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ResInsight/ApplicationCode/ProjectDataModel/Completions/RimFracture.cpp

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/////////////////////////////////////////////////////////////////////////////////
//
// Copyright (C) 2017-2018 Statoil ASA
// Copyright (C) 2018- 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 "RimFracture.h"
#include "RiaApplication.h"
#include "RiaColorTables.h"
#include "RiaCompletionTypeCalculationScheduler.h"
#include "RiaEclipseUnitTools.h"
#include "RiaLogging.h"
#include "Riu3DMainWindowTools.h"
#include "RigMainGrid.h"
#include "Rim3dView.h"
#include "RimEclipseCase.h"
#include "RimEclipseCellColors.h"
#include "RimEclipseView.h"
#include "RimEllipseFractureTemplate.h"
#include "RimFractureContainment.h"
#include "RimFractureTemplate.h"
#include "RimFractureTemplateCollection.h"
#include "RimOilField.h"
#include "RimProject.h"
#include "RimReservoirCellResultsStorage.h"
#include "RimStimPlanColors.h"
#include "RimStimPlanFractureTemplate.h"
#include "RivWellFracturePartMgr.h"
#include "FractureCommands/RicNewEllipseFractureTemplateFeature.h"
#include "FractureCommands/RicNewStimPlanFractureTemplateFeature.h"
#include "cafHexGridIntersectionTools/cafHexGridIntersectionTools.h"
#include "cafPdmUiDoubleSliderEditor.h"
#include "cafPdmUiPushButtonEditor.h"
#include "cafPdmUiToolButtonEditor.h"
#include "cafPdmUiTreeOrdering.h"
#include "cvfBoundingBox.h"
#include "cvfGeometryTools.h"
#include "cvfMath.h"
#include "cvfMatrix4.h"
#include "cvfPlane.h"
#include <QMessageBox>
#include <QString>
#include <cmath>
CAF_PDM_XML_ABSTRACT_SOURCE_INIT( RimFracture, "Fracture" );
//--------------------------------------------------------------------------------------------------
///
//--------------------------------------------------------------------------------------------------
void setDefaultFractureColorResult()
{
RiaApplication* app = RiaApplication::instance();
RimProject* proj = app->project();
for ( RimEclipseCase* const eclCase : proj->eclipseCases() )
{
for ( Rim3dView* const view : eclCase->views() )
{
std::vector<RimStimPlanColors*> fractureColors;
view->descendantsIncludingThisOfType( fractureColors );
for ( RimStimPlanColors* const stimPlanColors : fractureColors )
{
stimPlanColors->setDefaultResultName();
}
}
}
}
//--------------------------------------------------------------------------------------------------
///
//--------------------------------------------------------------------------------------------------
RimFracture::RimFracture()
{
// clang-format off
CAF_PDM_InitObject("Fracture", "", "", "");
CAF_PDM_InitFieldNoDefault(&m_fractureTemplate, "FractureDef", "Fracture Template", "", "", "");
CAF_PDM_InitField(&m_editFractureTemplate, "EditTemplate", false, "Edit", "", "", "");
m_editFractureTemplate.uiCapability()->setUiEditorTypeName(caf::PdmUiToolButtonEditor::uiEditorTypeName());
m_editFractureTemplate.uiCapability()->setUiLabelPosition(caf::PdmUiItemInfo::HIDDEN);
CAF_PDM_InitField(&m_createEllipseFractureTemplate, "CreateEllipseTemplate", false, "No Fracture Templates Found.", "", "", "");
m_createEllipseFractureTemplate.uiCapability()->setUiEditorTypeName(caf::PdmUiPushButtonEditor::uiEditorTypeName());
m_createEllipseFractureTemplate.uiCapability()->setUiLabelPosition(caf::PdmUiItemInfo::TOP);
CAF_PDM_InitField(&m_createStimPlanFractureTemplate, "CreateStimPlanTemplate", false, "Create New Template?", "", "", "");
m_createStimPlanFractureTemplate.uiCapability()->setUiEditorTypeName(caf::PdmUiPushButtonEditor::uiEditorTypeName());
m_createStimPlanFractureTemplate.uiCapability()->setUiLabelPosition(caf::PdmUiItemInfo::TOP);
CAF_PDM_InitFieldNoDefault(&m_anchorPosition, "AnchorPosition", "Anchor Position", "", "", "");
m_anchorPosition.uiCapability()->setUiHidden(true);
m_anchorPosition.xmlCapability()->disableIO();
CAF_PDM_InitFieldNoDefault(&m_uiAnchorPosition, "ui_positionAtWellpath", "Fracture Position", "", "", "");
m_uiAnchorPosition.registerGetMethod(this, &RimFracture::fracturePositionForUi);
m_uiAnchorPosition.uiCapability()->setUiReadOnly(true);
m_uiAnchorPosition.xmlCapability()->disableIO();
