///////////////////////////////////////////////////////////////////////////////// // // Copyright (C) 2011-2012 Statoil ASA, Ceetron AS // // 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 // for more details. // ///////////////////////////////////////////////////////////////////////////////// #include "RiaStdInclude.h" #include "RivReservoirViewPartMgr.h" #include "RivGridPartMgr.h" #include "RimReservoirView.h" #include "RigEclipseCase.h" #include "RigGridBase.h" #include "RigReservoirCellResults.h" #include "RigGridScalarDataAccess.h" //-------------------------------------------------------------------------------------------------- /// //-------------------------------------------------------------------------------------------------- RivReservoirViewPartMgr::RivReservoirViewPartMgr(RimReservoirView * resv) : m_reservoirView(resv) { m_scaleTransform = new cvf::Transform(); clearGeometryCache(); } //-------------------------------------------------------------------------------------------------- /// Clears the geometry cache for the given, and the dependent geometryTypes (from a visibility standpoint) //-------------------------------------------------------------------------------------------------- void RivReservoirViewPartMgr::scheduleGeometryRegen(ReservoirGeometryCacheType geometryType) { switch (geometryType) { case INACTIVE: clearGeometryCache(INACTIVE); clearGeometryCache(RANGE_FILTERED_INACTIVE); break; case RANGE_FILTERED_INACTIVE: clearGeometryCache(RANGE_FILTERED_INACTIVE); break; case ACTIVE: clearGeometryCache(ACTIVE); clearGeometryCache(ALL_WELL_CELLS); clearGeometryCache(VISIBLE_WELL_CELLS); clearGeometryCache(VISIBLE_WELL_FENCE_CELLS); clearGeometryCache(RANGE_FILTERED); clearGeometryCache(RANGE_FILTERED_WELL_CELLS); clearGeometryCache(VISIBLE_WELL_CELLS_OUTSIDE_RANGE_FILTER); clearGeometryCache(VISIBLE_WELL_FENCE_CELLS_OUTSIDE_RANGE_FILTER); clearGeometryCache(PROPERTY_FILTERED); clearGeometryCache(PROPERTY_FILTERED_WELL_CELLS); break; case ALL_WELL_CELLS: clearGeometryCache(ALL_WELL_CELLS); clearGeometryCache(VISIBLE_WELL_CELLS); clearGeometryCache(VISIBLE_WELL_FENCE_CELLS); clearGeometryCache(RANGE_FILTERED); clearGeometryCache(RANGE_FILTERED_WELL_CELLS); clearGeometryCache(VISIBLE_WELL_CELLS_OUTSIDE_RANGE_FILTER); clearGeometryCache(VISIBLE_WELL_FENCE_CELLS_OUTSIDE_RANGE_FILTER); clearGeometryCache(PROPERTY_FILTERED_WELL_CELLS); break; case VISIBLE_WELL_CELLS: clearGeometryCache(VISIBLE_WELL_CELLS); clearGeometryCache(VISIBLE_WELL_FENCE_CELLS); clearGeometryCache(VISIBLE_WELL_CELLS_OUTSIDE_RANGE_FILTER); clearGeometryCache(VISIBLE_WELL_FENCE_CELLS_OUTSIDE_RANGE_FILTER); clearGeometryCache(PROPERTY_FILTERED); clearGeometryCache(PROPERTY_FILTERED_WELL_CELLS); break; case VISIBLE_WELL_FENCE_CELLS: clearGeometryCache(VISIBLE_WELL_FENCE_CELLS); clearGeometryCache(VISIBLE_WELL_FENCE_CELLS_OUTSIDE_RANGE_FILTER); clearGeometryCache(PROPERTY_FILTERED_WELL_CELLS); break; case RANGE_FILTERED: clearGeometryCache(RANGE_FILTERED); clearGeometryCache(RANGE_FILTERED_INACTIVE); clearGeometryCache(RANGE_FILTERED_WELL_CELLS); clearGeometryCache(VISIBLE_WELL_CELLS_OUTSIDE_RANGE_FILTER); clearGeometryCache(VISIBLE_WELL_FENCE_CELLS_OUTSIDE_RANGE_FILTER); clearGeometryCache(PROPERTY_FILTERED); clearGeometryCache(PROPERTY_FILTERED_WELL_CELLS); break; case