opm-simulators/opm/autodiff/ParallelDebugOutput.hpp
Tor Harald Sandve dc8f811cbe Remove WellStateFullyImplicitBlackoilDense
After the restructuring of of the well model, keeping an extra class for
the "Dense" model is not needed. The only thing still left in
WellStateFullyImplicitBlackoilDense was some solvent related stuff, this
PR moves this to WellStateFullyImplicitBlackoil and removes
WellStateFullyImplicitBlackoilDense.

In addition to a cleaning code this PR fixes missing solvent well output.
2017-10-11 10:54:59 +02:00

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/*
Copyright 2015 IRIS AS
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 3 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/>.
*/
#ifndef OPM_PARALLELDEBUGOUTPUT_HEADER_INCLUDED
#define OPM_PARALLELDEBUGOUTPUT_HEADER_INCLUDED
#include <unordered_set>
#include <opm/common/data/SimulationDataContainer.hpp>
#include <opm/core/grid.h>
#include <opm/core/simulator/WellState.hpp>
#include <opm/core/wells/WellsManager.hpp>
#include <opm/autodiff/WellStateFullyImplicitBlackoil.hpp>
#include <opm/autodiff/WellStateFullyImplicitBlackoil.hpp>
#include <opm/core/wells/DynamicListEconLimited.hpp>
#if HAVE_OPM_GRID
#include <dune/grid/common/p2pcommunicator.hh>
#endif
namespace Opm
{
class ParallelDebugOutputInterface
{
protected:
ParallelDebugOutputInterface () {}
public:
virtual ~ParallelDebugOutputInterface() {}
//! \brief gather solution to rank 0 for EclipseWriter
//! \param localReservoirState The reservoir state
//! \param localWellState The well state
//! \param localCellData The cell data used for eclipse output
//! (needs to include the cell data of
//! localReservoirState)
//! \param wellStateStepNumber The step number of the well state.
virtual bool collectToIORank( const SimulationDataContainer& localReservoirState,
const WellStateFullyImplicitBlackoil& localWellState,
const data::Solution& localCellData,
const int wellStateStepNumber ) = 0;
virtual const SimulationDataContainer& globalReservoirState() const = 0 ;
virtual const data::Solution& globalCellData() const = 0 ;
virtual const WellStateFullyImplicitBlackoil& globalWellState() const = 0 ;
virtual bool isIORank() const = 0;
virtual bool isParallel() const = 0;
virtual int numCells() const = 0 ;
virtual const int* globalCell() const = 0;
};
template <class GridImpl>
class ParallelDebugOutput : public ParallelDebugOutputInterface
{
protected:
const GridImpl& grid_;
const SimulationDataContainer* globalState_;
const WellStateFullyImplicitBlackoil* wellState_;
const data::Solution* globalCellData_;
public:
ParallelDebugOutput ( const GridImpl& grid,
const EclipseState& /* eclipseState */,
const int,
const Opm::PhaseUsage& )
: grid_( grid ) {}
// gather solution to rank 0 for EclipseWriter
virtual bool collectToIORank( const SimulationDataContainer& localReservoirState,
const WellStateFullyImplicitBlackoil& localWellState,
const data::Solution& localCellData,
const int /* wellStateStepNumber */)
{
globalState_ = &localReservoirState;
wellState_ = &localWellState;
globalCellData_ = &localCellData;
return true ;
}
virtual const SimulationDataContainer& globalReservoirState() const { return *globalState_; }
virtual const data::Solution& globalCellData() const
{
return *globalCellData_;
}
virtual const WellStateFullyImplicitBlackoil& globalWellState() const { return *wellState_; }
virtual bool isIORank () const { return true; }
virtual bool isParallel () const { return false; }
virtual int numCells() const { return Opm::AutoDiffGrid::numCells(grid_); }
virtual const int* globalCell() const { return Opm::AutoDiffGrid::globalCell(grid_); }
};
#if HAVE_OPM_GRID
template <>
class ParallelDebugOutput< Dune::CpGrid> : public ParallelDebugOutputInterface
{
public:
typedef Dune::CpGrid Grid;
typedef typename Grid :: CollectiveCommunication CollectiveCommunication;
// global id
class GlobalCellIndex
{
int globalId_;
int localIndex_;
bool isInterior_;
