ResInsight/ApplicationLibCode/ReservoirDataModel/RigNumberOfFloodedPoreVolumesCalculator.cpp

/////////////////////////////////////////////////////////////////////////////////
//
//  Copyright (C) 2017-     Statoil ASA
//
//  ResInsight 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.
//
//  ResInsight 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 at <http://www.gnu.org/licenses/gpl.html>
//  for more details.
//
/////////////////////////////////////////////////////////////////////////////////

#include "RigNumberOfFloodedPoreVolumesCalculator.h"

#include "RiaPorosityModel.h"

#include "RigActiveCellInfo.h"
#include "RigCaseCellResultsData.h"
#include "RigEclipseCaseData.h"
#include "RigEclipseResultAddress.h"
#include "RigMainGrid.h"
#include "RigNNCData.h"
#include "RigReservoirBuilderMock.h"

#include "RimEclipseCase.h"
#include "RimReservoirCellResultsStorage.h"

#include "cafProgressInfo.h"
#include <QString>
#include <vector>

//--------------------------------------------------------------------------------------------------
///
//--------------------------------------------------------------------------------------------------
RigNumberOfFloodedPoreVolumesCalculator::RigNumberOfFloodedPoreVolumesCalculator( RimEclipseCase*             caseToApply,
                                                                                  const std::vector<QString>& tracerNames )
{
    RigMainGrid* mainGrid = caseToApply->eclipseCaseData()->mainGrid();

    RigEclipseCaseData*     eclipseCaseData = caseToApply->eclipseCaseData();
    RigCaseCellResultsData* gridCellResults = caseToApply->results( RiaDefines::PorosityModelType::MATRIX_MODEL );

    RigActiveCellInfo* actCellInfo     = caseToApply->eclipseCaseData()->activeCellInfo( RiaDefines::PorosityModelType::MATRIX_MODEL );
    size_t             resultCellCount = actCellInfo->reservoirActiveCellCount();

    size_t timeStepCount = caseToApply->eclipseCaseData()->results( RiaDefines::PorosityModelType::MATRIX_MODEL )->maxTimeStepCount();
    size_t totalProgress = tracerNames.size() + 8 + timeStepCount + 2 * timeStepCount;
    caf::ProgressInfo progress( totalProgress, "Calculating number of flooded mobile pore volumes." );
    progress.setProgressDescription( "Loading required results" );
    // PORV
    const std::vector<double>* porvResults = nullptr;
    std::vector<double>        porvActiveCellsResultStorage;
    porvResults = RigCaseCellResultsData::getResultIndexableStaticResult( actCellInfo, gridCellResults, "PORV", porvActiveCellsResultStorage );

    progress.incrementProgress();

    // SWCR if defined

    const std::vector<double>* swcrResults = nullptr;
    swcrResults = RigCaseCellResultsData::getResultIndexableStaticResult( actCellInfo, gridCellResults, "SWCR", porvActiveCellsResultStorage );
    progress.incrementProgress();

    std::vector<RigEclipseResultAddress> tracerResAddrs;
    for ( QString tracerName : tracerNames )
    {
        RigEclipseResultAddress tracerResAddr( RiaDefines::ResultCatType::DYNAMIC_NATIVE, tracerName );
        if ( gridCellResults->ensureKnownResultLoaded( tracerResAddr ) )
        {
            tracerResAddrs.push_back( tracerResAddr );
        }
        progress.incrementProgress();
    }
    std::vector<std::vector<double>> summedTracersAtAllTimesteps;

    // TODO: Option for Oil and Gas instead of water
    RigEclipseResultAddress flrWatIAddr( RiaDefines::ResultCatType::DYNAMIC_NATIVE, "FLRWATI+" );
    RigEclipseResultAddress flrWatJAddr( RiaDefines::ResultCatType::DYNAMIC_NATIVE, "FLRWATJ+" );
    RigEclipseResultAddress flrWatKAddr( RiaDefines::ResultCatType::DYNAMIC_NATIVE, "FLRWATK+" );

    bool hasFlowrateI = gridCellResults->ensureKnownResultLoaded( flrWatIAddr );
    progress.incrementProgress();
    bool hasFlowrateJ = gridCellResults->ensureKnownResultLoaded( flrWatJAddr );
    progress.incrementProgress();
    bool hasFlowrateK = gridCellResults->ensureKnownResultLoaded( flrWatKAddr );
    progress.incrementProgress();

    std::vector<const std::vector<double>*> flowrateIatAllTimeSteps;
    std::vector<const std::vector<double>*> flowrateJatAllTimeSteps;
    std::vector<const std::vector<double>*> flowrateKatAllTimeSteps;