RANGE_FILTERED_WELL_CELLS: clearGeometryCache(RANGE_FILTERED_WELL_CELLS); clearGeometryCache(RANGE_FILTERED); clearGeometryCache(VISIBLE_WELL_CELLS_OUTSIDE_RANGE_FILTER); clearGeometryCache(VISIBLE_WELL_FENCE_CELLS_OUTSIDE_RANGE_FILTER); clearGeometryCache(PROPERTY_FILTERED_WELL_CELLS); break; case VISIBLE_WELL_CELLS_OUTSIDE_RANGE_FILTER: clearGeometryCache(VISIBLE_WELL_CELLS_OUTSIDE_RANGE_FILTER); clearGeometryCache(VISIBLE_WELL_FENCE_CELLS_OUTSIDE_RANGE_FILTER); clearGeometryCache(PROPERTY_FILTERED_WELL_CELLS); break; case VISIBLE_WELL_FENCE_CELLS_OUTSIDE_RANGE_FILTER: clearGeometryCache(VISIBLE_WELL_FENCE_CELLS_OUTSIDE_RANGE_FILTER); clearGeometryCache(PROPERTY_FILTERED_WELL_CELLS); break; case PROPERTY_FILTERED: clearGeometryCache(PROPERTY_FILTERED); clearGeometryCache(PROPERTY_FILTERED_WELL_CELLS); break; case PROPERTY_FILTERED_WELL_CELLS: clearGeometryCache(PROPERTY_FILTERED_WELL_CELLS); break; } } //-------------------------------------------------------------------------------------------------- /// //-------------------------------------------------------------------------------------------------- void RivReservoirViewPartMgr::clearGeometryCache(ReservoirGeometryCacheType geomType) { RigCaseData* eclipseCase = NULL; if (m_reservoirView != NULL && m_reservoirView->eclipseCase()) { eclipseCase = m_reservoirView->eclipseCase()->reservoirData(); } if (geomType == PROPERTY_FILTERED) { for (size_t i = 0; i < m_propFilteredGeometryFramesNeedsRegen.size(); ++i) { m_propFilteredGeometryFramesNeedsRegen[i] = true; if (m_propFilteredGeometryFrames[i].notNull()) { m_propFilteredGeometryFrames[i]->clearAndSetReservoir(eclipseCase); m_propFilteredGeometryFrames[i]->setTransform(m_scaleTransform.p()); } } } else if (geomType == PROPERTY_FILTERED_WELL_CELLS) { for (size_t i = 0; i < m_propFilteredWellGeometryFramesNeedsRegen.size(); ++i) { m_propFilteredWellGeometryFramesNeedsRegen[i] = true; if (m_propFilteredWellGeometryFrames[i].notNull()) { m_propFilteredWellGeometryFrames[i]->clearAndSetReservoir(eclipseCase); m_propFilteredWellGeometryFrames[i]->setTransform(m_scaleTransform.p()); } } } else { m_geometriesNeedsRegen[geomType] = true; m_geometries[geomType].clearAndSetReservoir(eclipseCase); m_geometries[geomType].setTransform(m_scaleTransform.p()); } } //-------------------------------------------------------------------------------------------------- /// //-------------------------------------------------------------------------------------------------- void RivReservoirViewPartMgr::clearGeometryCache() { clearGeometryCache(ACTIVE); clearGeometryCache(ALL_WELL_CELLS); clearGeometryCache(VISIBLE_WELL_CELLS); clearGeometryCache(VISIBLE_WELL_FENCE_CELLS); clearGeometryCache(INACTIVE); clearGeometryCache(RANGE_FILTERED); clearGeometryCache(RANGE_FILTERED_WELL_CELLS); clearGeometryCache(RANGE_FILTERED_INACTIVE); clearGeometryCache(VISIBLE_WELL_CELLS_OUTSIDE_RANGE_FILTER); clearGeometryCache(VISIBLE_WELL_FENCE_CELLS_OUTSIDE_RANGE_FILTER); clearGeometryCache(PROPERTY_FILTERED); clearGeometryCache(PROPERTY_FILTERED_WELL_CELLS); } //-------------------------------------------------------------------------------------------------- /// //-------------------------------------------------------------------------------------------------- void