public:
GlobalCellIndex() : globalId_(-1), localIndex_(-1), isInterior_(true) {}
void setGhost() { isInterior_ = false; }
void setId( const int globalId ) { globalId_ = globalId; }
void setIndex( const int localIndex ) { localIndex_ = localIndex; }
int localIndex () const { return localIndex_; }
int id () const { return globalId_; }
bool isInterior() const { return isInterior_; }
};
typedef typename Dune::PersistentContainer< Grid, GlobalCellIndex > GlobalIndexContainer;
static const int dimension = Grid :: dimension ;
typedef typename Grid :: LeafGridView GridView;
typedef GridView AllGridView;
typedef Dune :: Point2PointCommunicator< Dune :: SimpleMessageBuffer > P2PCommunicatorType;
typedef typename P2PCommunicatorType :: MessageBufferType MessageBufferType;
typedef std::vector< GlobalCellIndex > LocalIndexMapType;
typedef std::vector<int> IndexMapType;
typedef std::vector< IndexMapType > IndexMapStorageType;
class DistributeIndexMapping : public P2PCommunicatorType::DataHandleInterface
{
protected:
const std::vector<int>& distributedGlobalIndex_;
IndexMapType& localIndexMap_;
IndexMapStorageType& indexMaps_;
std::map< const int, const int > globalPosition_;
#ifndef NDEBUG
std::set< int > checkPosition_;
#endif
public:
DistributeIndexMapping( const std::vector<int>& globalIndex,
const std::vector<int>& distributedGlobalIndex,
IndexMapType& localIndexMap,
IndexMapStorageType& indexMaps )
: distributedGlobalIndex_( distributedGlobalIndex ),
localIndexMap_( localIndexMap ),
indexMaps_( indexMaps ),
globalPosition_()
{
const size_t size = globalIndex.size();
// create mapping globalIndex --> localIndex
for ( size_t index = 0; index < size; ++index )
{
globalPosition_.insert( std::make_pair( globalIndex[ index ], index ) );
}
// on I/O rank we need to create a mapping from local to global
if( ! indexMaps_.empty() )
{
// for the ioRank create a localIndex to index in global state map
IndexMapType& indexMap = indexMaps_.back();
const size_t localSize = localIndexMap_.size();
indexMap.resize( localSize );
for( size_t i=0; i<localSize; ++i )
{
const int id = distributedGlobalIndex_[ localIndexMap_[ i ] ];
indexMap[ i ] = globalPosition_[ id ] ;
#ifndef NDEBUG
assert( checkPosition_.find( id ) == checkPosition_.end() );
checkPosition_.insert( id );
#endif
}
}
}
void pack( const int link, MessageBufferType& buffer )
{
// we should only get one link
if( link != 0 ) {
OPM_THROW(std::logic_error,"link in method pack is not 0 as execpted");
}
// pack all interior global cell id's
const int size = localIndexMap_.size();
buffer.write( size );
for( int index = 0; index < size; ++index )
{
const int globalIdx = distributedGlobalIndex_[ localIndexMap_[ index ] ];
buffer.write( globalIdx );
}
}
void unpack( const int link, MessageBufferType& buffer )
{
// get index map for current link
IndexMapType& indexMap = indexMaps_[ link ];
assert( ! globalPosition_.empty() );
// unpack all interior global cell id's
int numCells = 0;
buffer.read( numCells );
indexMap.resize( numCells );
for( int index = 0; index < numCells; ++index )
{
int globalId = -1;
buffer.read( globalId );
assert( globalPosition_.find( globalId ) != globalPosition_.end() );
indexMap[ index ] = globalPosition_[ globalId ];
#ifndef NDEBUG
assert( checkPosition_.find( globalId ) == checkPosition_.end() );
checkPosition_.insert( globalId );
#endif
}
}
};
enum { ioRank = 0 };
/// \brief Constructor
/// \param otherGrid The grid after loadbalance was run.
/// \param eclipseState The eclipse file parser output
/// \param numPhases The number of active phases.
/// \param permeability The permeabilities for the global(!) view.
ParallelDebugOutput( const Dune::CpGrid& otherGrid,
const EclipseState& eclipseState,
const int numPhases,
const Opm::PhaseUsage& phaseUsage)
: grid_(),
eclipseState_( eclipseState ),
globalCellData_(new data::Solution),
isIORank_(true),
phaseUsage_(phaseUsage)
{
// Switch to distributed view unconditionally for safety.