    RigNNCData*                  nncData     = eclipseCaseData->mainGrid()->nncData();
    const RigConnectionContainer connections = nncData->allConnections();

    progress.incrementProgress();

    // TODO: oil or gas flow rate
    std::vector<const std::vector<double>*> flowrateNNCatAllTimeSteps;
    QString                                 nncConnectionProperty = RiaDefines::propertyNameFluxWat();

    progress.incrementProgress();

    std::vector<double> daysSinceSimulationStart =
        caseToApply->eclipseCaseData()->results( RiaDefines::PorosityModelType::MATRIX_MODEL )->daysSinceSimulationStart();

    progress.incrementProgress();

    for ( size_t timeStep = 0; timeStep < daysSinceSimulationStart.size(); timeStep++ )
    {
        const std::vector<double>* flowrateI = nullptr;
        if ( hasFlowrateI )
        {
            flowrateI =
                &( eclipseCaseData->results( RiaDefines::PorosityModelType::MATRIX_MODEL )->cellScalarResults( flrWatIAddr, timeStep ) );
        }
        flowrateIatAllTimeSteps.push_back( flowrateI );

        const std::vector<double>* flowrateJ = nullptr;
        if ( hasFlowrateJ )
        {
            flowrateJ =
                &( eclipseCaseData->results( RiaDefines::PorosityModelType::MATRIX_MODEL )->cellScalarResults( flrWatJAddr, timeStep ) );
        }
        flowrateJatAllTimeSteps.push_back( flowrateJ );

        const std::vector<double>* flowrateK = nullptr;
        if ( hasFlowrateK )
        {
            flowrateK =
                &( eclipseCaseData->results( RiaDefines::PorosityModelType::MATRIX_MODEL )->cellScalarResults( flrWatKAddr, timeStep ) );
        }
        flowrateKatAllTimeSteps.push_back( flowrateK );

        size_t                     nativeTimeStepIndex = caseToApply->uiToNativeTimeStepIndex( timeStep );
        const std::vector<double>* connectionFlowrate =
            nncData->dynamicConnectionScalarResultByName( nncConnectionProperty, nativeTimeStepIndex );
        flowrateNNCatAllTimeSteps.push_back( connectionFlowrate );

        // sum all tracers at current timestep
        std::vector<double> summedTracerValues( resultCellCount );
        for ( const RigEclipseResultAddress& tracerResAddr : tracerResAddrs )
        {
            const std::vector<double>* tracerResult =
                &( eclipseCaseData->results( RiaDefines::PorosityModelType::MATRIX_MODEL )->cellScalarResults( tracerResAddr, timeStep ) );

            for ( size_t i = 0; i < summedTracerValues.size(); i++ )
            {
                summedTracerValues[i] += tracerResult->at( i );
            }
        }
        summedTracersAtAllTimesteps.push_back( summedTracerValues );

        progress.incrementProgress();
    }

    progress.setNextProgressIncrement( 2 * timeStepCount );
    progress.setProgressDescription( "Calculating" );

    calculate( mainGrid,
               caseToApply,
               daysSinceSimulationStart,
               porvResults,
               swcrResults,
               flowrateIatAllTimeSteps,
               flowrateJatAllTimeSteps,
               flowrateKatAllTimeSteps,
               connections,
               flowrateNNCatAllTimeSteps,
               summedTracersAtAllTimesteps );
}

//--------------------------------------------------------------------------------------------------
///
//--------------------------------------------------------------------------------------------------
std::vector<std::vector<double>>& RigNumberOfFloodedPoreVolumesCalculator::numberOfFloodedPorevolumes()
{
    return m_cumWinflowPVAllTimeSteps;
}

