Ejemplo n.º 1
0
//--------------------------------------------------------------------------------------------------
/// 
//--------------------------------------------------------------------------------------------------
void RigMainGrid::calculateFaults(const RigActiveCellInfo* activeCellInfo)
{
    m_faultsPrCellAcc = new RigFaultsPrCellAccumulator(m_cells.size());

    // Spread fault idx'es on the cells from the faults
    for (size_t fIdx = 0 ; fIdx < m_faults.size(); ++fIdx)
    {
        m_faults[fIdx]->accumulateFaultsPrCell(m_faultsPrCellAcc.p(), static_cast<int>(fIdx));
    }

    // Find the geometrical faults that is in addition: Has no user defined (eclipse) fault assigned.
    // Separate the grid faults that has an inactive cell as member

    RigFault* unNamedFault = new RigFault;
    unNamedFault->setName(RimDefines::undefinedGridFaultName());
    int unNamedFaultIdx = static_cast<int>(m_faults.size());
    m_faults.push_back(unNamedFault);

    RigFault* unNamedFaultWithInactive = new RigFault;
    unNamedFaultWithInactive->setName(RimDefines::undefinedGridFaultWithInactiveName());
    int unNamedFaultWithInactiveIdx = static_cast<int>(m_faults.size());
    m_faults.push_back(unNamedFaultWithInactive);

    const std::vector<cvf::Vec3d>& vxs = m_mainGrid->nodes();

    for (int gcIdx = 0 ; gcIdx < static_cast<int>(m_cells.size()); ++gcIdx)
    {
        if ( m_cells[gcIdx].isInvalid())
        {
            continue;
        }

        size_t neighborReservoirCellIdx;
        size_t neighborGridCellIdx;
        size_t i, j, k;
        RigGridBase* hostGrid = NULL; 
        bool firstNO_FAULTFaceForCell = true;
        bool isCellActive = true;

        for (char faceIdx = 0; faceIdx < 6; ++faceIdx)
        {
            cvf::StructGridInterface::FaceType face = cvf::StructGridInterface::FaceType(faceIdx);

            // For faces that has no used defined Fault assigned:

            if (m_faultsPrCellAcc->faultIdx(gcIdx, face) == RigFaultsPrCellAccumulator::NO_FAULT)
            {
                // Find neighbor cell
                if (firstNO_FAULTFaceForCell) // To avoid doing this for every face, and only when detecting a NO_FAULT
                {
                    hostGrid = m_cells[gcIdx].hostGrid();
                    hostGrid->ijkFromCellIndex(m_cells[gcIdx].gridLocalCellIndex(), &i,&j, &k);
                    isCellActive = activeCellInfo->isActive(gcIdx);

                    firstNO_FAULTFaceForCell = false;
                }

                if(!hostGrid->cellIJKNeighbor(i, j, k, face, &neighborGridCellIdx))
                {
                    continue;
                }

                neighborReservoirCellIdx = hostGrid->reservoirCellIndex(neighborGridCellIdx);
                if (m_cells[neighborReservoirCellIdx].isInvalid())
                {
                    continue;
                }

                bool isNeighborCellActive = activeCellInfo->isActive(neighborReservoirCellIdx);

                double tolerance = 1e-6;

                caf::SizeTArray4 faceIdxs;
                m_cells[gcIdx].faceIndices(face, &faceIdxs);
                caf::SizeTArray4 nbFaceIdxs;
                m_cells[neighborReservoirCellIdx].faceIndices(StructGridInterface::oppositeFace(face), &nbFaceIdxs);


                bool sharedFaceVertices = true;
                if (sharedFaceVertices && vxs[faceIdxs[0]].pointDistance(vxs[nbFaceIdxs[0]]) > tolerance ) sharedFaceVertices = false;
                if (sharedFaceVertices && vxs[faceIdxs[1]].pointDistance(vxs[nbFaceIdxs[3]]) > tolerance ) sharedFaceVertices = false;
                if (sharedFaceVertices && vxs[faceIdxs[2]].pointDistance(vxs[nbFaceIdxs[2]]) > tolerance ) sharedFaceVertices = false;
                if (sharedFaceVertices && vxs[faceIdxs[3]].pointDistance(vxs[nbFaceIdxs[1]]) > tolerance ) sharedFaceVertices = false;

                if (sharedFaceVertices)
                {
                    continue;
                }

