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334 lines
16 KiB
C++
334 lines
16 KiB
C++
/////////////////////////////////////////////////////////////////////////////////
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//
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// Copyright (C) 2018- Equinor ASA
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//
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// ResInsight is free software: you can redistribute it and/or modify
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// it under the terms of the GNU General Public License as published by
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// the Free Software Foundation, either version 3 of the License, or
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// (at your option) any later version.
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//
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// ResInsight is distributed in the hope that it will be useful, but WITHOUT ANY
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// WARRANTY; without even the implied warranty of MERCHANTABILITY or
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// FITNESS FOR A PARTICULAR PURPOSE.
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//
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// See the GNU General Public License at <http://www.gnu.org/licenses/gpl.html>
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// for more details.
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//
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/////////////////////////////////////////////////////////////////////////////////
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#include "RigEclipseContourMapProjection.h"
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#include "RigActiveCellInfo.h"
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#include "RigCaseCellResultsData.h"
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#include "RigCell.h"
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#include "RigCellGeometryTools.h"
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#include "RigContourMapCalculator.h"
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#include "RigContourMapGrid.h"
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#include "RigEclipseCaseData.h"
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#include "RigEclipseResultAddress.h"
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#include "RigHexIntersectionTools.h"
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#include "RigMainGrid.h"
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#include <algorithm>
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//--------------------------------------------------------------------------------------------------
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///
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//--------------------------------------------------------------------------------------------------
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RigEclipseContourMapProjection::RigEclipseContourMapProjection( const RigContourMapGrid& contourMapGrid,
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RigEclipseCaseData& eclipseCaseData,
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RigCaseCellResultsData& resultData )
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: RigContourMapProjection( contourMapGrid )
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, m_eclipseCaseData( eclipseCaseData )
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, m_resultData( resultData )
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, m_kLayers( 0u )
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, m_useActiveCellInfo( true )
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{
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m_mainGrid = m_eclipseCaseData.mainGrid();
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m_activeCellInfo = m_eclipseCaseData.activeCellInfo( RiaDefines::PorosityModelType::MATRIX_MODEL );
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m_kLayers = m_mainGrid->cellCountK();
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}
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//--------------------------------------------------------------------------------------------------
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///
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//--------------------------------------------------------------------------------------------------
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RigEclipseContourMapProjection::~RigEclipseContourMapProjection()
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{
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}
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//--------------------------------------------------------------------------------------------------
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///
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//--------------------------------------------------------------------------------------------------
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void RigEclipseContourMapProjection::generateAndSaveResults( const RigEclipseResultAddress& resultAddress,
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RigContourMapCalculator::ResultAggregationType resultAggregation,
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int timeStep )
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{
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std::tie( m_useActiveCellInfo, m_aggregatedResults ) =
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generateResults( *this, m_contourMapGrid, m_resultData, resultAddress, resultAggregation, timeStep );
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}
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//--------------------------------------------------------------------------------------------------
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///
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//--------------------------------------------------------------------------------------------------
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std::vector<double> RigEclipseContourMapProjection::generateResults( const RigEclipseResultAddress& resultAddress,
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RigContourMapCalculator::ResultAggregationType resultAggregation,
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int timeStep ) const
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{
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std::pair<bool, std::vector<double>> result =
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generateResults( *this, m_contourMapGrid, m_resultData, resultAddress, resultAggregation, timeStep );
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return result.second;
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}
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//--------------------------------------------------------------------------------------------------
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///