//--------------------------------------------------------------------------------------------------
///
//--------------------------------------------------------------------------------------------------
void RigNumberOfFloodedPoreVolumesCalculator::calculate( RigMainGrid*                            mainGrid,
                                                         RimEclipseCase*                         caseToApply,
                                                         std::vector<double>                     daysSinceSimulationStart,
                                                         const std::vector<double>*              porvResultsActiveCellsOnly,
                                                         const std::vector<double>*              swcrResults,
                                                         std::vector<const std::vector<double>*> flowrateIatAllTimeSteps,
                                                         std::vector<const std::vector<double>*> flowrateJatAllTimeSteps,
                                                         std::vector<const std::vector<double>*> flowrateKatAllTimeSteps,
                                                         const RigConnectionContainer&           connections,
                                                         std::vector<const std::vector<double>*> flowrateNNCatAllTimeSteps,
                                                         std::vector<std::vector<double>>        summedTracersAtAllTimesteps )
{
    // size_t totalNumberOfCells = mainGrid->globalCellArray().size();
    RigActiveCellInfo* actCellInfo     = caseToApply->eclipseCaseData()->activeCellInfo( RiaDefines::PorosityModelType::MATRIX_MODEL );
    size_t             resultCellCount = actCellInfo->reservoirActiveCellCount();

    caf::ProgressInfo progress( 2 * daysSinceSimulationStart.size(), "" );

    std::vector<std::vector<double>> cellQwInAtAllTimeSteps;
    std::vector<double>              cellQwInTimeStep0( resultCellCount );
    cellQwInAtAllTimeSteps.push_back( cellQwInTimeStep0 );

    for ( size_t timeStep = 1; timeStep < daysSinceSimulationStart.size(); timeStep++ )
    {
        std::vector<double> totoalFlowrateIntoCell( resultCellCount ); // brukt result celle index / active  antall i
                                                                       // stedet

        if ( flowrateIatAllTimeSteps[timeStep - 1] != nullptr && flowrateJatAllTimeSteps[timeStep - 1] != nullptr &&
             flowrateKatAllTimeSteps[timeStep - 1] != nullptr )

        {
            const std::vector<double>* flowrateI = flowrateIatAllTimeSteps[timeStep - 1];
            const std::vector<double>* flowrateJ = flowrateJatAllTimeSteps[timeStep - 1];
            const std::vector<double>* flowrateK = flowrateKatAllTimeSteps[timeStep - 1];

            if ( !flowrateI->empty() && !flowrateJ->empty() && !flowrateK->empty() )
            {
                distributeNeighbourCellFlow( mainGrid,
                                             caseToApply,
                                             summedTracersAtAllTimesteps[timeStep - 1],
                                             flowrateI,
                                             flowrateJ,
                                             flowrateK,
                                             totoalFlowrateIntoCell );
            }
        }

        const std::vector<double>* flowrateNNC = flowrateNNCatAllTimeSteps[timeStep - 1];

        if ( flowrateNNC && !flowrateNNC->empty() )
        {
            distributeNNCflow( connections, caseToApply, summedTracersAtAllTimesteps[timeStep - 1], flowrateNNC, totoalFlowrateIntoCell );
        }

        std::vector<double> CellQwIn( resultCellCount );

        double daysSinceSimStartNow          = daysSinceSimulationStart[timeStep];
        double daysSinceSimStartLastTimeStep = daysSinceSimulationStart[timeStep - 1];
        double deltaT                        = daysSinceSimStartNow - daysSinceSimStartLastTimeStep;

        for ( size_t cellResultIndex = 0; cellResultIndex < resultCellCount; cellResultIndex++ )
        {
            CellQwIn[cellResultIndex] = cellQwInAtAllTimeSteps[timeStep - 1][cellResultIndex] +
                                        ( totoalFlowrateIntoCell[cellResultIndex] ) * deltaT;
        }
        cellQwInAtAllTimeSteps.push_back( CellQwIn );

        progress.incrementProgress();
    }

    // Calculate number-of-cell-PV flooded

    std::vector<double> cumWinflowPVTimeStep0( resultCellCount );
    m_cumWinflowPVAllTimeSteps.clear();
    m_cumWinflowPVAllTimeSteps.push_back( cumWinflowPVTimeStep0 );

