerSet_.begin();
const auto& peerEndIt = peerSet_.end();
for (; peerIt != peerEndIt; ++peerIt) {
const auto& overlapWithPeer = domesticOverlapWithPeer_.find(*peerIt)->second;
auto idxIt = overlapWithPeer.begin();
const auto& idxEndIt = overlapWithPeer.end();
for (; idxIt != idxEndIt; ++idxIt) {
if (*idxIt >= 0 && foreignOverlap_.isLocal(*idxIt))
continue; // ignore border indices
masterRank_[static_cast<unsigned>(*idxIt)] = std::min(masterRank_[static_cast<unsigned>(*idxIt)], *peerIt);
}
}
}
void sendIndicesToPeer_(ProcessRank peerRank OPM_UNUSED_NOMPI)
{
#if HAVE_MPI
const auto& foreignOverlap = foreignOverlap_.foreignOverlapWithPeer(peerRank);
// first, send a message containing the number of additional
// indices stemming from the overlap (i.e. without the border
// indices)
size_t numIndices = foreignOverlap.size();
numIndicesSendBuffer_[peerRank] = new MpiBuffer<size_t>(1);
(*numIndicesSendBuffer_[peerRank])[0] = numIndices;
numIndicesSendBuffer_[peerRank]->send(peerRank);
// create MPI buffers
indicesSendBuffer_[peerRank] = new MpiBuffer<IndexDistanceNpeers>(numIndices);
// then send the additional indices themselfs
auto overlapIt = foreignOverlap.begin();
const auto& overlapEndIt = foreignOverlap.end();
for (unsigned i = 0; overlapIt != overlapEndIt; ++overlapIt, ++i) {
Index localIdx = overlapIt->index;
BorderDistance borderDistance = overlapIt->borderDistance;
size_t numPeers = foreignOverlap_.foreignOverlapByLocalIndex(localIdx).size();
IndexDistanceNpeers tmp;
tmp.index = globalIndices_.domesticToGlobal(localIdx);
tmp.borderDistance = borderDistance;
tmp.numPeers = static_cast<unsigned>(numPeers);
(*indicesSendBuffer_[peerRank])[i] = tmp;
}
indicesSendBuffer_[peerRank]->send(peerRank);
#endif // HAVE_MPI
}
void waitSendIndices_(ProcessRank peerRank)
{
numIndicesSendBuffer_[peerRank]->wait();
delete numIndicesSendBuffer_[peerRank];
indicesSendBuffer_[peerRank]->wait();
delete indicesSendBuffer_[peerRank];
}
void receiveIndicesFromPeer_(ProcessRank peerRank OPM_UNUSED_NOMPI)
{
#if HAVE_MPI
// receive the number of additional indices
int numIndices = -1;
MpiBuffer<size_t> numIndicesRecvBuff(1);
numIndicesRecvBuff.receive(peerRank);
numIndices = static_cast<int>(numIndicesRecvBuff[0]);
// receive the additional indices themselfs
MpiBuffer<IndexDistanceNpeers> recvBuff(static_cast<size_t>(numIndices));
recvBuff.receive(peerRank);
for (unsigned i = 0; i < static_cast<unsigned>(numIndices); ++i) {
Index globalIdx = recvBuff[i].index;
BorderDistance borderDistance = recvBuff[i].borderDistance;
// if the index is not already known, add it to the
// domestic indices
if (!globalIndices_.hasGlobalIndex(globalIdx)) {
Index newDomesticIdx = static_cast<Index>(globalIndices_.numDomestic());
globalIndices_.addIndex(newDomesticIdx, globalIdx);
size_t newSize = globalIndices_.numDomestic();
borderDistance_.resize(newSize, std::numeric_limits<int>::max());
domesticOverlapByIndex_.resize(newSize);
}
// convert the global index into a domestic one
Index domesticIdx = globalIndices_.globalToDomestic(globalIdx);
// extend the domestic overlap
domesticOverlapByIndex_[static_cast<unsigned>(domesticIdx)][static_cast<unsigned>(peerRank)] = borderDistance;
domesticOverlapWithPeer_[static_cast<unsigned>(peerRank)].push_back(domesticIdx);
//assert(borderDistance >= 0);
assert(globalIdx >= 0);
assert(domesticIdx >= 0);
assert(!(borderDistance == 0 && !foreignOverlap_.isLocal(domesticIdx)));
assert(!(borderDistance > 0 && foreignOverlap_.isLocal(domesticIdx)));
borderDistance_[static_cast<unsigned>(domesticIdx)] = std::min(borderDistance, borderDistance_[static_cast<unsigned>(domesticIdx)]);
}
#endif // HAVE_MPI
}
// this method is intended to set up the code mapping code for
// mapping domestic indices to the same ones used by a sequential
// grid. this requires detailed knowledge about how a grid
// distributes the degrees of freedom over multiple processes, but
// it can simplify debugging considerably because the indices can
// be made identical for the parallel and the sequential
// computations.
//
// by default, this method does nothing
void setupDebugMapping_()
{}
// this method is intended to map domestic indices to the ones
// used by a sequential grid.
//
// by default, this method does nothing
Index mapInternalToExternal_(Index internalIdx) const
{ return internalIdx; }
// this method is intended to map the indices used by a sequential
// to grid domestic indices ones.
//
// by default, this method does nothing
Index mapExternalToInternal_(Index externalIdx) const
{ return externalIdx; }
ProcessRank myRank_;
unsigned worldSize_;
ForeignOverlap foreignOverlap_;
BlackList blackList_;
DomesticOverlapByRank domesticOverlapWithPeer_;
OverlapByIndex domesticOverlapByIndex_;
std::vector<BorderDistance> borderDistance_;
std::vector<ProcessRank> masterRank_;
std::map<ProcessRank, MpiBuffer<size_t> *> numIndicesSendBuffer_;
std::map<ProcessRank, MpiBuffer<IndexDistanceNpeers> *> indicesSendBuffer_;
GlobalIndices globalIndices_;
PeerSet peerSet_;
};
} // namespace Linear
} // namespace Opm
#endif