ResInsight/ApplicationCode/ReservoirDataModel/RigFlowDiagResults.cpp

/////////////////////////////////////////////////////////////////////////////////
//
//  Copyright (C) 2016-     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 "RigFlowDiagResults.h"

#include "RigActiveCellInfo.h"
#include "RigEclipseCaseData.h"
#include "RigFlowDiagSolverInterface.h"
#include "RigFlowDiagStatCalc.h"
#include "RigEclipseCaseData.h"
#include "RigMainGrid.h"

#include "RimEclipseCase.h"
#include "RimEclipseResultCase.h"
#include "RimFlowDiagSolution.h"
#include "RigFlowDiagResultFrames.h"
#include "RigStatisticsDataCache.h"
#include "RigNumberOfFloodedPoreVolumesCalculator.h"

#include <cmath> // Needed for HUGE_VAL on Linux

namespace caf
{
    template<>
    void RigFlowDiagResults::CellFilterEnum::setUp()
    {
        addItem(RigFlowDiagResults::CELLS_ACTIVE,        "CELLS_ACTIVE",        "All Active Cells");
        addItem(RigFlowDiagResults::CELLS_VISIBLE,       "CELLS_VISIBLE",       "Visible Cells");
        addItem(RigFlowDiagResults::CELLS_COMMUNICATION, "CELLS_COMMUNICATION", "Injector Producer Communication");
        addItem(RigFlowDiagResults::CELLS_FLOODED,       "CELLS_FLOODED",       "Flooded by Injector");
        addItem(RigFlowDiagResults::CELLS_DRAINED,       "CELLS_DRAINED",       "Drained by Producer");
        setDefault(RigFlowDiagResults::CELLS_ACTIVE);
    }
}

//--------------------------------------------------------------------------------------------------
/// 
//--------------------------------------------------------------------------------------------------
RigFlowDiagResults::RigFlowDiagResults(RimFlowDiagSolution* flowSolution, size_t timeStepCount)
 : m_flowDiagSolution(flowSolution)
{

    m_timeStepCount = timeStepCount;
    m_hasAtemptedNativeResults.resize(timeStepCount);
    m_injProdPairFluxCommunicationTimesteps.resize(timeStepCount);
}

//--------------------------------------------------------------------------------------------------
/// 
//--------------------------------------------------------------------------------------------------
RigFlowDiagResults::~RigFlowDiagResults()
{

}


//--------------------------------------------------------------------------------------------------
/// 
//--------------------------------------------------------------------------------------------------
const std::vector<double>* RigFlowDiagResults::resultValues(const RigFlowDiagResultAddress& resVarAddr, size_t timeStepIndex)
{
    CVF_ASSERT(m_timeStepCount != cvf::UNDEFINED_SIZE_T); // Forgotten to call init

    return findOrCalculateResult(resVarAddr, timeStepIndex);
}

//--------------------------------------------------------------------------------------------------
/// 
//--------------------------------------------------------------------------------------------------
const RigActiveCellInfo * RigFlowDiagResults::activeCellInfo(const RigFlowDiagResultAddress& resVarAddr)
{
    RimEclipseResultCase* eclCase;
    m_flowDiagSolution->firstAncestorOrThisOfType(eclCase);
    
    return eclCase->eclipseCaseData()->activeCellInfo(RiaDefines::MATRIX_MODEL); // Todo: base on resVarAddr member
}

//--------------------------------------------------------------------------------------------------
/// 
//--------------------------------------------------------------------------------------------------
const std::vector<double>* RigFlowDiagResults::findOrCalculateResult(const RigFlowDiagResultAddress& resVarAddr, size_t timeStepIndex)
{
   
    std::vector<double>* frameData = findScalarResultFrame(resVarAddr, timeStepIndex);

    if ( frameData ) return frameData;

    frameData = calculateDerivedResult(resVarAddr, timeStepIndex);

    if ( frameData ) return frameData;

    // We need to access the native data from the opm solver

    if (!solverInterface()) return nullptr;

    calculateNativeResultsIfNotPreviouslyAttempted(timeStepIndex, resVarAddr.phaseSelection);

    return findScalarResultFrame(resVarAddr, timeStepIndex);
}

//--------------------------------------------------------------------------------------------------
/// 
//--------------------------------------------------------------------------------------------------
void RigFlowDiagResults::calculateNativeResultsIfNotPreviouslyAttempted(size_t timeStepIndex, RigFlowDiagResultAddress::PhaseSelection phaseSelection)
{
    auto it = m_hasAtemptedNativeResults[timeStepIndex].find(phaseSelection);
    if ( it == m_hasAtemptedNativeResults[timeStepIndex].end() || !it->second )
    {