    for ( size_t timeStep = 1; timeStep < daysSinceSimulationStart.size(); timeStep++ )
    {
        std::vector<double> cumWinflowPV( resultCellCount );
        for ( size_t cellResultIndex = 0; cellResultIndex < resultCellCount; cellResultIndex++ )
        {
            double scaledPoreVolume = porvResultsActiveCellsOnly->at( cellResultIndex );
            if ( swcrResults != nullptr && swcrResults->size() == resultCellCount )
            {
                scaledPoreVolume = scaledPoreVolume * ( 1 - swcrResults->at( cellResultIndex ) );
            }

            cumWinflowPV[cellResultIndex] = cellQwInAtAllTimeSteps[timeStep][cellResultIndex] / scaledPoreVolume;
        }
        m_cumWinflowPVAllTimeSteps.push_back( cumWinflowPV );
        progress.incrementProgress();
    }
}

//--------------------------------------------------------------------------------------------------
///
//--------------------------------------------------------------------------------------------------
void RigNumberOfFloodedPoreVolumesCalculator::distributeNNCflow( const RigConnectionContainer& connections,
                                                                 RimEclipseCase*               caseToApply,
                                                                 const std::vector<double>&    summedTracerValues,
                                                                 const std::vector<double>*    flowrateNNC,
                                                                 std::vector<double>&          flowrateIntoCell )
{
    RigActiveCellInfo* actCellInfo = caseToApply->eclipseCaseData()->activeCellInfo( RiaDefines::PorosityModelType::MATRIX_MODEL );

    // Find max count for connections with result. Allen results introduce connections without results
    size_t connectionsWithResultCount = std::min( flowrateNNC->size(), connections.size() );

    for ( size_t connectionIndex = 0; connectionIndex < connectionsWithResultCount; connectionIndex++ )
    {
        RigConnection connection      = connections[connectionIndex];
        double        connectionValue = flowrateNNC->at( connectionIndex );

        size_t cell1Index       = connection.c1GlobIdx();
        size_t cell1ResultIndex = actCellInfo->cellResultIndex( cell1Index );

        size_t cell2Index       = connection.c2GlobIdx();
        size_t cell2ResultIndex = actCellInfo->cellResultIndex( cell2Index );

        if ( connectionValue > 0 )
        {
            // Flow out of cell with cell1index, into cell cell2index
            flowrateIntoCell[cell2ResultIndex] += connectionValue * summedTracerValues[cell1ResultIndex];
        }
        else if ( connectionValue < 0 )
        {
            // flow out of cell with cell2index, into cell cell1index
            flowrateIntoCell[cell1ResultIndex] += -1.0 * connectionValue * summedTracerValues[cell2ResultIndex];
        }
    }
}

//--------------------------------------------------------------------------------------------------
///
//--------------------------------------------------------------------------------------------------
void RigNumberOfFloodedPoreVolumesCalculator::distributeNeighbourCellFlow( RigMainGrid*               mainGrid,
                                                                           RimEclipseCase*            caseToApply,
                                                                           const std::vector<double>& summedTracerValues,
                                                                           const std::vector<double>* flrWatResultI,
                                                                           const std::vector<double>* flrWatResultJ,
                                                                           const std::vector<double>* flrWatResultK,
                                                                           std::vector<double>&       totalFlowrateIntoCell )
{
    RigActiveCellInfo* actCellInfo = caseToApply->eclipseCaseData()->activeCellInfo( RiaDefines::PorosityModelType::MATRIX_MODEL );

    for ( size_t globalCellIndex = 0; globalCellIndex < mainGrid->totalCellCount(); globalCellIndex++ )
    {
        if ( !actCellInfo->isActive( globalCellIndex ) ) continue;

        const RigCell& cell               = mainGrid->cell( globalCellIndex );
        RigGridBase*   hostGrid           = cell.hostGrid();
        size_t         gridLocalCellIndex = cell.gridLocalCellIndex();

        size_t cellResultIndex = actCellInfo->cellResultIndex( globalCellIndex );

        size_t i, j, k;
        hostGrid->ijkFromCellIndex( gridLocalCellIndex, &i, &j, &k );

