ResInsight/ApplicationLibCode/GeoMech/GeoMechDataModel/RigFemPartResultCalculatorShearSlipIndicator.cpp

/////////////////////////////////////////////////////////////////////////////////
//
//  Copyright (C) 2020-     Equinor 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 "RigFemPartResultCalculatorShearSlipIndicator.h"

#include "RigFemPart.h"
#include "RigFemPartCollection.h"
#include "RigFemPartGrid.h"
#include "RigFemPartResultsCollection.h"
#include "RigFemResultAddress.h"
#include "RigFemScalarResultFrames.h"
#include "RigGeoMechWellLogExtractor.h"

#include "cafProgressInfo.h"

#include <QString>

//--------------------------------------------------------------------------------------------------
///
//--------------------------------------------------------------------------------------------------
RigFemPartResultCalculatorShearSlipIndicator::RigFemPartResultCalculatorShearSlipIndicator( RigFemPartResultsCollection& collection )
    : RigFemPartResultCalculator( collection )
{
}

//--------------------------------------------------------------------------------------------------
///
//--------------------------------------------------------------------------------------------------
RigFemPartResultCalculatorShearSlipIndicator::~RigFemPartResultCalculatorShearSlipIndicator()
{
}

//--------------------------------------------------------------------------------------------------
///
//--------------------------------------------------------------------------------------------------
bool RigFemPartResultCalculatorShearSlipIndicator::isMatching( const RigFemResultAddress& resVarAddr ) const
{
    return ( resVarAddr.fieldName == "ST" && resVarAddr.componentName == "DPN" );
}

//--------------------------------------------------------------------------------------------------
///
//--------------------------------------------------------------------------------------------------
RigFemScalarResultFrames*
    RigFemPartResultCalculatorShearSlipIndicator::calculate( int partIndex, const RigFemResultAddress& resVarAddr )
{
    CVF_ASSERT( isMatching( resVarAddr ) );

    caf::ProgressInfo frameCountProgress( m_resultCollection->frameCount() * 3, "" );
    frameCountProgress.setProgressDescription( "Calculating Shear Slip Indicator." );

    // Pore pressure
    frameCountProgress.setNextProgressIncrement( m_resultCollection->frameCount() );
    RigFemScalarResultFrames* porePressureDataFrames =
        m_resultCollection->findOrLoadScalarResult( partIndex,
                                                    RigFemResultAddress( resVarAddr.resultPosType, "POR-Bar", "" ) );
    frameCountProgress.incrementProgress();

    // Total vertical stress (ST.S33)
    frameCountProgress.setNextProgressIncrement( m_resultCollection->frameCount() );
    RigFemScalarResultFrames* stressDataFrames =
        m_resultCollection->findOrLoadScalarResult( partIndex,
                                                    RigFemResultAddress( resVarAddr.resultPosType, "ST", "S33" ) );
    frameCountProgress.incrementProgress();

    frameCountProgress.setNextProgressIncrement( m_resultCollection->frameCount() );

    RigFemScalarResultFrames* shearSlipIndicatorFrames =
        m_resultCollection->createScalarResult( partIndex, RigFemResultAddress( resVarAddr.resultPosType, "ST", "DPN" ) );

    const RigFemPart*     femPart     = m_resultCollection->parts()->part( partIndex );
    const RigFemPartGrid* femPartGrid = femPart->getOrCreateStructGrid();

    float inf = std::numeric_limits<float>::infinity();

    frameCountProgress.setNextProgressIncrement( 1u );

    int frameCount = stressDataFrames->frameCount();
    for ( int fIdx = 0; fIdx < frameCount; ++fIdx )
    {
        const std::vector<float>& porFrameData = porePressureDataFrames->frameData( fIdx );

        const std::vector<float>& stressFrameData = stressDataFrames->frameData( fIdx );

        std::vector<float>& shearSlipIndicatorFrameData = shearSlipIndicatorFrames->frameData( fIdx );

        size_t valCount = stressFrameData.size();
        shearSlipIndicatorFrameData.resize( valCount );

        int elementCount = femPart->elementCount();

#pragma omp parallel for
        for ( int elmIdx = 0; elmIdx < elementCount; ++elmIdx )
        {
            RigElementType elmType = femPart->elementType( elmIdx );

            int elmNodeCount = RigFemTypes::elementNodeCount( femPart->elementType( elmIdx ) );

            if ( femPart->isHexahedron( elmIdx ) )
            {
                for ( int elmNodIdx = 0; elmNodIdx < elmNodeCount; ++elmNodIdx )
                {
                    // Use hydrostatic pressure from cell centroid.
                    // Use centroid to avoid intra-element differences
                    cvf::Vec3d cellCentroid       = femPartGrid->cellCentroid( elmIdx );
                    double     cellCentroidTvdMSL = -cellCentroid.z();

                    double waterDensity = m_resultCollection->waterDensityShearSlipIndicator();
                    double cellCenterHydroStaticPressure =
                        RigGeoMechWellLogExtractor::hydroStaticPorePressureAtDepth( cellCentroidTvdMSL, waterDensity );

                    size_t elmNodResIdx = femPart->elementNodeResultIdx( elmIdx, elmNodIdx );
                    if ( elmNodResIdx < stressFrameData.size() )
                    {
                        // Pore pressure (unit: Bar)
                        float porePressureBar     = porFrameData[elmNodResIdx];
                        float totalVerticalStress = stressFrameData[elmNodResIdx];

                        float shearSlipIndicator = inf;
                        if ( porePressureBar != inf && totalVerticalStress - cellCenterHydroStaticPressure != 0.0 )
                        {
                            shearSlipIndicator = ( porePressureBar - cellCenterHydroStaticPressure ) /
                                                 ( totalVerticalStress - cellCenterHydroStaticPressure );
                        }

                        shearSlipIndicatorFrameData[elmNodResIdx] = shearSlipIndicator;
                    }
                }
            }
            else
            {
                for ( int elmNodIdx = 0; elmNodIdx < elmNodeCount; ++elmNodIdx )
                {
                    size_t elmNodResIdx = femPart->elementNodeResultIdx( elmIdx, elmNodIdx );
                    if ( elmNodResIdx < stressFrameData.size() )
                    {
                        shearSlipIndicatorFrameData[elmNodResIdx] = inf;
                    }
                }
            }
        }

        frameCountProgress.incrementProgress();
    }

    RigFemScalarResultFrames* requestedResultFrames = m_resultCollection->findOrLoadScalarResult( partIndex, resVarAddr );
    return requestedResultFrames;
}