RivReservoirViewPartMgr::appendStaticGeometryPartsToModel(cvf::ModelBasicList* model, ReservoirGeometryCacheType geometryType, const std::vector& gridIndices) { if (m_geometriesNeedsRegen[geometryType]) { createGeometry( geometryType); } m_geometries[geometryType].appendPartsToModel(model, gridIndices); } //-------------------------------------------------------------------------------------------------- /// //-------------------------------------------------------------------------------------------------- void RivReservoirViewPartMgr::appendDynamicGeometryPartsToModel(cvf::ModelBasicList* model, ReservoirGeometryCacheType geometryType, size_t frameIndex, const std::vector& gridIndices) { if (geometryType == PROPERTY_FILTERED) { if (frameIndex >= m_propFilteredGeometryFramesNeedsRegen.size() || m_propFilteredGeometryFramesNeedsRegen[frameIndex]) { createPropertyFilteredGeometry(frameIndex); } m_propFilteredGeometryFrames[frameIndex]->appendPartsToModel(model, gridIndices); } else if (geometryType == PROPERTY_FILTERED_WELL_CELLS) { if (frameIndex >= m_propFilteredWellGeometryFramesNeedsRegen.size() || m_propFilteredWellGeometryFramesNeedsRegen[frameIndex]) { createPropertyFilteredWellGeometry(frameIndex); } m_propFilteredWellGeometryFrames[frameIndex]->appendPartsToModel(model, gridIndices); } } //-------------------------------------------------------------------------------------------------- /// //-------------------------------------------------------------------------------------------------- void RivReservoirViewPartMgr::createGeometry(ReservoirGeometryCacheType geometryType) { RigCaseData* res = m_reservoirView->eclipseCase()->reservoirData(); m_geometries[geometryType].clearAndSetReservoir(res); m_geometries[geometryType].setTransform(m_scaleTransform.p()); std::vector grids; res->allGrids(&grids); for (size_t i = 0; i < grids.size(); ++i) { cvf::ref cellVisibility = m_geometries[geometryType].cellVisibility(i); computeVisibility(cellVisibility.p(), geometryType, grids[i], i); m_geometries[geometryType].setCellVisibility(i, cellVisibility.p()); } m_geometriesNeedsRegen[geometryType] = false; } //-------------------------------------------------------------------------------------------------- /// //-------------------------------------------------------------------------------------------------- void RivReservoirViewPartMgr::computeVisibility(cvf::UByteArray* cellVisibility, ReservoirGeometryCacheType geometryType, RigGridBase* grid, size_t gridIdx) { RigCaseData* eclipseCase = m_reservoirView->eclipseCase()->reservoirData(); RigActiveCellInfo* activeCellInfo = m_reservoirView->currentActiveCellInfo(); switch (geometryType) { case ACTIVE: computeNativeVisibility(cellVisibility, grid, activeCellInfo, eclipseCase->wellCellsInGrid(gridIdx), false, false, true, m_reservoirView->showMainGrid() ); break; case ALL_WELL_CELLS: copyByteArray(cellVisibility, eclipseCase->wellCellsInGrid(gridIdx)); break; case VISIBLE_WELL_CELLS: { cvf::ref allWellCellsVisibility; if (m_geometriesNeedsRegen[ALL_WELL_CELLS]) createGeometry(ALL_WELL_CELLS); allWellCellsVisibility = m_geometries[ALL_WELL_CELLS].cellVisibility(gridIdx); m_reservoirView->calculateVisibleWellCellsIncFence(cellVisibility, grid); #pragma omp parallel for for (int cellIdx = 0; cellIdx < static_cast(cellVisibility->size()); ++cellIdx) { (*cellVisibility)[cellIdx] = (*allWellCellsVisibility)[cellIdx] && (*cellVisibility)[cellIdx]; } } break; case VISIBLE_WELL_FENCE_CELLS: { cvf::ref allWellCellsVisibility; if (m_geometriesNeedsRegen[ALL_WELL_CELLS]) createGeometry(ALL_WELL_CELLS); allWellCellsVisibility = m_geometries[ALL_WELL_CELLS].cellVisibility(gridIdx); m_reservoirView->calculateVisibleWellCellsIncFence(cellVisibility, grid); #pragma omp parallel for for (int cellIdx = 0; cellIdx < static_cast(cellVisibility->size()); ++cellIdx) { (*cellVisibility)[cellIdx] = !(*allWellCellsVisibility)[cellIdx] && (*cellVisibility)[cellIdx]; } } break; case INACTIVE: computeNativeVisibility(cellVisibility, grid, activeCellInfo, eclipseCase->wellCellsInGrid(gridIdx), m_reservoirView->showInvalidCells(), true, false, m_reservoirView->showMainGrid()); break; case RANGE_FILTERED: { cvf::ref nativeVisibility; if (m_geometriesNeedsRegen[ACTIVE]) createGeometry(ACTIVE); nativeVisibility = m_geometries[ACTIVE].cellVisibility(gridIdx); computeRangeVisibility(cellVisibility, grid, nativeVisibility.p(), m_reservoirView->rangeFilterCollection()); } break; case RANGE_FILTERED_INACTIVE: { cvf::ref nativeVisibility; if (m_geometriesNeedsRegen[INACTIVE]) createGeometry(INACTIVE); nativeVisibility = m_geometries[INACTIVE].cellVisibility(gridIdx); computeRangeVisibility(cellVisibility, grid, nativeVisibility.p(), m_reservoirView->rangeFilterCollection()); } break; case RANGE_FILTERED_WELL_CELLS: { cvf::ref nativeVisibility; if (m_geometriesNeedsRegen[ALL_WELL_CELLS]) createGeometry(ALL_WELL_CELLS); nativeVisibility = m_geometries[ALL_WELL_CELLS].cellVisibility(gridIdx); computeRangeVisibility(cellVisibility, grid, nativeVisibility.p(), m_reservoirView->rangeFilterCollection()); } break; case VISIBLE_WELL_CELLS_OUTSIDE_RANGE_FILTER: { cvf::ref visibleWellCells; cvf::ref rangeFilteredWellCells; if (m_geometriesNeedsRegen[VISIBLE_WELL_CELLS]) createGeometry(VISIBLE_WELL_CELLS); if (m_geometriesNeedsRegen[RANGE_FILTERED_WELL_CELLS]) createGeometry(RANGE_FILTERED_WELL_CELLS); visibleWellCells = m_geometries[VISIBLE_WELL_CELLS].cellVisibility(gridIdx); rangeFilteredWellCells = m_geometries[RANGE_FILTERED_WELL_CELLS].cellVisibility(gridIdx); cellVisibility->resize(visibleWellCells->size()); #pragma omp parallel for for (int cellIdx = 0; cellIdx < static_cast(cellVisibility->size()); ++cellIdx) { (*cellVisibility)[cellIdx] = (*visibleWellCells)[cellIdx] && !(*rangeFilteredWellCells)[cellIdx]; } } break; case VISIBLE_WELL_FENCE_CELLS_OUTSIDE_RANGE_FILTER: { cvf::ref visibleWellCells; cvf::ref rangeFilteredWellCells; if (m_geometriesNeedsRegen[VISIBLE_WELL_FENCE_CELLS]) createGeometry(VISIBLE_WELL_FENCE_CELLS); if (m_geometriesNeedsRegen[RANGE_FILTERED]) createGeometry(RANGE_FILTERED); visibleWellCells = m_geometries[VISIBLE_WELL_FENCE_CELLS].cellVisibility(gridIdx); rangeFilteredWellCells = m_geometries[RANGE_FILTERED].cellVisibility(gridIdx); cellVisibility->resize(visibleWellCells->size()); #pragma omp parallel for for (int cellIdx = 0; cellIdx < static_cast(cellVisibility->size()); ++cellIdx) { (*cellVisibility)[cellIdx] = (*visibleWellCells)[cellIdx] && !