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//--------------------------------------------------------------------------------------------------
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std::pair<bool, std::vector<double>>
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RigEclipseContourMapProjection::generateResults( const RigEclipseContourMapProjection& contourMapProjection,
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const RigContourMapGrid& contourMapGrid,
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RigCaseCellResultsData& resultData,
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const RigEclipseResultAddress& resultAddress,
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RigContourMapCalculator::ResultAggregationType resultAggregation,
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int timeStep )
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{
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size_t nCells = contourMapProjection.numberOfCells();
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std::vector<double> aggregatedResults = std::vector<double>( nCells, std::numeric_limits<double>::infinity() );
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bool useActiveCellInfo = resultAddress.isValid() && resultData.hasResultEntry( resultAddress ) &&
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resultData.isUsingGlobalActiveIndex( resultAddress );
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auto isTernaryResult = []( const RigEclipseResultAddress& address ) -> bool
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{
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return address.resultCatType() == RiaDefines::ResultCatType::DYNAMIC_NATIVE &&
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( address.resultName().compare( RiaResultNames::ternarySaturationResultName(), Qt::CaseInsensitive ) == 0 );
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};
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if ( !isTernaryResult( resultAddress ) )
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{
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std::vector<double> gridResultValues;
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if ( RigContourMapCalculator::isColumnResult( resultAggregation ) )
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{
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resultData.ensureKnownResultLoaded( RigEclipseResultAddress( RiaDefines::ResultCatType::STATIC_NATIVE, "PORO" ) );
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resultData.ensureKnownResultLoaded( RigEclipseResultAddress( RiaDefines::ResultCatType::STATIC_NATIVE, "NTG" ) );
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resultData.ensureKnownResultLoaded( RigEclipseResultAddress( RiaDefines::ResultCatType::STATIC_NATIVE, "DZ" ) );
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if ( resultAggregation == RigContourMapCalculator::OIL_COLUMN || resultAggregation == RigContourMapCalculator::HYDROCARBON_COLUMN )
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{
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resultData.ensureKnownResultLoaded(
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RigEclipseResultAddress( RiaDefines::ResultCatType::DYNAMIC_NATIVE, RiaResultNames::soil() ) );
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}
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if ( resultAggregation == RigContourMapCalculator::GAS_COLUMN || resultAggregation == RigContourMapCalculator::HYDROCARBON_COLUMN )
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{
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resultData.ensureKnownResultLoaded(
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RigEclipseResultAddress( RiaDefines::ResultCatType::DYNAMIC_NATIVE, RiaResultNames::sgas() ) );
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}
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gridResultValues = calculateColumnResult( resultData, resultAggregation, timeStep );
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}
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else
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{
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// TODO: this was RimEclipseCellColors->hasStaticResult()
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if ( resultAddress.resultCatType() == RiaDefines::ResultCatType::STATIC_NATIVE && timeStep > 0 ) timeStep = 0;
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resultData.ensureKnownResultLoaded( resultAddress );
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// When loading a project file, grid calculator results are not computed the first time this function is
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// called. Must check if result is loaded. See RimReloadCaseTools::updateAll3dViews()
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if ( resultAddress.isValid() && resultData.hasResultEntry( resultAddress ) && resultData.isResultLoaded( resultAddress ) )
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{
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gridResultValues = resultData.cellScalarResults( resultAddress, timeStep );
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}
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}
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if ( !gridResultValues.empty() )
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{
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#pragma omp parallel for
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for ( int index = 0; index < static_cast<int>( nCells ); ++index )
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{
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cvf::Vec2ui ij = contourMapGrid.ijFromCellIndex( index );
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const std::vector<std::pair<size_t, double>>& matchingCells = contourMapProjection.cellsAtIJ( ij.x(), ij.y() );
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aggregatedResults[index] =
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RigContourMapCalculator::calculateValueInMapCell( contourMapProjection, matchingCells, gridResultValues, resultAggregation );
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}
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}
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}
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return { useActiveCellInfo, aggregatedResults };
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}
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std::vector<double> RigEclipseContourMapProjection::calculateColumnResult( RigContourMapCalculator::ResultAggregationType resultAggregation,
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int timeStep ) const
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{
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return calculateColumnResult( m_resultData, resultAggregation, timeStep );
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}
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//--------------------------------------------------------------------------------------------------