CAF_PDM_InitField(&m_azimuth, "Azimuth", 0.0, "Azimuth", "", "", "");
m_azimuth.uiCapability()->setUiEditorTypeName(caf::PdmUiDoubleSliderEditor::uiEditorTypeName());
CAF_PDM_InitField(&m_perforationLength, "PerforationLength", 1.0, "Perforation Length", "", "", "");
CAF_PDM_InitField(&m_perforationEfficiency, "PerforationEfficiency", 1.0, "Perforation Efficiency", "", "", "");
m_perforationEfficiency.uiCapability()->setUiEditorTypeName(caf::PdmUiDoubleSliderEditor::uiEditorTypeName());
CAF_PDM_InitField(&m_wellDiameter, "WellDiameter", 0.216, "Well Diameter at Fracture", "", "", "");
CAF_PDM_InitField(&m_dip, "Dip", 0.0, "Dip", "", "", "");
CAF_PDM_InitField(&m_tilt, "Tilt", 0.0, "Tilt", "", "", "");
CAF_PDM_InitField(&m_fractureUnit, "FractureUnit", caf::AppEnum<RiaEclipseUnitTools::UnitSystem>(RiaEclipseUnitTools::UnitSystem::UNITS_METRIC), "Fracture Unit System", "", "", "");
m_fractureUnit.uiCapability()->setUiReadOnly(true);
CAF_PDM_InitField(&m_stimPlanTimeIndexToPlot, "TimeIndexToPlot", 0, "StimPlan Time Step", "", "", "");
CAF_PDM_InitFieldNoDefault(&m_uiWellPathAzimuth, "WellPathAzimuth", "Well Path Azimuth", "", "", "");
m_uiWellPathAzimuth.registerGetMethod(this, &RimFracture::wellAzimuthAtFracturePositionText);
m_uiWellPathAzimuth.uiCapability()->setUiReadOnly(true);
m_uiWellPathAzimuth.xmlCapability()->disableIO();
CAF_PDM_InitFieldNoDefault(&m_uiWellFractureAzimuthDiff, "WellFractureAzimuthDiff", "Azimuth Difference Between\nFracture and Well", "", "", "");
m_uiWellFractureAzimuthDiff.registerGetMethod(this, &RimFracture::wellFractureAzimuthDiffText);
m_uiWellFractureAzimuthDiff.uiCapability()->setUiReadOnly(true);
m_uiWellFractureAzimuthDiff.xmlCapability()->disableIO();
CAF_PDM_InitField(&m_wellFractureAzimuthAngleWarning, "WellFractureAzimithAngleWarning", QString("Difference is below 10 degrees. Consider longitudinal fracture"), "", "", "", "");
m_wellFractureAzimuthAngleWarning.uiCapability()->setUiReadOnly(true);
m_wellFractureAzimuthAngleWarning.xmlCapability()->disableIO();
m_fracturePartMgr = new RivWellFracturePartMgr(this);
// clang-format on
}
//--------------------------------------------------------------------------------------------------
///
//--------------------------------------------------------------------------------------------------
RimFracture::~RimFracture()
{
}
//--------------------------------------------------------------------------------------------------
///
//--------------------------------------------------------------------------------------------------
double RimFracture::perforationLength() const
{
return m_perforationLength();
}
//--------------------------------------------------------------------------------------------------
///
//--------------------------------------------------------------------------------------------------
double RimFracture::perforationEfficiency() const
{
return m_perforationEfficiency();
}
//--------------------------------------------------------------------------------------------------
///
//--------------------------------------------------------------------------------------------------
void RimFracture::setStimPlanTimeIndexToPlot( int timeIndex )
{
m_stimPlanTimeIndexToPlot = timeIndex;
}
//--------------------------------------------------------------------------------------------------
///
//--------------------------------------------------------------------------------------------------
std::vector<size_t> RimFracture::getPotentiallyFracturedCells( const RigMainGrid* mainGrid ) const
{
std::vector<size_t> cellindecies;
if ( !mainGrid ) return cellindecies;
cvf::BoundingBox fractureBBox = this->boundingBoxInDomainCoords();
mainGrid->findIntersectingCells( fractureBBox, &cellindecies );
return cellindecies;
}
//--------------------------------------------------------------------------------------------------
///
//--------------------------------------------------------------------------------------------------
void RimFracture::fieldChangedByUi( const caf::PdmFieldHandle* changedField, const QVariant& oldValue, const QVariant& newValue )
{
if ( changedField == &m_fractureTemplate )
{
if ( fractureUnit() != m_fractureTemplate->fractureTemplateUnit() )
{