        RigFlowDiagTimeStepResult nativeTimestepResults =  solverInterface()->calculate(timeStepIndex,
                                                                                        phaseSelection,
                                                                                        m_flowDiagSolution->allInjectorTracerActiveCellIndices(timeStepIndex),
                                                                                        m_flowDiagSolution->allProducerTracerActiveCellIndices(timeStepIndex));

        std::map<RigFlowDiagResultAddress, std::vector<double> >& nativeResults = nativeTimestepResults.nativeResults();

        for ( auto& resIt: nativeResults )
        {
            RigFlowDiagResultFrames*  nativeResFrames = findScalarResult(resIt.first);
            if ( !nativeResFrames ) nativeResFrames = createScalarResult(resIt.first);

            nativeResFrames->frameData(timeStepIndex).swap(resIt.second);
        }

        m_injProdPairFluxCommunicationTimesteps[timeStepIndex][phaseSelection].swap(nativeTimestepResults.injProdWellPairFluxes());

        m_hasAtemptedNativeResults[timeStepIndex][phaseSelection] = true;
    }
}

//--------------------------------------------------------------------------------------------------
/// 
//--------------------------------------------------------------------------------------------------
std::vector<double>* RigFlowDiagResults::findScalarResultFrame(const RigFlowDiagResultAddress& resVarAddr, size_t timeStepIndex)
{
    RigFlowDiagResultFrames*  resFrames = findScalarResult  (resVarAddr);

    if ( resFrames )
    {
        std::vector<double>& frame = resFrames->frameData(timeStepIndex);
        if ( frame.size() ) return(&frame);
    }
    return nullptr;
}

//--------------------------------------------------------------------------------------------------
/// 
//--------------------------------------------------------------------------------------------------
RigFlowDiagSolverInterface* RigFlowDiagResults::solverInterface()
{
    RimEclipseResultCase* eclCase;
    m_flowDiagSolution->firstAncestorOrThisOfType(eclCase);

    return eclCase->flowDiagSolverInterface();
}

//--------------------------------------------------------------------------------------------------
/// 
//--------------------------------------------------------------------------------------------------
RigFlowDiagResultFrames* RigFlowDiagResults::createScalarResult(const RigFlowDiagResultAddress& resVarAddr)
{
    cvf::ref<RigFlowDiagResultFrames> newFrameSet = new RigFlowDiagResultFrames(m_timeStepCount);
    m_resultSets[resVarAddr] = newFrameSet;

    return newFrameSet.p();
}

//--------------------------------------------------------------------------------------------------
/// 
//--------------------------------------------------------------------------------------------------
RigFlowDiagResultFrames* RigFlowDiagResults::findScalarResult(const RigFlowDiagResultAddress& resVarAddr)
{
    decltype(m_resultSets)::iterator it = m_resultSets.find(resVarAddr);

    if ( it == m_resultSets.end() ) return nullptr;

    return it->second.p();
}

//--------------------------------------------------------------------------------------------------
/// 
//--------------------------------------------------------------------------------------------------
std::vector<double>* RigFlowDiagResults::calculateDerivedResult(const RigFlowDiagResultAddress& resVarAddr, size_t timeStepIndex)
{
    if (resVarAddr.isNativeResult()) return nullptr;

    if (resVarAddr.variableName == RIG_FLD_TOF_RESNAME)
    {
        return calculateAverageTOFResult(resVarAddr, timeStepIndex);
    }
    else if (resVarAddr.variableName == RIG_FLD_CELL_FRACTION_RESNAME)
    {
        return calculateSumOfFractionsResult(resVarAddr, timeStepIndex);
    }
    else if ( resVarAddr.variableName == RIG_FLD_COMMUNICATION_RESNAME )
    {
        return calculateCommunicationResult(resVarAddr, timeStepIndex);
    }
    else if ( resVarAddr.variableName == RIG_FLD_MAX_FRACTION_TRACER_RESNAME )
    {
        return calculateTracerWithMaxFractionResult(resVarAddr, timeStepIndex);
    }
    else if (resVarAddr.variableName == RIG_NUM_FLOODED_PV)
    {
        calculateNumFloodedPV(resVarAddr);
        return findScalarResultFrame(resVarAddr, timeStepIndex);
    }

    return nullptr; 
}


//--------------------------------------------------------------------------------------------------
/// 
//--------------------------------------------------------------------------------------------------
std::vector<double>* RigFlowDiagResults::calculateAverageTOFResult(const RigFlowDiagResultAddress& resVarAddr, size_t timeStepIndex)
{
    std::vector<const std::vector<double>* > injectorTOFs      = findResultsForSelectedTracers(resVarAddr, timeStepIndex,
                                                                                               RIG_FLD_TOF_RESNAME, RimFlowDiagSolution::INJECTOR);
    std::vector<const std::vector<double>* > injectorFractions = findResultsForSelectedTracers(resVarAddr, timeStepIndex,
                                                                                               RIG_FLD_CELL_FRACTION_RESNAME, RimFlowDiagSolution::INJECTOR);