Dune::CpGrid distributed_grid = otherGrid;
const CollectiveCommunication& comm = otherGrid.comm();
if( comm.size() > 1 )
{
std::set< int > send, recv;
distributed_grid.switchToDistributedView();
toIORankComm_ = distributed_grid.comm();
isIORank_ = (distributed_grid.comm().rank() == ioRank);
// the I/O rank receives from all other ranks
if( isIORank() )
{
// copy grid
grid_.reset( new Dune::CpGrid(otherGrid ) );
grid_->switchToGlobalView();
Dune::CpGrid& globalGrid = *grid_;
// initialize global state with correct sizes
globalReservoirState_.reset( new SimulationDataContainer( globalGrid.numCells(), globalGrid.numFaces(), numPhases ));
// copy global cartesian index
globalIndex_ = globalGrid.globalCell();
unsigned int count = 0;
auto gridView = globalGrid.leafGridView();
for( auto it = gridView.begin< 0 >(),
end = gridView.end< 0 >(); it != end; ++it, ++count )
{
}
assert( count == globalIndex_.size() );
for(int i=0; i<comm.size(); ++i)
{
if( i != ioRank )
{
recv.insert( i );
}
}
}
else // all other simply send to the I/O rank
{
// globalReservoirState will be deferenced even if this rank is not outputting anything
// To prevent dereferencing a nullptr we create an empty container
globalReservoirState_.reset( new SimulationDataContainer( 0, 0, 0));
send.insert( ioRank );
}
localIndexMap_.clear();
localIndexMap_.reserve( distributed_grid.size( 0 ) );
unsigned int index = 0;
auto localView = distributed_grid.leafGridView();
for( auto it = localView.begin< 0 >(),
end = localView.end< 0 >(); it != end; ++it, ++index )
{
const auto element = *it ;
// only store interior element for collection
if( element.partitionType() == Dune :: InteriorEntity )
{
localIndexMap_.push_back( index );
}
}
// insert send and recv linkage to communicator
toIORankComm_.insertRequest( send, recv );
if( isIORank() )
{
// need an index map for each rank
indexMaps_.clear();
indexMaps_.resize( comm.size() );
}
// distribute global id's to io rank for later association of dof's
DistributeIndexMapping distIndexMapping( globalIndex_, distributed_grid.globalCell(), localIndexMap_, indexMaps_ );
toIORankComm_.exchange( distIndexMapping );
}
else // serial run
{
// copy global cartesian index
globalIndex_ = distributed_grid.globalCell();
}
}
class PackUnPackSimulationDataContainer : public P2PCommunicatorType::DataHandleInterface
{
const data::Solution& localCellData_;
data::Solution& globalCellData_;
const WellStateFullyImplicitBlackoil& localWellState_;
WellStateFullyImplicitBlackoil& globalWellState_;
const IndexMapType& localIndexMap_;
const IndexMapStorageType& indexMaps_;
public:
PackUnPackSimulationDataContainer( std::size_t numGlobalCells,
const data::Solution& localCellData,
data::Solution& globalCellData,
const WellStateFullyImplicitBlackoil& localWellState,
WellStateFullyImplicitBlackoil& globalWellState,
const IndexMapType& localIndexMap,
const IndexMapStorageType& indexMaps,
const bool isIORank )
: localCellData_( localCellData ),
globalCellData_( globalCellData ),
localWellState_( localWellState ),
globalWellState_( globalWellState ),
localIndexMap_( localIndexMap ),
indexMaps_( indexMaps )
{
if( isIORank )
{
// add missing data to global cell data
for (const auto& pair : localCellData_) {
const std::string& key = pair.first;
std::size_t container_size = numGlobalCells;
auto ret = globalCellData_.insert(key, pair.second.dim,
std::vector<double>(container_size),
pair.second.target);
assert(ret.second);
DUNE_UNUSED_PARAMETER(ret.second); //dummy op to prevent warning with -DNDEBUG
}
MessageBufferType buffer;
pack( 0, buffer );
// the last index map is the local one
doUnpack( indexMaps.back(), buffer );
}
}
// pack all data associated with link
void pack( const int link, MessageBufferType& buffer )
{
// we should only get one link
if( link != 0 ) {
OPM_THROW(std::logic_error,"link in method pack is not 0 as execpted");
}
// write all cell data registered in local state
for (const auto& pair : localCellData_) {
const auto& data = pair.second.data;
// write all data from local data to buffer
write( buffer, localIndexMap_, data);
}
// write all data from local well state to buffer
writeWells( buffer );
}
void doUnpack( const IndexMapType& indexMap, MessageBufferType& buffer )
{
// we loop over the data as
// its order governs the order the data got received.