QString fractureUnitText = RiaEclipseUnitTools::UnitSystemType::uiText( fractureUnit() );
QString warningText =
QString( "Using a fracture template defined in a different unit is not supported.\n\nPlease select a "
"fracture template of unit '%1'" )
.arg( fractureUnitText );
QMessageBox::warning( nullptr, "Fracture Template Selection", warningText );
PdmObjectHandle* prevValue = oldValue.value<caf::PdmPointer<PdmObjectHandle>>().rawPtr();
auto prevTemplate = dynamic_cast<RimFractureTemplate*>( prevValue );
m_fractureTemplate = prevTemplate;
}
setFractureTemplate( m_fractureTemplate );
setDefaultFractureColorResult();
}
else if ( changedField == &m_editFractureTemplate )
{
m_editFractureTemplate = false;
if ( m_fractureTemplate != nullptr )
{
Riu3DMainWindowTools::selectAsCurrentItem( m_fractureTemplate() );
}
}
else if ( changedField == &m_createEllipseFractureTemplate )
{
m_createEllipseFractureTemplate = false;
RicNewEllipseFractureTemplateFeature::createNewTemplateForFractureAndUpdate( this );
}
else if ( changedField == &m_createStimPlanFractureTemplate )
{
RicNewStimPlanFractureTemplateFeature::createNewTemplateForFractureAndUpdate( this );
}
if ( changedField == &m_azimuth || changedField == &m_fractureTemplate ||
changedField == &m_stimPlanTimeIndexToPlot || changedField == this->objectToggleField() ||
changedField == &m_dip || changedField == &m_tilt || changedField == &m_perforationLength )
{
clearCachedNonDarcyProperties();
RimEclipseCase* eclipseCase = nullptr;
this->firstAncestorOrThisOfType( eclipseCase );
if ( eclipseCase )
{
RiaCompletionTypeCalculationScheduler::instance()->scheduleRecalculateCompletionTypeAndRedrawAllViews(
eclipseCase );
}
else
{
RiaCompletionTypeCalculationScheduler::instance()->scheduleRecalculateCompletionTypeAndRedrawAllViews();
}
RimProject::current()->scheduleCreateDisplayModelAndRedrawAllViews();
}
}
//--------------------------------------------------------------------------------------------------
///
//--------------------------------------------------------------------------------------------------
cvf::Vec3d RimFracture::fracturePosition() const
{
return m_anchorPosition;
}
//--------------------------------------------------------------------------------------------------
///
//--------------------------------------------------------------------------------------------------
const NonDarcyData& RimFracture::nonDarcyProperties() const
{
CVF_ASSERT( !m_cachedFractureProperties.isDirty() );
return m_cachedFractureProperties;
}
//--------------------------------------------------------------------------------------------------
///
//--------------------------------------------------------------------------------------------------
void RimFracture::ensureValidNonDarcyProperties()
{
if ( m_cachedFractureProperties.isDirty() )
{
NonDarcyData props;
if ( m_fractureTemplate )
{
props.width = m_fractureTemplate->computeFractureWidth( this );
props.conductivity = m_fractureTemplate->computeKh( this );
props.dFactor = m_fractureTemplate->computeDFactor( this );
props.effectivePermeability = m_fractureTemplate->computeEffectivePermeability( this );
props.eqWellRadius = m_fractureTemplate->computeWellRadiusForDFactorCalculation( this );
props.betaFactor = m_fractureTemplate->getOrComputeBetaFactor( this );
props.isDataDirty = false;
}
m_cachedFractureProperties = props;
}
}
//--------------------------------------------------------------------------------------------------
///
//--------------------------------------------------------------------------------------------------
void RimFracture::clearCachedNonDarcyProperties()
{
m_cachedFractureProperties = NonDarcyData();
}
//--------------------------------------------------------------------------------------------------
///
//--------------------------------------------------------------------------------------------------
RiaDefines::WellPathComponentType RimFracture::componentType() const
{
return RiaDefines::WellPathComponentType::FRACTURE;
}
//--------------------------------------------------------------------------------------------------
///
//--------------------------------------------------------------------------------------------------