    std::vector<const std::vector<double>* > producerTOFs      = findResultsForSelectedTracers(resVarAddr, timeStepIndex,
                                                                                               RIG_FLD_TOF_RESNAME, RimFlowDiagSolution::PRODUCER);
    std::vector<const std::vector<double>* > producerFractions = findResultsForSelectedTracers(resVarAddr, timeStepIndex,
                                                                                               RIG_FLD_CELL_FRACTION_RESNAME, RimFlowDiagSolution::PRODUCER);
    size_t activeCellCount =  this->activeCellInfo(resVarAddr)->reservoirActiveCellCount();

    std::vector<double> injectorTotalFractions;
    std::vector<double> injectorFractMultTof;
    calculateSumOfFractionAndFractionMultTOF(activeCellCount, injectorFractions, injectorTOFs, &injectorTotalFractions, &injectorFractMultTof);

    std::vector<double> producerTotalFractions;
    std::vector<double> producerFractMultTof;
    calculateSumOfFractionAndFractionMultTOF(activeCellCount, producerFractions, producerTOFs, &producerTotalFractions, &producerFractMultTof);

    RigFlowDiagResultFrames* averageTofFrames = this->createScalarResult(resVarAddr);
    std::vector<double>& averageTof = averageTofFrames->frameData(timeStepIndex);
    averageTof.resize(activeCellCount, HUGE_VAL);

    for ( size_t acIdx = 0 ; acIdx < activeCellCount; ++acIdx )
    {
        if ( injectorTotalFractions[acIdx] == 0.0 && producerTotalFractions[acIdx] == 0.0 )
        {
            averageTof[acIdx] = HUGE_VAL;
        }
        else
        {
            double retVal = 0.0;
            if ( injectorTotalFractions[acIdx] != 0.0 ) retVal +=  (1.0/injectorTotalFractions[acIdx]) * injectorFractMultTof[acIdx];
            if ( producerTotalFractions[acIdx] != 0.0 ) retVal +=  (1.0/producerTotalFractions[acIdx]) * producerFractMultTof[acIdx];
            averageTof[acIdx] = retVal;
        }
    }

    /// Test to remove all averaging    
    // if (injectorTOFs.size()) averageTof = (*injectorTOFs[0]);

    return &averageTof;
}


//--------------------------------------------------------------------------------------------------
/// 
//--------------------------------------------------------------------------------------------------
void RigFlowDiagResults::calculateSumOfFractionAndFractionMultTOF(size_t activeCellCount,
                                                                  const std::vector<const std::vector<double> *> & fractions, 
                                                                  const std::vector<const std::vector<double> *> & TOFs,
                                                                  std::vector<double> *sumOfFractions,
                                                                  std::vector<double> *fractionMultTOF)
{
    sumOfFractions->resize(activeCellCount, 0.0);
    fractionMultTOF->resize(activeCellCount, 0.0);

    for ( size_t iIdx = 0; iIdx < fractions.size() ; ++iIdx )
    {
        const std::vector<double> * frInj = fractions[iIdx];
        const std::vector<double> * tofInj = TOFs[iIdx];

        if ( ! (frInj && tofInj) ) continue;

        for ( size_t acIdx = 0 ; acIdx < activeCellCount; ++acIdx )
        {
            if ( (*frInj)[acIdx] == HUGE_VAL ) continue;

            (*sumOfFractions)[acIdx] += (*frInj)[acIdx];
            (*fractionMultTOF)[acIdx]   += (*frInj)[acIdx] * (*tofInj)[acIdx];
        }
    }
}

//--------------------------------------------------------------------------------------------------
/// 
//--------------------------------------------------------------------------------------------------
std::vector<double>* RigFlowDiagResults::calculateSumOfFractionsResult(const RigFlowDiagResultAddress& resVarAddr, size_t timeStepIndex)
{
    std::vector<const std::vector<double>* > fractions = findResultsForSelectedTracers(resVarAddr,
                                                                                       timeStepIndex,
                                                                                       RIG_FLD_CELL_FRACTION_RESNAME,
                                                                                       RimFlowDiagSolution::UNDEFINED);