for (auto& pair : localCellData_) {
const std::string& key = pair.first;
auto& data = globalCellData_.data(key);
//write all data from local cell data to buffer
read( buffer, indexMap, data);
}
// read well data from buffer
readWells( buffer );
}
// unpack all data associated with link
void unpack( const int link, MessageBufferType& buffer )
{
doUnpack( indexMaps_[ link ], buffer );
}
protected:
template <class Vector>
void write( MessageBufferType& buffer, const IndexMapType& localIndexMap,
const Vector& vector,
const unsigned int offset = 0, const unsigned int stride = 1 ) const
{
unsigned int size = localIndexMap.size();
buffer.write( size );
assert( vector.size() >= stride * size );
for( unsigned int i=0; i<size; ++i )
{
const unsigned int index = localIndexMap[ i ] * stride + offset;
assert( index < vector.size() );
buffer.write( vector[ index ] );
}
}
template <class Vector>
void read( MessageBufferType& buffer,
const IndexMapType& indexMap,
Vector& vector,
const unsigned int offset = 0, const unsigned int stride = 1 ) const
{
unsigned int size = 0;
buffer.read( size );
assert( size == indexMap.size() );
for( unsigned int i=0; i<size; ++i )
{
const unsigned int index = indexMap[ i ] * stride + offset;
assert( index < vector.size() );
buffer.read( vector[ index ] );
}
}
void writeString( MessageBufferType& buffer, const std::string& s) const
{
const int size = s.size();
buffer.write( size );
for( int i=0; i<size; ++i )
{
buffer.write( s[ i ] );
}
}
void readString( MessageBufferType& buffer, std::string& s) const
{
int size = -1;
buffer.read( size );
s.resize( size );
for( int i=0; i<size; ++i )
{
buffer.read( s[ i ] );
}
}
void writeWells( MessageBufferType& buffer ) const
{
int nWells = localWellState_.wellMap().size();
buffer.write( nWells );
auto end = localWellState_.wellMap().end();
for( auto it = localWellState_.wellMap().begin(); it != end; ++it )
{
const std::string& name = it->first;
const int wellIdx = it->second[ 0 ];
// write well name
writeString( buffer, name );
// write well data
buffer.write( localWellState_.bhp()[ wellIdx ] );
buffer.write( localWellState_.thp()[ wellIdx ] );
const int wellRateIdx = wellIdx * localWellState_.numPhases();
for( int np=0; np<localWellState_.numPhases(); ++np )
buffer.write( localWellState_.wellRates()[ wellRateIdx + np ] );
// Write well control
buffer.write(localWellState_.currentControls()[ wellIdx ]);
// Write perfRates and perfPress. No need to figure out the index
// mapping there as the ordering of the perforations should
// be the same for global and local state.
const int end_con = it->second[1] + it->second[2];
for( int con = it->second[1]; con < end_con; ++con )
{
buffer.write( localWellState_.perfRates()[ con ] );
}
for( int con = it->second[1]; con < end_con; ++con )
{
buffer.write( localWellState_.perfPress()[ con ] );
}
// Write perfPhaseRate
const int np = localWellState_.perfPhaseRates().size() /
localWellState_.perfRates().size();
for( int con = it->second[1]*np; con < end_con*np; ++con )
{
buffer.write( localWellState_.perfPhaseRates()[ con ] );
}
}
}
void readWells( MessageBufferType& buffer )
{
int nWells = -1;
buffer.read( nWells );
// unpack all wells that have been sent
std::string name ;
for( int well = 0; well < nWells ; ++well )
{
// read well name for local identification
readString( buffer, name );
// unpack values
auto it = globalWellState_.wellMap().find( name );
if( it == globalWellState_.wellMap().end() )
{
OPM_THROW(std::logic_error,"global state does not contain well " << name );
}
const int wellIdx = it->second[ 0 ];
buffer.read( globalWellState_.bhp()[ wellIdx ] );
buffer.read( globalWellState_.thp()[ wellIdx ] );
const int wellRateIdx = wellIdx * globalWellState_.numPhases();
for( int np=0; np<globalWellState_.numPhases(); ++np )
buffer.read( globalWellState_.wellRates()[ wellRateIdx + np ] );
// Write well control
buffer.read(globalWellState_.currentControls()[ wellIdx ]);
// Read perfRates and perfPress. No need to figure out the index
// mapping there as the ordering of the perforations should
// be the same for global and local state.