QString RimFracture::componentLabel() const
{
return name();
}
//--------------------------------------------------------------------------------------------------
///
//--------------------------------------------------------------------------------------------------
QString RimFracture::componentTypeLabel() const
{
return "Fracture";
}
//--------------------------------------------------------------------------------------------------
///
//--------------------------------------------------------------------------------------------------
cvf::Color3f RimFracture::defaultComponentColor() const
{
return RiaColorTables::wellPathComponentColors()[componentType()];
}
//--------------------------------------------------------------------------------------------------
///
//--------------------------------------------------------------------------------------------------
double RimFracture::startMD() const
{
if ( fractureTemplate()->orientationType() == RimFractureTemplate::ALONG_WELL_PATH )
{
return fractureMD() - 0.5 * perforationLength();
}
else
{
return fractureMD();
}
}
//--------------------------------------------------------------------------------------------------
///
//--------------------------------------------------------------------------------------------------
double RimFracture::endMD() const
{
if ( fractureTemplate()->orientationType() == RimFractureTemplate::ALONG_WELL_PATH )
{
return startMD() + perforationLength();
}
else
{
return startMD() + fractureTemplate()->computeFractureWidth( this );
}
}
//--------------------------------------------------------------------------------------------------
/// https://stackoverflow.com/a/52432897
//--------------------------------------------------------------------------------------------------
double getAbsoluteDiff2Angles( const double x, const double y, const double c )
{
// c can be PI (for radians) or 180.0 (for degrees);
return c - fabs( fmod( fabs( x - y ), 2 * c ) - c );
}
//--------------------------------------------------------------------------------------------------
///
//--------------------------------------------------------------------------------------------------
double RimFracture::wellFractureAzimuthDiff() const
{
// Compute the relative difference between two lines
// See https://github.com/OPM/ResInsight/issues/5899
double angle1 = wellAzimuthAtFracturePosition();
double angle2 = m_azimuth;
double diffDegrees = getAbsoluteDiff2Angles( angle1, angle2, 180.0 );
double smallesDiffDegrees = std::min( 180.0 - diffDegrees, diffDegrees );
return smallesDiffDegrees;
}
//--------------------------------------------------------------------------------------------------
///
//--------------------------------------------------------------------------------------------------
QString RimFracture::wellFractureAzimuthDiffText() const
{
double wellDifference = wellFractureAzimuthDiff();
return QString::number( wellDifference, 'f', 2 );
}
//--------------------------------------------------------------------------------------------------
///
//--------------------------------------------------------------------------------------------------
QString RimFracture::wellAzimuthAtFracturePositionText() const
{
double wellAzimuth = wellAzimuthAtFracturePosition();
return QString::number( wellAzimuth, 'f', 2 );
}
//--------------------------------------------------------------------------------------------------
///
//--------------------------------------------------------------------------------------------------
cvf::BoundingBox RimFracture::boundingBoxInDomainCoords() const
{
std::vector<cvf::Vec3f> nodeCoordVec;
std::vector<cvf::uint> triangleIndices;
this->triangleGeometry( &triangleIndices, &nodeCoordVec );
cvf::BoundingBox fractureBBox;
for ( const auto& nodeCoord : nodeCoordVec )
fractureBBox.add( nodeCoord );
return fractureBBox;
}
//--------------------------------------------------------------------------------------------------
///
//--------------------------------------------------------------------------------------------------
double RimFracture::wellRadius() const
{
if ( m_fractureUnit == RiaEclipseUnitTools::UnitSystem::UNITS_METRIC )
{
return m_wellDiameter / 2.0;
}