                // To avoid doing this calculation for the opposite face 
                int faultIdx = unNamedFaultIdx;
                if (!(isCellActive && isNeighborCellActive)) faultIdx = unNamedFaultWithInactiveIdx;

                m_faultsPrCellAcc->setFaultIdx(gcIdx, face, faultIdx);
                m_faultsPrCellAcc->setFaultIdx(neighborReservoirCellIdx, StructGridInterface::oppositeFace(face), faultIdx);

                // Add as fault face only if the grid index is less than the neighbors

                if (static_cast<size_t>(gcIdx) < neighborReservoirCellIdx)
                {
                    RigFault::FaultFace ff(gcIdx, cvf::StructGridInterface::FaceType(faceIdx), neighborReservoirCellIdx);
                    if(isCellActive && isNeighborCellActive)
                    {
                        unNamedFault->faultFaces().push_back(ff);
                    }
                    else
                    {
                        unNamedFaultWithInactive->faultFaces().push_back(ff);
                    }
                }
                else
                {
                    CVF_FAIL_MSG("Found fault with global neighbor index less than the native index. "); // Should never occur. because we flag the opposite face in the faultsPrCellAcc
                }
            }
        }
    }

    distributeNNCsToFaults();
}
//--------------------------------------------------------------------------------------------------
/// 
//--------------------------------------------------------------------------------------------------
void RimEclipseStatisticsCaseEvaluator::evaluateForResults(const QList<ResSpec>& resultSpecification)
{
    CVF_ASSERT(m_destinationCase);
    
    // First build the destination result data structures to receive the statistics

    for (int i = 0; i < resultSpecification.size(); i++)
    {
        RifReaderInterface::PorosityModelResultType poroModel = resultSpecification[i].m_poroModel;
        RimDefines::ResultCatType resultType = resultSpecification[i].m_resType;
        QString resultName = resultSpecification[i].m_resVarName;

        size_t activeCellCount = m_destinationCase->activeCellInfo(poroModel)->reservoirActiveCellCount();
        RigCaseCellResultsData* destCellResultsData = m_destinationCase->results(poroModel);

        // Placeholder data used to be created here,
        // this is now moved to RimIdenticalGridCaseGroup::loadMainCaseAndActiveCellInfo()


        // Create new result data structures to contain the statistical values
        std::vector<QString> statisticalResultNames;

        statisticalResultNames.push_back(createResultNameMin(resultName));
        statisticalResultNames.push_back(createResultNameMax(resultName));
        statisticalResultNames.push_back(createResultNameMean(resultName));
        statisticalResultNames.push_back(createResultNameDev(resultName));
        statisticalResultNames.push_back(createResultNameRange(resultName));

        if (m_statisticsConfig.m_calculatePercentiles)
        {
            statisticalResultNames.push_back(createResultNamePVal(resultName, m_statisticsConfig.m_pMinPos));
            statisticalResultNames.push_back(createResultNamePVal(resultName, m_statisticsConfig.m_pMidPos));
            statisticalResultNames.push_back(createResultNamePVal(resultName, m_statisticsConfig.m_pMaxPos));
        }

        if (activeCellCount > 0)
        {
            for (size_t i = 0; i < statisticalResultNames.size(); ++i)
            {
                addNamedResult(destCellResultsData, resultType, statisticalResultNames[i], activeCellCount);
            }
        }
    }

    // Start the loop that calculates the statistics

    caf::ProgressInfo progressInfo(m_timeStepIndices.size(), "Computing Statistics");

    for (size_t timeIndicesIdx = 0; timeIndicesIdx < m_timeStepIndices.size(); timeIndicesIdx++)
    {
        size_t timeStepIdx = m_timeStepIndices[timeIndicesIdx];

        for (size_t gridIdx = 0; gridIdx < m_destinationCase->gridCount(); gridIdx++)
        {
            RigGridBase* grid = m_destinationCase->grid(gridIdx);

            for (int resSpecIdx = 0; resSpecIdx < resultSpecification.size(); resSpecIdx++)
            {
                RifReaderInterface::PorosityModelResultType poroModel = resultSpecification[resSpecIdx].m_poroModel;
                RimDefines::ResultCatType resultType = resultSpecification[resSpecIdx].m_resType;
                QString resultName = resultSpecification[resSpecIdx].m_resVarName;

                size_t activeCellCount = m_destinationCase->activeCellInfo(poroModel)->reservoirActiveCellCount();

                if (activeCellCount == 0) continue;