    RigFlowDiagResultFrames* sumOfFractionsFrames = this->createScalarResult(resVarAddr);
    std::vector<double>& sumOfFractions = sumOfFractionsFrames->frameData(timeStepIndex);

    size_t activeCellCount =  this->activeCellInfo(resVarAddr)->reservoirActiveCellCount();

    calculateSumOfFractions(fractions, activeCellCount, &sumOfFractions);

    return &sumOfFractions;
}


//--------------------------------------------------------------------------------------------------
/// 
//--------------------------------------------------------------------------------------------------
std::vector<double>* RigFlowDiagResults::calculateTracerWithMaxFractionResult(const RigFlowDiagResultAddress &resVarAddr, size_t timeStepIndex)
{
    std::vector< std::pair<std::string, const std::vector<double>* > > fractions = findNamedResultsForSelectedTracers(resVarAddr,
                                                                                                                      timeStepIndex,
                                                                                                                      RIG_FLD_CELL_FRACTION_RESNAME,
                                                                                                                      RimFlowDiagSolution::UNDEFINED);

    std::vector<int> resultTracerIdxToGlobalTracerIdx;
    {
        resultTracerIdxToGlobalTracerIdx.resize(fractions.size(), -1);

        std::vector<QString> allTracerNames = m_flowDiagSolution->tracerNames();
        int selTracerIdx = 0;
        for ( const auto& trNameFractionPair: fractions )
        {
            for ( size_t globIdx = 0; globIdx < allTracerNames.size(); ++globIdx )
            {
                if ( allTracerNames[globIdx].toStdString() == trNameFractionPair.first )
                {
                    resultTracerIdxToGlobalTracerIdx[selTracerIdx] = static_cast<int>(globIdx);
                    break;
                }
            }

            ++selTracerIdx;
        }
    }

    size_t activeCellCount =  this->activeCellInfo(resVarAddr)->reservoirActiveCellCount();

    RigFlowDiagResultFrames* maxFractionTracerIdxFrames = this->createScalarResult(resVarAddr);
    std::vector<double>& maxFractionTracerIdx = maxFractionTracerIdxFrames->frameData(timeStepIndex);
    {

        maxFractionTracerIdx.resize(activeCellCount, HUGE_VAL);

        std::vector<double> maxFraction;
        maxFraction.resize(activeCellCount, -HUGE_VAL);

        for ( size_t frIdx = 0; frIdx < fractions.size(); ++frIdx )
        {
            const std::vector<double> * fr = fractions[frIdx].second;

            if (!fr) continue;

            for ( size_t acIdx = 0 ; acIdx < activeCellCount; ++acIdx )
            {
                if ( (*fr)[acIdx] == HUGE_VAL ) continue;

                if ( maxFraction[acIdx] < (*fr)[acIdx] )
                {
                    maxFraction[acIdx] =  (*fr)[acIdx];
                    maxFractionTracerIdx[acIdx] = resultTracerIdxToGlobalTracerIdx[frIdx];
                }
            }
        }
    }

    return &maxFractionTracerIdx;
}


//--------------------------------------------------------------------------------------------------
/// 
//--------------------------------------------------------------------------------------------------
std::vector<double>* RigFlowDiagResults::calculateCommunicationResult(const RigFlowDiagResultAddress& resVarAddr, size_t timeStepIndex)
{
    std::vector<const std::vector<double>* > injectorFractions = findResultsForSelectedTracers(resVarAddr,
                                                                                               timeStepIndex,
                                                                                               RIG_FLD_CELL_FRACTION_RESNAME,
                                                                                               RimFlowDiagSolution::INJECTOR);
    std::vector<const std::vector<double>* > producerFractions = findResultsForSelectedTracers(resVarAddr,
                                                                                               timeStepIndex,
                                                                                               RIG_FLD_CELL_FRACTION_RESNAME,
                                                                                               RimFlowDiagSolution::PRODUCER);
    size_t activeCellCount =  this->activeCellInfo(resVarAddr)->reservoirActiveCellCount();

    std::vector<double> sumOfInjectorFractions;
    calculateSumOfFractions(injectorFractions, activeCellCount, &sumOfInjectorFractions);

    std::vector<double> sumOfProducerFractions;
    calculateSumOfFractions(producerFractions, activeCellCount, &sumOfProducerFractions);

    RigFlowDiagResultFrames* commFrames = this->createScalarResult(resVarAddr);
    std::vector<double>& commPI = commFrames->frameData(timeStepIndex);
    commPI.resize(activeCellCount, HUGE_VAL);

    for ( size_t acIdx = 0 ; acIdx < activeCellCount; ++acIdx )
    {
        if ( (sumOfInjectorFractions)[acIdx] == HUGE_VAL ) continue;
        if ( (sumOfProducerFractions)[acIdx] == HUGE_VAL ) continue;

        (commPI)[acIdx] =  (sumOfInjectorFractions)[acIdx] * (sumOfProducerFractions)[acIdx];
    }

    return &commPI;
}

//--------------------------------------------------------------------------------------------------
/// 
//--------------------------------------------------------------------------------------------------
void RigFlowDiagResults::calculateNumFloodedPV(const RigFlowDiagResultAddress& resVarAddr)
{
    RimEclipseCase* eclipseCase;
    m_flowDiagSolution->firstAncestorOrThisOfTypeAsserted(eclipseCase);
    std::vector<QString> tracerNames;
    for (const std::string& tracerName : resVarAddr.selectedTracerNames)
    {
        tracerNames.push_back(QString::fromUtf8(tracerName.c_str()));
    }
    RigNumberOfFloodedPoreVolumesCalculator calc(eclipseCase, tracerNames);