else if ( m_fractureUnit == RiaEclipseUnitTools::UnitSystem::UNITS_FIELD )
{
return RiaEclipseUnitTools::inchToFeet( m_wellDiameter / 2.0 );
}
return cvf::UNDEFINED_DOUBLE;
}
//--------------------------------------------------------------------------------------------------
///
//--------------------------------------------------------------------------------------------------
cvf::Vec3d RimFracture::anchorPosition() const
{
return m_anchorPosition();
}
//--------------------------------------------------------------------------------------------------
///
//--------------------------------------------------------------------------------------------------
cvf::Mat4d RimFracture::transformMatrix() const
{
cvf::Vec3d center = anchorPosition();
// Dip (in XY plane)
cvf::Mat4d dipRotation = cvf::Mat4d::fromRotation( cvf::Vec3d::Z_AXIS, cvf::Math::toRadians( m_dip() ) );
// Dip (out of XY plane)
cvf::Mat4d tiltRotation = cvf::Mat4d::fromRotation( cvf::Vec3d::X_AXIS, cvf::Math::toRadians( m_tilt() ) );
// Ellipsis geometry is produced in XY-plane, rotate 90 deg around X to get zero azimuth along Y
cvf::Mat4d rotationFromTesselator = cvf::Mat4d::fromRotation( cvf::Vec3d::X_AXIS, cvf::Math::toRadians( 90.0f ) );
// Azimuth rotation
cvf::Mat4d azimuthRotation = cvf::Mat4d::fromRotation( cvf::Vec3d::Z_AXIS, cvf::Math::toRadians( -m_azimuth() - 90 ) );
cvf::Mat4d m = azimuthRotation * rotationFromTesselator * dipRotation * tiltRotation;
m.setTranslation( center );
return m;
}
//--------------------------------------------------------------------------------------------------
///
//--------------------------------------------------------------------------------------------------
double RimFracture::dip() const
{
return m_dip();
}
//--------------------------------------------------------------------------------------------------
///
//--------------------------------------------------------------------------------------------------
double RimFracture::tilt() const
{
return m_tilt();
}
//--------------------------------------------------------------------------------------------------
///
//--------------------------------------------------------------------------------------------------
void RimFracture::setFractureTemplateNoUpdate( RimFractureTemplate* fractureTemplate )
{
if ( fractureTemplate && fractureTemplate->fractureTemplateUnit() != fractureUnit() )
{
QString fractureUnitText = RiaEclipseUnitTools::UnitSystemType::uiText( fractureUnit() );
QString warningText =
QString( "Using a fracture template defined in a different unit is not supported.\n\nPlease select a "
"fracture template of unit '%1'" )
.arg( fractureUnitText );
QMessageBox::warning( nullptr, "Fracture Template Selection", warningText );
return;
}
m_fractureTemplate = fractureTemplate;
}
//--------------------------------------------------------------------------------------------------
///
//--------------------------------------------------------------------------------------------------
void RimFracture::triangleGeometry( std::vector<cvf::uint>* triangleIndices, std::vector<cvf::Vec3f>* nodeCoords ) const
{
RimFractureTemplate* fractureDef = fractureTemplate();
if ( fractureDef )
{
fractureDef->fractureTriangleGeometry( nodeCoords, triangleIndices );
}
cvf::Mat4d m = transformMatrix();
for ( cvf::Vec3f& v : *nodeCoords )
{
cvf::Vec3d vd( v );
vd.transformPoint( m );
v = cvf::Vec3f( vd );
}
}
//--------------------------------------------------------------------------------------------------
///
//--------------------------------------------------------------------------------------------------
cvf::Vec3d RimFracture::fracturePositionForUi() const
{
cvf::Vec3d v = m_anchorPosition;
v.z() = -v.z();
return v;
}
//--------------------------------------------------------------------------------------------------
///
//--------------------------------------------------------------------------------------------------
QList<caf::PdmOptionItemInfo> RimFracture::calculateValueOptions( const caf::PdmFieldHandle* fieldNeedingOptions,
bool* useOptionsOnly )
{
QList<caf::PdmOptionItemInfo> options;
RimProject* proj = RimProject::current();
CVF_ASSERT( proj );
if ( fieldNeedingOptions == &m_fractureTemplate )