                RigCaseCellResultsData* destCellResultsData = m_destinationCase->results(poroModel);

                size_t dataAccessTimeStepIndex = timeStepIdx;

                // Always evaluate statistics once, and always use time step index zero
                if (resultType == RimDefines::STATIC_NATIVE)
                {
                    if (timeIndicesIdx > 0) continue;

                    dataAccessTimeStepIndex = 0;
                }

                // Build data access objects for source scalar results

                cvf::Collection<RigResultAccessor> sourceDataAccessList;
                for (size_t caseIdx = 0; caseIdx < m_sourceCases.size(); caseIdx++)
                {
                    RimEclipseCase* sourceCase = m_sourceCases.at(caseIdx);

                    // Trigger loading of dataset
                    sourceCase->results(poroModel)->findOrLoadScalarResultForTimeStep(resultType, resultName, dataAccessTimeStepIndex);

                    cvf::ref<RigResultAccessor> resultAccessor = RigResultAccessorFactory::createResultAccessor(sourceCase->reservoirData(), gridIdx, poroModel, dataAccessTimeStepIndex, resultName, resultType);
                    if (resultAccessor.notNull())
                    {
                        sourceDataAccessList.push_back(resultAccessor.p());
                    }
                }

                // Build data access objects for destination scalar results
                // Find the created result container, if any, and put its resultAccessor into the enum indexed destination collection

                cvf::Collection<RigResultModifier> destinationDataAccessList;
                std::vector<QString> statisticalResultNames(STAT_PARAM_COUNT);

                statisticalResultNames[MIN] = createResultNameMin(resultName);
                statisticalResultNames[MAX] = createResultNameMax(resultName);
                statisticalResultNames[RANGE] = createResultNameRange(resultName);
                statisticalResultNames[MEAN] = createResultNameMean(resultName);
                statisticalResultNames[STDEV] = createResultNameDev(resultName);
                statisticalResultNames[PMIN] = createResultNamePVal(resultName, m_statisticsConfig.m_pMinPos);
                statisticalResultNames[PMID] = createResultNamePVal(resultName, m_statisticsConfig.m_pMidPos);
                statisticalResultNames[PMAX] = createResultNamePVal(resultName, m_statisticsConfig.m_pMaxPos);

                for (size_t stIdx = 0; stIdx < statisticalResultNames.size(); ++stIdx)
                {
                    size_t scalarResultIndex = destCellResultsData->findScalarResultIndex(resultType, statisticalResultNames[stIdx]);

                    cvf::ref<RigResultModifier> resultModifier = RigResultModifierFactory::createResultModifier(m_destinationCase, grid->gridIndex(), poroModel, dataAccessTimeStepIndex, scalarResultIndex);
                    destinationDataAccessList.push_back(resultModifier.p());
                }

                 std::vector<double> statParams(STAT_PARAM_COUNT, HUGE_VAL);
                 std::vector<double> values(sourceDataAccessList.size(), HUGE_VAL);
                // Loop over the cells in the grid, get the case values, and calculate the cell statistics 
#pragma omp parallel for schedule(dynamic) firstprivate(statParams, values)
                for (int cellIdx = 0; static_cast<size_t>(cellIdx) < grid->cellCount(); cellIdx++)
                {

                    size_t reservoirCellIndex = grid->reservoirCellIndex(cellIdx);
                    if (m_destinationCase->activeCellInfo(poroModel)->isActive(reservoirCellIndex))
                    {
                        // Extract the cell values from each of the cases and assemble them into one vector

                        

                        bool foundAnyValidValues = false;
                        for (size_t caseIdx = 0; caseIdx < sourceDataAccessList.size(); caseIdx++)
                        {
                            double val = sourceDataAccessList.at(caseIdx)->cellScalar(cellIdx);
                            values[caseIdx] = val;