const int end_con = it->second[1] + it->second[2];
for( int con = it->second[1]; con < end_con; ++con )
{
buffer.read( globalWellState_.perfRates()[ con ] );
}
for( int con = it->second[1]; con < end_con; ++con )
{
buffer.read( globalWellState_.perfPress()[ con ] );
}
// Read perfPhaseRate
const int np = globalWellState_.perfPhaseRates().size() /
globalWellState_.perfRates().size();
for( int con = it->second[1]*np; con < end_con*np; ++con )
{
buffer.read( globalWellState_.perfPhaseRates()[ con ] );
}
}
}
};
// gather solution to rank 0 for EclipseWriter
bool collectToIORank( const SimulationDataContainer& /*localReservoirState*/,
const WellStateFullyImplicitBlackoil& localWellState,
const data::Solution& localCellData,
const int wellStateStepNumber )
{
if( isIORank() )
{
Dune::CpGrid& globalGrid = *grid_;
// TODO: make a dummy DynamicListEconLimited here for NOW for compilation and development
// TODO: NOT SURE whether it will cause problem for parallel running
// TODO: TO BE TESTED AND IMPROVED
const DynamicListEconLimited dynamic_list_econ_limited;
// Create wells and well state.
WellsManager wells_manager(eclipseState_,
wellStateStepNumber,
Opm::UgGridHelpers::numCells( globalGrid ),
Opm::UgGridHelpers::globalCell( globalGrid ),
Opm::UgGridHelpers::cartDims( globalGrid ),
Opm::UgGridHelpers::dimensions( globalGrid ),
Opm::UgGridHelpers::cell2Faces( globalGrid ),
Opm::UgGridHelpers::beginFaceCentroids( globalGrid ),
dynamic_list_econ_limited,
false,
// We need to pass the optionaly arguments
// as we get the following error otherwise
// with c++ (Debian 4.9.2-10) 4.9.2 and -std=c++11
// converting to const std::unordered_set<std::basic_string<char> > from initializer list would use explicit constructor
std::unordered_set<std::string>());
const Wells* wells = wells_manager.c_wells();
globalWellState_.init(wells, *globalReservoirState_, globalWellState_, phaseUsage_ );
globalCellData_->clear();
}
PackUnPackSimulationDataContainer packUnpack( numCells(),
localCellData, *globalCellData_,
localWellState, globalWellState_,
localIndexMap_, indexMaps_,
isIORank() );
//toIORankComm_.exchangeCached( packUnpack );
toIORankComm_.exchange( packUnpack );
#ifndef NDEBUG
// make sure every process is on the same page
toIORankComm_.barrier();
#endif
if( isIORank() )
{
// copy values from globalCellData to globalReservoirState
const std::map<std::string, std::vector<double> > no_extra_data;
solutionToSim(*globalCellData_, no_extra_data, phaseUsage_, *globalReservoirState_);
}
return isIORank();
}
const SimulationDataContainer& globalReservoirState() const { return *globalReservoirState_; }
const data::Solution& globalCellData() const
{
return *globalCellData_;
}
const WellStateFullyImplicitBlackoil& globalWellState() const { return globalWellState_; }
bool isIORank() const
{
return isIORank_;
}
bool isParallel() const
{
return toIORankComm_.size() > 1;
}
int numCells () const { return globalIndex_.size(); }
const int* globalCell () const
{
assert( ! globalIndex_.empty() );
return globalIndex_.data();
}
protected:
std::unique_ptr< Dune::CpGrid > grid_;
const EclipseState& eclipseState_;
P2PCommunicatorType toIORankComm_;
IndexMapType globalIndex_;
IndexMapType localIndexMap_;
IndexMapStorageType indexMaps_;
std::unique_ptr<SimulationDataContainer> globalReservoirState_;
std::unique_ptr<data::Solution> globalCellData_;
// this needs to be revised
WellStateFullyImplicitBlackoil globalWellState_;
// true if we are on I/O rank
bool isIORank_;
// Phase usage needed to convert solution to simulation data container
Opm::PhaseUsage phaseUsage_;
};
#endif // #if HAVE_OPM_GRID
} // end namespace Opm
#endif