    RigFlowDiagResultFrames* frames = this->createScalarResult(resVarAddr);
    for (size_t frameIdx = 0; frameIdx < m_timeStepCount; ++frameIdx)
    {
        std::vector<double>& frame = frames->frameData(frameIdx);

        frame.swap(calc.numberOfFloodedPorevolumes()[frameIdx]);
    }
}


//--------------------------------------------------------------------------------------------------
/// 
//--------------------------------------------------------------------------------------------------
std::vector<const std::vector<double>* > RigFlowDiagResults::findResultsForSelectedTracers(const RigFlowDiagResultAddress& resVarAddr,
                                                                                           size_t timeStepIndex,
                                                                                           const std::string& nativeResultName,
                                                                                           RimFlowDiagSolution::TracerStatusType wantedTracerType)
{

    std::vector<const std::vector<double>* > selectedTracersResults;

    for ( const std::string& tracerName: resVarAddr.selectedTracerNames )
    {
        RimFlowDiagSolution::TracerStatusType tracerType = m_flowDiagSolution->tracerStatusInTimeStep(QString::fromStdString(tracerName), timeStepIndex);

        if (tracerType != RimFlowDiagSolution::CLOSED 
            && ( tracerType == wantedTracerType || wantedTracerType == RimFlowDiagSolution::UNDEFINED) )
        {
            selectedTracersResults.push_back(findOrCalculateResult(RigFlowDiagResultAddress(nativeResultName, resVarAddr.phaseSelection, tracerName), timeStepIndex));
        }
    }

    return selectedTracersResults;
}


//--------------------------------------------------------------------------------------------------
/// 
//--------------------------------------------------------------------------------------------------
std::vector< std::pair<std::string, const std::vector<double>*> > 
RigFlowDiagResults::findNamedResultsForSelectedTracers(const RigFlowDiagResultAddress& resVarAddr,
                                                       size_t timeStepIndex,
                                                       const std::string& nativeResultName,
                                                       RimFlowDiagSolution::TracerStatusType wantedTracerType)
{

    std::vector<std::pair<std::string, const std::vector<double>* > > selectedTracersResults;

    for ( const std::string& tracerName: resVarAddr.selectedTracerNames )
    {
        RimFlowDiagSolution::TracerStatusType tracerType = m_flowDiagSolution->tracerStatusInTimeStep(QString::fromStdString(tracerName), timeStepIndex);

        if (tracerType != RimFlowDiagSolution::CLOSED 
            && ( tracerType == wantedTracerType || wantedTracerType == RimFlowDiagSolution::UNDEFINED) )
        {
            selectedTracersResults.push_back(std::make_pair(tracerName, findOrCalculateResult(RigFlowDiagResultAddress(nativeResultName, resVarAddr.phaseSelection, tracerName), timeStepIndex)));
        }
    }

    return selectedTracersResults;
}


//--------------------------------------------------------------------------------------------------
/// 
//--------------------------------------------------------------------------------------------------
RigStatisticsDataCache* RigFlowDiagResults::statistics(const RigFlowDiagResultAddress& resVarAddr)
{
    RigStatisticsDataCache* statCache = m_resultStatistics[resVarAddr].p();
    if ( !statCache )
    {
        RigFlowDiagStatCalc* calculator = new RigFlowDiagStatCalc(this, resVarAddr);
        statCache = new RigStatisticsDataCache(calculator);
        m_resultStatistics[resVarAddr] = statCache;
    }

    return statCache;
}

//--------------------------------------------------------------------------------------------------
/// 
//--------------------------------------------------------------------------------------------------
void RigFlowDiagResults::calculateSumOfFractions(const std::vector<const std::vector<double> *> &fractions, 
                                                 size_t activeCellCount,
                                                 std::vector<double>* sumOfFractions)
{
    sumOfFractions->resize(activeCellCount, HUGE_VAL);

    for ( size_t iIdx = 0; iIdx < fractions.size() ; ++iIdx )
    {
        const std::vector<double> * fraction = fractions[iIdx];

        if ( ! (fraction) ) continue;

        for ( size_t acIdx = 0 ; acIdx < activeCellCount; ++acIdx )
        {
            if ( (*fraction)[acIdx] == HUGE_VAL ) continue;

            if ( (*sumOfFractions)[acIdx] == HUGE_VAL ) (*sumOfFractions)[acIdx] = 0.0;

            (*sumOfFractions)[acIdx] += (*fraction)[acIdx];
        }
    }
}

//--------------------------------------------------------------------------------------------------
/// 
//--------------------------------------------------------------------------------------------------
void RigFlowDiagResults::minMaxScalarValues(const RigFlowDiagResultAddress& resVarAddr, int timeStepIndex,
                                                     double* localMin, double* localMax)
{
    this->statistics(resVarAddr)->minMaxCellScalarValues(timeStepIndex, *localMin, *localMax);
}