(*rangeFilteredWellCells)[cellIdx]; } } break; default: CVF_ASSERT(false); // Call special function for property filtered stuff break; } } //-------------------------------------------------------------------------------------------------- /// //-------------------------------------------------------------------------------------------------- void RivReservoirViewPartMgr::createPropertyFilteredGeometry(size_t frameIndex) { RigCaseData* res = m_reservoirView->eclipseCase()->reservoirData(); if ( frameIndex >= m_propFilteredGeometryFrames.size()) { m_propFilteredGeometryFrames.resize(frameIndex + 1); m_propFilteredGeometryFramesNeedsRegen.resize(frameIndex + 1, true); } if ( m_propFilteredGeometryFrames[frameIndex].isNull()) m_propFilteredGeometryFrames[frameIndex] = new RivReservoirPartMgr; m_propFilteredGeometryFrames[frameIndex]->clearAndSetReservoir(res); m_propFilteredGeometryFrames[frameIndex]->setTransform(m_scaleTransform.p()); std::vector grids; res->allGrids(&grids); bool hasActiveRangeFilters = m_reservoirView->rangeFilterCollection()->hasActiveFilters() || m_reservoirView->wellCollection()->hasVisibleWellCells(); for (size_t gIdx = 0; gIdx < grids.size(); ++gIdx) { cvf::ref cellVisibility = m_propFilteredGeometryFrames[frameIndex]->cellVisibility(gIdx); cvf::ref rangeVisibility; cvf::ref fenceVisibility; cvf::cref cellIsWellCellStatuses = res->wellCellsInGrid(gIdx); if (m_geometriesNeedsRegen[RANGE_FILTERED]) createGeometry(RANGE_FILTERED); if (m_geometriesNeedsRegen[VISIBLE_WELL_FENCE_CELLS_OUTSIDE_RANGE_FILTER]) createGeometry(VISIBLE_WELL_FENCE_CELLS_OUTSIDE_RANGE_FILTER); rangeVisibility = m_geometries[RANGE_FILTERED].cellVisibility(gIdx); fenceVisibility = m_geometries[VISIBLE_WELL_FENCE_CELLS_OUTSIDE_RANGE_FILTER].cellVisibility(gIdx); cellVisibility->resize(rangeVisibility->size()); #pragma omp parallel for for (int cellIdx = 0; cellIdx < static_cast(cellVisibility->size()); ++cellIdx) { (*cellVisibility)[cellIdx] = (!hasActiveRangeFilters && !(*cellIsWellCellStatuses)[cellIdx]) || (*rangeVisibility)[cellIdx] || (*fenceVisibility)[cellIdx]; } computePropertyVisibility(cellVisibility.p(), grids[gIdx], frameIndex, cellVisibility.p(), m_reservoirView->propertyFilterCollection()); m_propFilteredGeometryFrames[frameIndex]->setCellVisibility(gIdx, cellVisibility.p()); } m_propFilteredGeometryFramesNeedsRegen[frameIndex] = false; } //-------------------------------------------------------------------------------------------------- /// //-------------------------------------------------------------------------------------------------- void RivReservoirViewPartMgr::createPropertyFilteredWellGeometry(size_t frameIndex) { RigCaseData* res = m_reservoirView->eclipseCase()->reservoirData(); if ( frameIndex >= m_propFilteredWellGeometryFrames.size()) { m_propFilteredWellGeometryFrames.resize(frameIndex + 1); m_propFilteredWellGeometryFramesNeedsRegen.resize(frameIndex + 1, true); } if ( m_propFilteredWellGeometryFrames[frameIndex].isNull()) m_propFilteredWellGeometryFrames[frameIndex] = new RivReservoirPartMgr; m_propFilteredWellGeometryFrames[frameIndex]->clearAndSetReservoir(res); m_propFilteredWellGeometryFrames[frameIndex]->setTransform(m_scaleTransform.p()); std::vector grids; res->allGrids(&grids); bool hasActiveRangeFilters = m_reservoirView->rangeFilterCollection()->hasActiveFilters() || m_reservoirView->wellCollection()->hasVisibleWellCells(); for (size_t gIdx = 0; gIdx < grids.size(); ++gIdx) { cvf::ref cellVisibility = m_propFilteredWellGeometryFrames[frameIndex]->cellVisibility(gIdx); cvf::ref rangeVisibility; cvf::ref wellCellsOutsideVisibility; cvf::cref cellIsWellCellStatuses = res->wellCellsInGrid(gIdx); if (m_geometriesNeedsRegen[RANGE_FILTERED_WELL_CELLS]) createGeometry(RANGE_FILTERED_WELL_CELLS); rangeVisibility = m_geometries[RANGE_FILTERED_WELL_CELLS].cellVisibility(gIdx); if (m_geometriesNeedsRegen[VISIBLE_WELL_CELLS_OUTSIDE_RANGE_FILTER]) createGeometry(VISIBLE_WELL_CELLS_OUTSIDE_RANGE_FILTER); wellCellsOutsideVisibility = m_geometries[VISIBLE_WELL_CELLS_OUTSIDE_RANGE_FILTER].cellVisibility(gIdx); cellVisibility->resize(rangeVisibility->size()); #pragma omp parallel for for (int cellIdx = 0; cellIdx < static_cast(cellVisibility->size()); ++cellIdx) { (*cellVisibility)[cellIdx] = (!hasActiveRangeFilters && (*cellIsWellCellStatuses)[cellIdx]) || (*rangeVisibility)[cellIdx] || (*wellCellsOutsideVisibility)[cellIdx]; } computePropertyVisibility(cellVisibility.p(), grids[gIdx], frameIndex, cellVisibility.p(), m_reservoirView->propertyFilterCollection()); m_propFilteredWellGeometryFrames[frameIndex]->setCellVisibility(gIdx, cellVisibility.p()); } m_propFilteredWellGeometryFramesNeedsRegen[frameIndex] = false; } //-------------------------------------------------------------------------------------------------- /// Evaluate visibility based on cell state //-------------------------------------------------------------------------------------------------- void RivReservoirViewPartMgr::computeNativeVisibility(cvf::UByteArray* cellVisibility, const RigGridBase* grid, const RigActiveCellInfo* activeCellInfo, const cvf::UByteArray* cellIsInWellStatuses, bool invalidCellsIsVisible, bool inactiveCellsIsVisible, bool activeCellsIsVisible, bool mainGridIsVisible) { CVF_ASSERT(cellVisibility != NULL); CVF_ASSERT(grid != NULL); CVF_ASSERT(activeCellInfo != NULL); CVF_ASSERT(cellIsInWellStatuses != NULL); CVF_ASSERT(cellIsInWellStatuses->size() >= grid->cellCount()); cellVisibility->resize(grid->cellCount()); #pragma omp parallel for for (int cellIndex = 0; cellIndex < static_cast(grid->cellCount()); cellIndex++) { const RigCell& cell = grid->cell(cellIndex); size_t globalCellIndex = cell.mainGridCellIndex(); if ( !invalidCellsIsVisible && cell.isInvalid() || !inactiveCellsIsVisible && !activeCellInfo->isActive(globalCellIndex) || !activeCellsIsVisible && activeCellInfo->isActive(globalCellIndex) || mainGridIsVisible && (cell.subGrid() != NULL) || (*cellIsInWellStatuses)[cellIndex] ) { (*cellVisibility)[cellIndex] = false; } else { (*cellVisibility)[cellIndex] = true; } } } //-------------------------------------------------------------------------------------------------- /// Copy the data from source into destination. This is not trivial to do using cvf::Array ... /// using parallelized operator [] and not memcopy. Do not know what is faster. //-------------------------------------------------------------------------------------------------- void RivReservoirViewPartMgr::copyByteArray(cvf::UByteArray* destination, const cvf::UByteArray* source ) { CVF_ASSERT(destination != NULL); CVF_ASSERT(source != NULL); if (destination->size() != source->size()) { destination->resize(source->size()); } #pragma omp parallel for for (int cellIndex = 0; cellIndex < static_cast(source->size()); cellIndex++) { (*destination)[cellIndex] = (*source)[cellIndex]; } } //-------------------------------------------------------------------------------------------------- /// //-------------------------------------------------------------------------------------------------- void RivReservoirViewPartMgr::computeRangeVisibility(cvf::UByteArray* cellVisibility, const RigGridBase* grid, const cvf::UByteArray* nativeVisibility, const RimCellRangeFilterCollection* rangeFilterColl) { CVF_ASSERT(cellVisibility != NULL); CVF_ASSERT(nativeVisibility != NULL); CVF_ASSERT(rangeFilterColl != NULL); CVF_ASSERT(grid != NULL); CVF_ASSERT(nativeVisibility->size() == grid->cellCount()); if (rangeFilterColl->hasActiveFilters()) { if (cellVisibility != nativeVisibility) (*cellVisibility) = (*nativeVisibility); // Build range filter for current grid cvf::CellRangeFilter mainGridCellRangeFilter; rangeFilterColl->compoundCellRangeFilter(&mainGridCellRangeFilter); #pragma omp parallel for for (int cellIndex = 0; cellIndex < static_cast(grid->cellCount()); cellIndex++) { if ( (*nativeVisibility)[cellIndex] ) { const RigCell& cell = grid->cell(cellIndex); size_t mainGridCellIndex = cell.mainGridCellIndex(); size_t mainGridI; size_t mainGridJ; size_t mainGridK; grid->mainGrid()->ijkFromCellIndex(mainGridCellIndex, &mainGridI, &mainGridJ, &mainGridK); (*cellVisibility)[cellIndex] = !mainGridCellRangeFilter.isCellRejected(mainGridI, mainGridJ, mainGridK); } } } else { cellVisibility->resize(grid->cellCount()); cellVisibility->setAll(false); } } //-------------------------------------------------------------------------------------------------- /// //-------------------------------------------------------------------------------------------------- void RivReservoirViewPartMgr::computePropertyVisibility(cvf::UByteArray* cellVisibility, const RigGridBase* grid, size_t timeStepIndex, const cvf::UByteArray* rangeFilterVisibility, RimCellPropertyFilterCollection* propFilterColl) { CVF_ASSERT(cellVisibility != NULL); CVF_ASSERT(rangeFilterVisibility != NULL); CVF_ASSERT(propFilterColl != NULL); CVF_ASSERT(grid->cellCount() > 0); CVF_ASSERT(rangeFilterVisibility->size() == grid->cellCount()); // Copy if not equal if (cellVisibility != rangeFilterVisibility ) (*cellVisibility) = *rangeFilterVisibility; if (propFilterColl->hasActiveFilters()) { std::list< caf::PdmPointer< RimCellPropertyFilter > >::const_iterator pfIt; for (pfIt = propFilterColl->propertyFilters().begin(); pfIt != propFilterColl->propertyFilters().end(); ++pfIt) { if ((*pfIt)->active()&& (*pfIt)->resultDefinition->hasResult()) { const double lowerBound = (*pfIt)->lowerBound(); const double upperBound = (*pfIt)->upperBound(); size_t scalarResultIndex = (*pfIt)->resultDefinition->gridScalarIndex(); // Set time step to zero for static results if ((*pfIt)->resultDefinition()->hasStaticResult()) { timeStepIndex = 0; } const RimCellFilter::FilterModeType filterType = (*pfIt)->filterMode(); RifReaderInterface::PorosityModelResultType porosityModel = RigCaseCellResultsData::convertFromProjectModelPorosityModel((*pfIt)->resultDefinition()->porosityModel()); RigCaseData* eclipseCase = propFilterColl->reservoirView()->eclipseCase()->reservoirData(); cvf::ref dataAccessObject = eclipseCase->dataAccessObject(grid, porosityModel, timeStepIndex, scalarResultIndex); CVF_ASSERT(dataAccessObject.notNull()); #pragma omp parallel for schedule(dynamic) for (int cellIndex = 0; cellIndex < static_cast(grid->cellCount()); cellIndex++) { if ( (*cellVisibility)[cellIndex] ) { size_t resultValueIndex = cellIndex; double scalarValue = dataAccessObject->cellScalar(resultValueIndex); if (lowerBound <= scalarValue && scalarValue <= upperBound) { if (filterType == RimCellFilter::EXCLUDE) { (*cellVisibility)[cellIndex] = false; } } else { if (filterType == RimCellFilter::INCLUDE) { (*cellVisibility)[cellIndex] = false; } } } } } } } } //-------------------------------------------------------------------------------------------------- /// //-------------------------------------------------------------------------------------------------- void RivReservoirViewPartMgr::updateCellColor(ReservoirGeometryCacheType geometryType, size_t timeStepIndex, cvf::Color4f color) { if (geometryType == PROPERTY_FILTERED) { m_propFilteredGeometryFrames[timeStepIndex]->updateCellColor(color ); } else if (geometryType == PROPERTY_FILTERED_WELL_CELLS) { m_propFilteredWellGeometryFrames[timeStepIndex]->updateCellColor(color ); } else { m_geometries[geometryType].updateCellColor(color); } } //-------------------------------------------------------------------------------------------------- /// //-------------------------------------------------------------------------------------------------- void RivReservoirViewPartMgr::updateCellColor(ReservoirGeometryCacheType geometryType, cvf::Color4f color) { //CVF_ASSERT(geometryType != PROPERTY_FILTERED); //CVF_ASSERT(geometryType != PROPERTY_FILTERED_WELL_CELLS); updateCellColor(geometryType, 0 , color); } //-------------------------------------------------------------------------------------------------- /// //-------------------------------------------------------------------------------------------------- void RivReservoirViewPartMgr::updateCellResultColor(ReservoirGeometryCacheType geometryType, size_t timeStepIndex, RimResultSlot* cellResultSlot) { if (geometryType == PROPERTY_FILTERED) { m_propFilteredGeometryFrames[timeStepIndex]->updateCellResultColor(timeStepIndex, cellResultSlot); } else if (geometryType == PROPERTY_FILTERED_WELL_CELLS) { m_propFilteredWellGeometryFrames[timeStepIndex]->updateCellResultColor(timeStepIndex, cellResultSlot); } else { m_geometries[geometryType].updateCellResultColor(timeStepIndex, cellResultSlot); } } //-------------------------------------------------------------------------------------------------- /// //-------------------------------------------------------------------------------------------------- void RivReservoirViewPartMgr::updateCellEdgeResultColor(ReservoirGeometryCacheType geometryType, size_t timeStepIndex, RimResultSlot* cellResultSlot, RimCellEdgeResultSlot* cellEdgeResultSlot) { if (geometryType == PROPERTY_FILTERED) { m_propFilteredGeometryFrames[timeStepIndex]->updateCellEdgeResultColor( timeStepIndex, cellResultSlot, cellEdgeResultSlot ); } else if (geometryType == PROPERTY_FILTERED_WELL_CELLS) { m_propFilteredWellGeometryFrames[timeStepIndex]->updateCellEdgeResultColor( timeStepIndex, cellResultSlot, cellEdgeResultSlot ); } else { m_geometries[geometryType].updateCellEdgeResultColor(timeStepIndex, cellResultSlot, cellEdgeResultSlot ); } }