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///
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//--------------------------------------------------------------------------------------------------
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std::vector<double> RigEclipseContourMapProjection::calculateColumnResult( RigCaseCellResultsData& resultData,
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RigContourMapCalculator::ResultAggregationType resultAggregation,
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int timeStep )
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{
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bool hasPoroResult = resultData.hasResultEntry( RigEclipseResultAddress( RiaDefines::ResultCatType::STATIC_NATIVE, "PORO" ) );
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bool hasNtgResult = resultData.hasResultEntry( RigEclipseResultAddress( RiaDefines::ResultCatType::STATIC_NATIVE, "NTG" ) );
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bool hasDzResult = resultData.hasResultEntry( RigEclipseResultAddress( RiaDefines::ResultCatType::STATIC_NATIVE, "DZ" ) );
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if ( !( hasPoroResult && hasNtgResult && hasDzResult ) )
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{
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return std::vector<double>();
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}
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const std::vector<double>& poroResults =
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resultData.cellScalarResults( RigEclipseResultAddress( RiaDefines::ResultCatType::STATIC_NATIVE, "PORO" ), 0 );
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const std::vector<double>& ntgResults =
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resultData.cellScalarResults( RigEclipseResultAddress( RiaDefines::ResultCatType::STATIC_NATIVE, "NTG" ), 0 );
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const std::vector<double>& dzResults =
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resultData.cellScalarResults( RigEclipseResultAddress( RiaDefines::ResultCatType::STATIC_NATIVE, "DZ" ), 0 );
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CVF_ASSERT( poroResults.size() == ntgResults.size() && ntgResults.size() == dzResults.size() );
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std::vector<double> resultValues( poroResults.size(), 0.0 );
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if ( resultAggregation == RigContourMapCalculator::OIL_COLUMN || resultAggregation == RigContourMapCalculator::HYDROCARBON_COLUMN )
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{
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const std::vector<double>& soilResults =
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resultData.cellScalarResults( RigEclipseResultAddress( RiaDefines::ResultCatType::DYNAMIC_NATIVE, RiaResultNames::soil() ),
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timeStep );
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for ( size_t cellResultIdx = 0; cellResultIdx < resultValues.size(); ++cellResultIdx )
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{
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resultValues[cellResultIdx] = soilResults[cellResultIdx];
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}
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}
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if ( resultAggregation == RigContourMapCalculator::GAS_COLUMN || resultAggregation == RigContourMapCalculator::HYDROCARBON_COLUMN )
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{
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bool hasGasResult =
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resultData.hasResultEntry( RigEclipseResultAddress( RiaDefines::ResultCatType::DYNAMIC_NATIVE, RiaResultNames::sgas() ) );
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if ( hasGasResult )
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{
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const std::vector<double>& sgasResults =
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resultData.cellScalarResults( RigEclipseResultAddress( RiaDefines::ResultCatType::DYNAMIC_NATIVE, RiaResultNames::sgas() ),
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timeStep );
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for ( size_t cellResultIdx = 0; cellResultIdx < resultValues.size(); ++cellResultIdx )
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{
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resultValues[cellResultIdx] += sgasResults[cellResultIdx];
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}
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}
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}
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for ( size_t cellResultIdx = 0; cellResultIdx < resultValues.size(); ++cellResultIdx )
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{
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resultValues[cellResultIdx] *= poroResults[cellResultIdx] * ntgResults[cellResultIdx] * dzResults[cellResultIdx];
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}
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return resultValues;
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}
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//--------------------------------------------------------------------------------------------------
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///
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//--------------------------------------------------------------------------------------------------
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std::vector<size_t> RigEclipseContourMapProjection::findIntersectingCells( const cvf::BoundingBox& bbox ) const
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{
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return m_mainGrid->findIntersectingCells( bbox );
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}
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//--------------------------------------------------------------------------------------------------
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///
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//--------------------------------------------------------------------------------------------------
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size_t RigEclipseContourMapProjection::kLayer( size_t globalCellIdx ) const
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{
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const RigCell& cell = m_mainGrid->cell( globalCellIdx );
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size_t mainGridCellIdx = cell.mainGridCellIndex();
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size_t i, j, k;
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m_mainGrid->ijkFromCellIndex( mainGridCellIdx, &i, &j, &k );
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return k;
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}
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//--------------------------------------------------------------------------------------------------