//--------------------------------------------------------------------------------------------------
/// 
//--------------------------------------------------------------------------------------------------
void RigFlowDiagResults::minMaxScalarValues(const RigFlowDiagResultAddress& resVarAddr,
                                                     double* globalMin, double* globalMax)
{
    this->statistics(resVarAddr)->minMaxCellScalarValues(*globalMin, *globalMax);
}

//--------------------------------------------------------------------------------------------------
/// 
//--------------------------------------------------------------------------------------------------
void RigFlowDiagResults::posNegClosestToZero(const RigFlowDiagResultAddress& resVarAddr, int timeStepIndex, double* localPosClosestToZero, double* localNegClosestToZero)
{
    this->statistics(resVarAddr)->posNegClosestToZero(timeStepIndex, *localPosClosestToZero, *localNegClosestToZero);
}

//--------------------------------------------------------------------------------------------------
/// 
//--------------------------------------------------------------------------------------------------
void RigFlowDiagResults::posNegClosestToZero(const RigFlowDiagResultAddress& resVarAddr, double* globalPosClosestToZero, double* globalNegClosestToZero)
{
    this->statistics(resVarAddr)->posNegClosestToZero(*globalPosClosestToZero, *globalNegClosestToZero);
}

//--------------------------------------------------------------------------------------------------
/// 
//--------------------------------------------------------------------------------------------------
void RigFlowDiagResults::meanScalarValue(const RigFlowDiagResultAddress& resVarAddr, double* meanValue)
{
    CVF_ASSERT(meanValue);

    this->statistics(resVarAddr)->meanCellScalarValues(*meanValue);
}

//--------------------------------------------------------------------------------------------------
/// 
//--------------------------------------------------------------------------------------------------
void RigFlowDiagResults::meanScalarValue(const RigFlowDiagResultAddress& resVarAddr, int timeStepIndex, double* meanValue)
{
    this->statistics(resVarAddr)->meanCellScalarValues(timeStepIndex, *meanValue);
}

//--------------------------------------------------------------------------------------------------
/// 
//--------------------------------------------------------------------------------------------------
void RigFlowDiagResults::p10p90ScalarValues(const RigFlowDiagResultAddress& resVarAddr, double* p10, double* p90)
{
    this->statistics(resVarAddr)->p10p90CellScalarValues(*p10, *p90);
}

//--------------------------------------------------------------------------------------------------
/// 
//--------------------------------------------------------------------------------------------------
void RigFlowDiagResults::p10p90ScalarValues(const RigFlowDiagResultAddress& resVarAddr, int timeStepIndex, double* p10, double* p90)
{
    this->statistics(resVarAddr)->p10p90CellScalarValues(timeStepIndex, *p10, *p90);
}

//--------------------------------------------------------------------------------------------------
/// 
//--------------------------------------------------------------------------------------------------
void RigFlowDiagResults::sumScalarValue(const RigFlowDiagResultAddress& resVarAddr, double* sum)
{
    CVF_ASSERT(sum);

    this->statistics(resVarAddr)->sumCellScalarValues(*sum);
}

//--------------------------------------------------------------------------------------------------
/// 
//--------------------------------------------------------------------------------------------------
void RigFlowDiagResults::sumScalarValue(const RigFlowDiagResultAddress& resVarAddr, int timeStepIndex, double* sum)
{
    CVF_ASSERT(sum);

    this->statistics(resVarAddr)->sumCellScalarValues(timeStepIndex, *sum);
}

//--------------------------------------------------------------------------------------------------
/// 
//--------------------------------------------------------------------------------------------------
const std::vector<size_t>& RigFlowDiagResults::scalarValuesHistogram(const RigFlowDiagResultAddress& resVarAddr)
{
    return this->statistics(resVarAddr)->cellScalarValuesHistogram();
}

//--------------------------------------------------------------------------------------------------
/// 
//--------------------------------------------------------------------------------------------------
const std::vector<size_t>& RigFlowDiagResults::scalarValuesHistogram(const RigFlowDiagResultAddress& resVarAddr, int timeStepIndex)
{
    return this->statistics(resVarAddr)->cellScalarValuesHistogram(timeStepIndex);
}

//--------------------------------------------------------------------------------------------------
/// 
//--------------------------------------------------------------------------------------------------
const std::vector<int>& RigFlowDiagResults::uniqueCellScalarValues(const RigFlowDiagResultAddress& resVarAddr)
{
    return this->statistics(resVarAddr)->uniqueCellScalarValues();
}

//--------------------------------------------------------------------------------------------------
/// 
//--------------------------------------------------------------------------------------------------
const std::vector<int>& RigFlowDiagResults::uniqueCellScalarValues(const RigFlowDiagResultAddress& resVarAddr, int timeStepIndex)
{
    return this->statistics(resVarAddr)->uniqueCellScalarValues(timeStepIndex);
}