        if ( i < ( hostGrid->cellCountI() - 1 ) )
        {
            size_t gridLocalCellIndexPosINeighbour = hostGrid->cellIndexFromIJK( i + 1, j, k );
            size_t reservoirCellIndexPosINeighbour = hostGrid->reservoirCellIndex( gridLocalCellIndexPosINeighbour );
            size_t cellResultIndexPosINeighbour    = actCellInfo->cellResultIndex( reservoirCellIndexPosINeighbour );

            if ( !actCellInfo->isActive( reservoirCellIndexPosINeighbour ) ) continue;

            if ( hostGrid->cell( gridLocalCellIndexPosINeighbour ).subGrid() != nullptr )
            {
                // subgrid exists in cell, will be handled though NNCs
                continue;
            }

            if ( flrWatResultI->at( cellResultIndex ) > 0 )
            {
                // Flow out of cell globalCellIndex, into cell i+1
                totalFlowrateIntoCell[cellResultIndexPosINeighbour] +=
                    flrWatResultI->at( cellResultIndex ) * summedTracerValues[cellResultIndex];
            }
            else if ( flrWatResultI->at( cellResultIndex ) < 0 )
            {
                // Flow into cell globelCellIndex, from cell i+1
                totalFlowrateIntoCell[cellResultIndex] +=
                    ( -1.0 ) * flrWatResultI->at( cellResultIndex ) * summedTracerValues[cellResultIndexPosINeighbour];
            }
        }

        if ( j < ( hostGrid->cellCountJ() - 1 ) )
        {
            size_t gridLocalCellIndexPosJNeighbour = hostGrid->cellIndexFromIJK( i, j + 1, k );
            size_t reservoirCellIndexPosJNeighbour = hostGrid->reservoirCellIndex( gridLocalCellIndexPosJNeighbour );
            size_t cellResultIndexPosJNeighbour    = actCellInfo->cellResultIndex( reservoirCellIndexPosJNeighbour );

            if ( !actCellInfo->isActive( reservoirCellIndexPosJNeighbour ) ) continue;

            if ( hostGrid->cell( gridLocalCellIndexPosJNeighbour ).subGrid() != nullptr )
            {
                // subgrid exists in cell, will be handled though NNCs
                continue;
            }

            if ( flrWatResultJ->at( cellResultIndex ) > 0 )
            {
                // Flow out of cell globalCellIndex, into cell i+1
                totalFlowrateIntoCell[cellResultIndexPosJNeighbour] +=
                    flrWatResultJ->at( cellResultIndex ) * summedTracerValues[cellResultIndex];
            }
            else if ( flrWatResultJ->at( cellResultIndex ) < 0 )
            {
                // Flow into cell globelCellIndex, from cell i+1
                totalFlowrateIntoCell[cellResultIndex] +=
                    ( -1.0 ) * flrWatResultJ->at( cellResultIndex ) * summedTracerValues[cellResultIndexPosJNeighbour];
            }
        }

        if ( k < ( hostGrid->cellCountK() - 1 ) )
        {
            size_t gridLocalCellIndexPosKNeighbour = hostGrid->cellIndexFromIJK( i, j, k + 1 );
            size_t reservoirCellIndexPosKNeighbour = hostGrid->reservoirCellIndex( gridLocalCellIndexPosKNeighbour );
            size_t cellResultIndexPosKNeighbour    = actCellInfo->cellResultIndex( reservoirCellIndexPosKNeighbour );

            if ( !actCellInfo->isActive( reservoirCellIndexPosKNeighbour ) ) continue;

            if ( hostGrid->cell( gridLocalCellIndexPosKNeighbour ).subGrid() != nullptr )
            {
                // subgrid exists in cell, will be handled though NNCs
                continue;
            }

            if ( flrWatResultK->at( cellResultIndex ) > 0 )
            {
                // Flow out of cell globalCellIndex, into cell i+1
                totalFlowrateIntoCell[cellResultIndexPosKNeighbour] +=
                    flrWatResultK->at( cellResultIndex ) * summedTracerValues[cellResultIndex];
            }
            else if ( flrWatResultK->at( cellResultIndex ) < 0 )
            {
                // Flow into cell globelCellIndex, from cell i+1
                totalFlowrateIntoCell[cellResultIndex] +=
                    ( -1.0 ) * flrWatResultK->at( cellResultIndex ) * summedTracerValues[cellResultIndexPosKNeighbour];
            }
        }
    }
}