                            if (val != HUGE_VAL)
                            {
                                foundAnyValidValues = true;
                            }
                        }

                        // Do the real statistics calculations
                       

                        if (foundAnyValidValues)
                        {
                            RigStatisticsMath::calculateBasicStatistics(values, &statParams[MIN], &statParams[MAX], &statParams[RANGE], &statParams[MEAN], &statParams[STDEV]);

                            // Calculate percentiles
                            if (m_statisticsConfig.m_calculatePercentiles )
                            {
                                if (m_statisticsConfig.m_pValMethod == RimEclipseStatisticsCase::NEAREST_OBSERVATION)
                                {
                                    std::vector<double> pValPoss;
                                    pValPoss.push_back(m_statisticsConfig.m_pMinPos);
                                    pValPoss.push_back(m_statisticsConfig.m_pMidPos);
                                    pValPoss.push_back(m_statisticsConfig.m_pMaxPos);
                                    std::vector<double> pVals = RigStatisticsMath::calculateNearestRankPercentiles(values, pValPoss);
                                    statParams[PMIN] = pVals[0];
                                    statParams[PMID] = pVals[1];
                                    statParams[PMAX] = pVals[2];
                                }
                                else if (m_statisticsConfig.m_pValMethod == RimEclipseStatisticsCase::HISTOGRAM_ESTIMATED)
                                {
                                    std::vector<size_t> histogram;
                                    RigHistogramCalculator histCalc(statParams[MIN], statParams[MAX], 100, &histogram);
                                    histCalc.addData(values);
                                    statParams[PMIN] = histCalc.calculatePercentil(m_statisticsConfig.m_pMinPos);
                                    statParams[PMID] = histCalc.calculatePercentil(m_statisticsConfig.m_pMidPos);
                                    statParams[PMAX] = histCalc.calculatePercentil(m_statisticsConfig.m_pMaxPos);
                                }
                                else if (m_statisticsConfig.m_pValMethod == RimEclipseStatisticsCase::INTERPOLATED_OBSERVATION)
                                {
                                    std::vector<double> pValPoss;
                                    pValPoss.push_back(m_statisticsConfig.m_pMinPos);
                                    pValPoss.push_back(m_statisticsConfig.m_pMidPos);
                                    pValPoss.push_back(m_statisticsConfig.m_pMaxPos);
                                    std::vector<double> pVals = RigStatisticsMath::calculateInterpolatedPercentiles(values, pValPoss);
                                    statParams[PMIN] = pVals[0];
                                    statParams[PMID] = pVals[1];
                                    statParams[PMAX] = pVals[2];
                                }
                                else
                                {
                                    CVF_ASSERT(false);
                                }
                            }
                        }

                        // Set the results into the results data structures

                        for (size_t stIdx = 0; stIdx < statParams.size(); ++stIdx)
                        {
                            if (destinationDataAccessList[stIdx].notNull())
                            {
                                destinationDataAccessList[stIdx]->setCellScalar(cellIdx, statParams[stIdx]);
                            }
                        }
                    }
                }
            }
        }

        // When one time step is completed, free memory and clean up
        // Microsoft note: On Windows, the maximum number of files open at the same time is 512
        // http://msdn.microsoft.com/en-us/library/kdfaxaay%28vs.71%29.aspx

        for (size_t caseIdx = 0; caseIdx < m_sourceCases.size(); caseIdx++)
        {
            RimEclipseCase* eclipseCase = m_sourceCases.at(caseIdx);

            if (!eclipseCase->reservoirViews.size())
            {
                eclipseCase->results(RifReaderInterface::MATRIX_RESULTS)->cellResults()->freeAllocatedResultsData();
                eclipseCase->results(RifReaderInterface::FRACTURE_RESULTS)->cellResults()->freeAllocatedResultsData();
            }

            // Todo : These calls really do nothing right now the access actually closes automatically in ert i belive ...
            eclipseCase->results(RifReaderInterface::MATRIX_RESULTS)->readerInterface()->close();
            eclipseCase->results(RifReaderInterface::FRACTURE_RESULTS)->readerInterface()->close();
        }

        progressInfo.setProgress(timeIndicesIdx);
    }
}