//--------------------------------------------------------------------------------------------------
/// 
//--------------------------------------------------------------------------------------------------
void RigFlowDiagResults::mobileVolumeWeightedMean(const RigFlowDiagResultAddress& resVarAddr, int timeStepIndex, double* mean)
{
    this->statistics(resVarAddr)->mobileVolumeWeightedMean(timeStepIndex, *mean);
}

//--------------------------------------------------------------------------------------------------
/// 
//--------------------------------------------------------------------------------------------------
std::pair<double, double> RigFlowDiagResults::injectorProducerPairFluxes(const std::string& injTracername, 
                                                                         const std::string& prodTracerName, 
                                                                         int timeStepIndex)
{
    calculateNativeResultsIfNotPreviouslyAttempted(timeStepIndex, RigFlowDiagResultAddress::PHASE_ALL);

    auto commPair =  m_injProdPairFluxCommunicationTimesteps[timeStepIndex][RigFlowDiagResultAddress::PHASE_ALL].find(std::make_pair(injTracername, prodTracerName));
    if (commPair != m_injProdPairFluxCommunicationTimesteps[timeStepIndex][RigFlowDiagResultAddress::PHASE_ALL].end())
    {
        return commPair->second;
    }
    else
    {
        return std::make_pair(0.0, 0.0);
    }
}

//--------------------------------------------------------------------------------------------------
/// 
//--------------------------------------------------------------------------------------------------
double RigFlowDiagResults::maxAbsPairFlux(int timeStepIndex)
{
    calculateNativeResultsIfNotPreviouslyAttempted(timeStepIndex, RigFlowDiagResultAddress::PHASE_ALL);
    double maxFlux = 0.0;

    for (const auto& commPair : m_injProdPairFluxCommunicationTimesteps[timeStepIndex][RigFlowDiagResultAddress::PHASE_ALL])
    {
        if (fabs(commPair.second.first)  > maxFlux ) maxFlux = fabs(commPair.second.first);
        if (fabs(commPair.second.second) > maxFlux ) maxFlux = fabs(commPair.second.second);
    }

    return maxFlux;
}

//--------------------------------------------------------------------------------------------------
/// 
//--------------------------------------------------------------------------------------------------
std::vector<int> RigFlowDiagResults::calculatedTimeSteps(RigFlowDiagResultAddress::PhaseSelection phaseSelection)
{
    std::vector<int> timestepIndices;
    for (size_t tsIdx = 0; tsIdx < m_timeStepCount; ++tsIdx)
    {
        auto it = m_hasAtemptedNativeResults[tsIdx].find(phaseSelection);
        if (it != m_hasAtemptedNativeResults[tsIdx].end() && it->second)
        {
            timestepIndices.push_back(static_cast<int>(tsIdx));
        }
    }

    return timestepIndices;
}

//--------------------------------------------------------------------------------------------------
/// 
//--------------------------------------------------------------------------------------------------
RigFlowDiagSolverInterface::FlowCharacteristicsResultFrame RigFlowDiagResults::flowCharacteristicsResults(int timeStepIndex,
                                                                                                          CellFilter cellSelection,
                                                                                                          const std::vector<QString>& tracerNames,
                                                                                                          double max_pv_fraction,
                                                                                                          double minCommunication,
                                                                                                          int maxTof)
{
    std::set<std::string> injectorNames;
    std::set<std::string> producerNames;

    for (const QString& tracerName : tracerNames)
    {
        RimFlowDiagSolution::TracerStatusType status = m_flowDiagSolution->tracerStatusInTimeStep(tracerName, timeStepIndex);
        if (status == RimFlowDiagSolution::INJECTOR)
        {
            injectorNames.insert(tracerName.toStdString());
        }
        else if (status == RimFlowDiagSolution::PRODUCER)
        {
            producerNames.insert(tracerName.toStdString());
        }
    }

    RigFlowDiagResultAddress injectorAddress(RIG_FLD_TOF_RESNAME, RigFlowDiagResultAddress::PHASE_ALL, injectorNames);
    RigFlowDiagResultAddress producerAddress(RIG_FLD_TOF_RESNAME, RigFlowDiagResultAddress::PHASE_ALL, producerNames);

    const std::vector<double>* allInjectorResults = resultValues(injectorAddress, timeStepIndex);
    const std::vector<double>* allProducerResults = resultValues(producerAddress, timeStepIndex);

    std::vector<double> injectorResults;
    std::vector<double> producerResults;
    std::vector<size_t> selectedCellIndices;

    if (cellSelection == CELLS_COMMUNICATION)
    {
        std::set<std::string> allTracers;
        allTracers.insert(injectorNames.begin(), injectorNames.end());
        allTracers.insert(producerNames.begin(), producerNames.end());