{
RimOilField* oilField = proj->activeOilField();
if ( oilField && oilField->fractureDefinitionCollection() )
{
RimFractureTemplateCollection* fracDefColl = oilField->fractureDefinitionCollection();
for ( RimFractureTemplate* fracDef : fracDefColl->fractureTemplates() )
{
QString displayText = fracDef->nameAndUnit();
if ( fracDef->fractureTemplateUnit() != fractureUnit() )
{
displayText += " (non-matching unit)";
}
options.push_back( caf::PdmOptionItemInfo( displayText, fracDef ) );
}
}
}
else if ( fieldNeedingOptions == &m_stimPlanTimeIndexToPlot )
{
if ( fractureTemplate() )
{
RimFractureTemplate* fracTemplate = fractureTemplate();
if ( dynamic_cast<RimStimPlanFractureTemplate*>( fracTemplate ) )
{
RimStimPlanFractureTemplate* fracTemplateStimPlan =
dynamic_cast<RimStimPlanFractureTemplate*>( fracTemplate );
std::vector<double> timeValues = fracTemplateStimPlan->timeSteps();
int index = 0;
for ( double value : timeValues )
{
options.push_back( caf::PdmOptionItemInfo( QString::number( value ), index ) );
index++;
}
}
}
}
return options;
}
//--------------------------------------------------------------------------------------------------
///
//--------------------------------------------------------------------------------------------------
void RimFracture::defineUiOrdering( QString uiConfigName, caf::PdmUiOrdering& uiOrdering )
{
if ( m_fractureUnit() == RiaEclipseUnitTools::UnitSystem::UNITS_METRIC )
{
m_wellDiameter.uiCapability()->setUiName( "Well Diameter [m]" );
m_perforationLength.uiCapability()->setUiName( "Perforation Length [m]" );
}
else if ( m_fractureUnit() == RiaEclipseUnitTools::UnitSystem::UNITS_FIELD )
{
m_wellDiameter.uiCapability()->setUiName( "Well Diameter [inches]" );
m_perforationLength.uiCapability()->setUiName( "Perforation Length [ft]" );
}
if ( fractureTemplate() )
{
if ( fractureTemplate()->orientationType() == RimFractureTemplate::ALONG_WELL_PATH ||
fractureTemplate()->orientationType() == RimFractureTemplate::TRANSVERSE_WELL_PATH )
{
m_uiWellPathAzimuth.uiCapability()->setUiHidden( true );
m_uiWellFractureAzimuthDiff.uiCapability()->setUiHidden( true );
m_wellFractureAzimuthAngleWarning.uiCapability()->setUiHidden( true );
}
else if ( fractureTemplate()->orientationType() == RimFractureTemplate::AZIMUTH )
{
m_uiWellPathAzimuth.uiCapability()->setUiHidden( false );
m_uiWellFractureAzimuthDiff.uiCapability()->setUiHidden( false );
if ( wellFractureAzimuthDiff() < 10 || ( wellFractureAzimuthDiff() > 170 && wellFractureAzimuthDiff() < 190 ) ||
wellFractureAzimuthDiff() > 350 )
{
m_wellFractureAzimuthAngleWarning.uiCapability()->setUiHidden( false );
}
else
{
m_wellFractureAzimuthAngleWarning.uiCapability()->setUiHidden( true );
}
}
if ( fractureTemplate()->orientationType() == RimFractureTemplate::ALONG_WELL_PATH ||
fractureTemplate()->orientationType() == RimFractureTemplate::TRANSVERSE_WELL_PATH )
{
m_azimuth.uiCapability()->setUiReadOnly( true );
}
else if ( fractureTemplate()->orientationType() == RimFractureTemplate::AZIMUTH )
{
m_azimuth.uiCapability()->setUiReadOnly( false );
}
if ( fractureTemplate()->orientationType() == RimFractureTemplate::ALONG_WELL_PATH )
{
m_perforationEfficiency.uiCapability()->setUiHidden( false );
m_perforationLength.uiCapability()->setUiHidden( false );
}
else
{
m_perforationEfficiency.uiCapability()->setUiHidden( true );
m_perforationLength.uiCapability()->setUiHidden( true );
}
if ( fractureTemplate()->conductivityType() == RimFractureTemplate::FINITE_CONDUCTIVITY )
{
m_wellDiameter.uiCapability()->setUiHidden( false );
}
else if ( fractureTemplate()->conductivityType() == RimFractureTemplate::INFINITE_CONDUCTIVITY )
{
m_wellDiameter.uiCapability()->setUiHidden( true );
}
RimFractureTemplate* fracTemplate = fractureTemplate();
if ( dynamic_cast<RimStimPlanFractureTemplate*>( fracTemplate ) )
{
m_stimPlanTimeIndexToPlot.uiCapability()->setUiHidden( false );
m_stimPlanTimeIndexToPlot.uiCapability()->setUiReadOnly( true );
}
else
{
m_stimPlanTimeIndexToPlot.uiCapability()->setUiHidden( true );
}
}
else
{
m_stimPlanTimeIndexToPlot.uiCapability()->setUiHidden( true );
}
}
//--------------------------------------------------------------------------------------------------