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///
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//--------------------------------------------------------------------------------------------------
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size_t RigEclipseContourMapProjection::kLayers() const
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{
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return m_kLayers;
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}
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//--------------------------------------------------------------------------------------------------
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///
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//--------------------------------------------------------------------------------------------------
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double RigEclipseContourMapProjection::calculateOverlapVolume( size_t globalCellIdx, const cvf::BoundingBox& bbox ) const
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{
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std::array<cvf::Vec3d, 8> hexCorners;
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const RigCell& cell = m_mainGrid->cell( globalCellIdx );
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size_t localCellIdx = cell.gridLocalCellIndex();
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RigGridBase* localGrid = cell.hostGrid();
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localGrid->cellCornerVertices( localCellIdx, hexCorners.data() );
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cvf::BoundingBox overlapBBox;
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std::array<cvf::Vec3d, 8> overlapCorners;
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if ( RigCellGeometryTools::estimateHexOverlapWithBoundingBox( hexCorners, bbox, &overlapCorners, &overlapBBox ) )
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{
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double overlapVolume = RigCellGeometryTools::calculateCellVolume( overlapCorners );
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return overlapVolume;
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}
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return 0.0;
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}
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//--------------------------------------------------------------------------------------------------
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///
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//--------------------------------------------------------------------------------------------------
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double RigEclipseContourMapProjection::calculateRayLengthInCell( size_t globalCellIdx,
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const cvf::Vec3d& highestPoint,
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const cvf::Vec3d& lowestPoint ) const
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{
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std::array<cvf::Vec3d, 8> hexCorners;
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const RigCell& cell = m_mainGrid->cell( globalCellIdx );
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size_t localCellIdx = cell.gridLocalCellIndex();
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RigGridBase* localGrid = cell.hostGrid();
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localGrid->cellCornerVertices( localCellIdx, hexCorners.data() );
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std::vector<HexIntersectionInfo> intersections;
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if ( RigHexIntersectionTools::lineHexCellIntersection( highestPoint, lowestPoint, hexCorners.data(), 0, &intersections ) )
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{
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double lengthInCell = ( intersections.back().m_intersectionPoint - intersections.front().m_intersectionPoint ).length();
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return lengthInCell;
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}
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return 0.0;
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}
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//--------------------------------------------------------------------------------------------------
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///
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//--------------------------------------------------------------------------------------------------
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double RigEclipseContourMapProjection::getParameterWeightForCell( size_t cellResultIdx, const std::vector<double>& cellWeights ) const
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{
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if ( cellWeights.empty() ) return 1.0;
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double result = std::max( cellWeights[cellResultIdx], 0.0 );
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if ( result < 1.0e-6 )
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{
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result = 0.0;
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}
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return result;
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}
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//--------------------------------------------------------------------------------------------------
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///
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//--------------------------------------------------------------------------------------------------
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size_t RigEclipseContourMapProjection::gridResultIndex( size_t globalCellIdx ) const
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{
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if ( m_useActiveCellInfo ) return m_activeCellInfo->cellResultIndex( globalCellIdx );
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return globalCellIdx;
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}
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//--------------------------------------------------------------------------------------------------
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///
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//--------------------------------------------------------------------------------------------------
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std::vector<bool> RigEclipseContourMapProjection::getMapCellVisibility( int viewStepIndex,
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RigContourMapCalculator::ResultAggregationType resultAggregation )
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{
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return std::vector<bool>( numberOfCells(), true );
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}
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