        RigFlowDiagResultAddress communicationAddress(RIG_FLD_COMMUNICATION_RESNAME, RigFlowDiagResultAddress::PHASE_ALL, allTracers);
        const std::vector<double>* communicationResult = resultValues(communicationAddress, timeStepIndex);

        for (size_t i = 0; i < communicationResult->size(); ++i)
        {
            if (communicationResult->at(i) != HUGE_VAL && communicationResult->at(i) >= minCommunication)
            {
                selectedCellIndices.push_back(i);
                if (allInjectorResults != nullptr) injectorResults.push_back(allInjectorResults->at(i));
                if (allProducerResults != nullptr) producerResults.push_back(allProducerResults->at(i));
            }
        }
    }
    else if (cellSelection == CELLS_FLOODED)
    {
        if (allInjectorResults != nullptr)
        {
            for (size_t i = 0; i < allInjectorResults->size(); ++i)
            {
                if (allInjectorResults->at(i) != HUGE_VAL && allInjectorResults->at(i) <= maxTof)
                {
                    selectedCellIndices.push_back(i);
                    injectorResults.push_back(allInjectorResults->at(i));
                    if (allProducerResults != nullptr)
                    {
                        producerResults.push_back(allProducerResults->at(i));
                    }
                    else
                    {
                        producerResults.push_back(0);
                    }
                }
            }
        }
    }
    else if (cellSelection == CELLS_DRAINED)
    {
        if (allProducerResults != nullptr)
        {
            for (size_t i = 0; i < allProducerResults->size(); ++i)
            {
                if (allProducerResults->at(i) != HUGE_VAL && allProducerResults->at(i) <= maxTof)
                {
                    selectedCellIndices.push_back(i);
                    producerResults.push_back(allProducerResults->at(i));
                    if (allInjectorResults != nullptr)
                    {
                        injectorResults.push_back(allInjectorResults->at(i));
                    }
                    else
                    {
                        injectorResults.push_back(0);
                    }
                }
            }
        }
    }
    else
    {
        if (allInjectorResults != nullptr) injectorResults = *allInjectorResults;
        if (allProducerResults != nullptr) producerResults = *allProducerResults;

        for (size_t i = 0; i < injectorResults.size(); ++i)
        {
            selectedCellIndices.push_back(i);
        }
    }

    return solverInterface()->calculateFlowCharacteristics(&injectorResults, &producerResults, selectedCellIndices, max_pv_fraction);
}

//--------------------------------------------------------------------------------------------------
/// 
//--------------------------------------------------------------------------------------------------
RigFlowDiagSolverInterface::FlowCharacteristicsResultFrame RigFlowDiagResults::flowCharacteristicsResults(int timeStepIndex,
                                                                                                          const std::vector<char>& visibleActiveCells,
                                                                                                          double max_pv_fraction)
{
    std::vector<QString> tracerNames = m_flowDiagSolution->tracerNames();

    std::set<std::string> injectorNames;
    std::set<std::string> producerNames;

    for (const QString& tracerName : tracerNames)
    {
        RimFlowDiagSolution::TracerStatusType status = m_flowDiagSolution->tracerStatusInTimeStep(tracerName, timeStepIndex);
        if (status == RimFlowDiagSolution::INJECTOR)
        {
            injectorNames.insert(tracerName.toStdString());
        }
        else if (status == RimFlowDiagSolution::PRODUCER)
        {
            producerNames.insert(tracerName.toStdString());
        }
    }

    RigFlowDiagResultAddress injectorAddress(RIG_FLD_TOF_RESNAME, RigFlowDiagResultAddress::PHASE_ALL, injectorNames);
    RigFlowDiagResultAddress producerAddress(RIG_FLD_TOF_RESNAME, RigFlowDiagResultAddress::PHASE_ALL, producerNames);

    const std::vector<double>* allInjectorResults = resultValues(injectorAddress, timeStepIndex);
    const std::vector<double>* allProducerResults = resultValues(producerAddress, timeStepIndex);

    std::vector<size_t> selectedCellIndices;
    std::vector<double> injectorResults;
    std::vector<double> producerResults;

    for (size_t i = 0; i < visibleActiveCells.size(); ++i)
    {
        if (visibleActiveCells[i])
        {
            selectedCellIndices.push_back(i);
            injectorResults.push_back(allInjectorResults->at(i));
            producerResults.push_back(allProducerResults->at(i));
        }
    }

    return solverInterface()->calculateFlowCharacteristics(&injectorResults, &producerResults, selectedCellIndices, max_pv_fraction);
}

//--------------------------------------------------------------------------------------------------
/// 
//--------------------------------------------------------------------------------------------------
RimFlowDiagSolution* RigFlowDiagResults::flowDiagSolution()
{
    { return m_flowDiagSolution; }
}