///
//--------------------------------------------------------------------------------------------------
void RimFracture::defineEditorAttribute( const caf::PdmFieldHandle* field,
QString uiConfigName,
caf::PdmUiEditorAttribute* attribute )
{
if ( field == &m_azimuth )
{
caf::PdmUiDoubleSliderEditorAttribute* myAttr = dynamic_cast<caf::PdmUiDoubleSliderEditorAttribute*>( attribute );
if ( myAttr )
{
myAttr->m_minimum = 0;
myAttr->m_maximum = 360;
}
}
if ( field == &m_perforationEfficiency )
{
caf::PdmUiDoubleSliderEditorAttribute* myAttr = dynamic_cast<caf::PdmUiDoubleSliderEditorAttribute*>( attribute );
if ( myAttr )
{
myAttr->m_minimum = 0;
myAttr->m_maximum = 1.0;
}
}
if ( field == &m_createEllipseFractureTemplate )
{
auto myAttr = dynamic_cast<caf::PdmUiPushButtonEditorAttribute*>( attribute );
myAttr->m_buttonText = "Ellipse Template";
}
if ( field == &m_createStimPlanFractureTemplate )
{
auto myAttr = dynamic_cast<caf::PdmUiPushButtonEditorAttribute*>( attribute );
myAttr->m_buttonText = "StimPlan Template";
}
}
//--------------------------------------------------------------------------------------------------
///
//--------------------------------------------------------------------------------------------------
void RimFracture::setAnchorPosition( const cvf::Vec3d& pos )
{
m_anchorPosition = pos;
}
//--------------------------------------------------------------------------------------------------
///
//--------------------------------------------------------------------------------------------------
RiaEclipseUnitTools::UnitSystem RimFracture::fractureUnit() const
{
return m_fractureUnit();
}
//--------------------------------------------------------------------------------------------------
///
//--------------------------------------------------------------------------------------------------
void RimFracture::setFractureUnit( RiaEclipseUnitTools::UnitSystem unitSystem )
{
m_fractureUnit = unitSystem;
}
//--------------------------------------------------------------------------------------------------
///
//--------------------------------------------------------------------------------------------------
bool RimFracture::isEclipseCellOpenForFlow( const RigMainGrid* mainGrid,
const std::set<size_t>& reservoirCellIndicesOpenForFlow,
size_t globalCellIndex ) const
{
CVF_ASSERT( fractureTemplate() );
if ( !fractureTemplate()->fractureContainment()->isEnabled() ) return true;
return fractureTemplate()->fractureContainment()->isEclipseCellOpenForFlow( mainGrid,
globalCellIndex,
reservoirCellIndicesOpenForFlow );
}
//--------------------------------------------------------------------------------------------------
///
//--------------------------------------------------------------------------------------------------
void RimFracture::setFractureTemplate( RimFractureTemplate* fractureTemplate )
{
setFractureTemplateNoUpdate( fractureTemplate );
if ( !fractureTemplate )
{
return;
}
RimStimPlanFractureTemplate* stimPlanFracTemplate = dynamic_cast<RimStimPlanFractureTemplate*>( fractureTemplate );
if ( stimPlanFracTemplate )
{
m_stimPlanTimeIndexToPlot = stimPlanFracTemplate->activeTimeStepIndex();
}
if ( fractureTemplate->orientationType() == RimFractureTemplate::AZIMUTH )
{
m_azimuth = fractureTemplate->azimuthAngle();
}
else
{
this->updateAzimuthBasedOnWellAzimuthAngle();
}
this->m_wellDiameter = fractureTemplate->wellDiameter();
this->m_perforationLength = fractureTemplate->perforationLength();
clearCachedNonDarcyProperties();
}
//--------------------------------------------------------------------------------------------------
///
//--------------------------------------------------------------------------------------------------
RimFractureTemplate* RimFracture::fractureTemplate() const
{
return m_fractureTemplate();
}
//--------------------------------------------------------------------------------------------------
///
//--------------------------------------------------------------------------------------------------
RivWellFracturePartMgr* RimFracture::fracturePartManager()
{
CVF_ASSERT( m_fracturePartMgr.notNull() );
return m_fracturePartMgr.p();
}
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