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ResInsight/ApplicationLibCode/ProjectDataModel/Flow/RimFlowCharacteristicsPlot.cpp
Magne Sjaastad 40080a99de
9978 Improve UI for long drop-down lists, use tree selection more 
* Improve tree selection editor
- always call defineEditorAttributes
- use heightHint in editor attributes 
- use tree selection editor as default editor for std::vector

* Use tree selection editor instead of list selection editor
List selection editor must be used when editing std::vector<cvf::vec3d> and similar. Replace other use of list selection editor with tree selection editor.

* Set checked state based on text string for integer only models
For models with only integer values, use text string to define the items to be selected. The full list will always be visible, and the checked state will be updated when editing the filter text.

Example: "1, 5-7" will set items 1, 5, 6, 7 checked and all other items unchecked

* Minor fixes
- Set placeholder text after content is added (to ensure correct data type)
- Fix check of integers. `canConvert<int>()`returns true for both QString and int. Thus convert to string and then check for int conversion.

* Activate filtering when unchecking all items in list with only integers
- Reactivate filtering when uncheck of all items for a list with only integer values (to keep consistency between filter and list)
- Update function name for clarity

---------

Co-authored-by: Jørgen Herje <jorgen.herje@ceetronsolutions.com>
2023-05-22 15:44:37 +02:00

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/////////////////////////////////////////////////////////////////////////////////
//
// Copyright (C) 2017 Statoil 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 "RimFlowCharacteristicsPlot.h"
#include "RiaPreferences.h"
#include "RifCsvDataTableFormatter.h"
#include "RigActiveCellInfo.h"
#include "RigEclipseCaseData.h"
#include "RigFlowDiagResults.h"
#include "RimEclipseCaseTools.h"
#include "RimEclipseCellColors.h"
#include "RimEclipsePropertyFilter.h"
#include "RimEclipsePropertyFilterCollection.h"
#include "RimEclipseResultCase.h"
#include "RimEclipseView.h"
#include "RimFaultInViewCollection.h"
#include "RimFlowDiagSolution.h"
#include "RicEclipsePropertyFilterFeatureImpl.h"
#include "RicSelectOrCreateViewFeatureImpl.h"
#include "RiuFlowCharacteristicsPlot.h"
#include "RiuMainWindow.h"
#include "cafPdmUiCheckBoxEditor.h"
#include "cafPdmUiPushButtonEditor.h"
#include "cafUtils.h"
#include <QDateTime>
#include <cmath> // Needed for HUGE_VAL on Linux
namespace caf
{
template <>
void AppEnum<RimFlowCharacteristicsPlot::TimeSelectionType>::setUp()
{
addItem( RimFlowCharacteristicsPlot::ALL_AVAILABLE, "ALL_AVAILABLE", "All With Calculated Flow Diagnostics" );
addItem( RimFlowCharacteristicsPlot::SELECTED, "SELECTED", "Selected" );
setDefault( RimFlowCharacteristicsPlot::SELECTED );
}
} // namespace caf
CAF_PDM_SOURCE_INIT( RimFlowCharacteristicsPlot, "FlowCharacteristicsPlot" );
//--------------------------------------------------------------------------------------------------
///
//--------------------------------------------------------------------------------------------------
RimFlowCharacteristicsPlot::RimFlowCharacteristicsPlot()
{
CAF_PDM_InitObject( "Flow Characteristics", ":/FlowCharPlot16x16.png" );
CAF_PDM_InitFieldNoDefault( &m_case, "FlowCase", "Case" );
CAF_PDM_InitFieldNoDefault( &m_flowDiagSolution, "FlowDiagSolution", "Flow Diag Solution" );
m_flowDiagSolution.uiCapability()->setUiHidden( true );
CAF_PDM_InitFieldNoDefault( &m_timeStepSelectionType, "TimeSelectionType", "Time Steps" );
CAF_PDM_InitFieldNoDefault( &m_selectedTimeSteps, "SelectedTimeSteps", "" );
m_selectedTimeSteps.uiCapability()->setUiHidden( true );
CAF_PDM_InitFieldNoDefault( &m_selectedTimeStepsUi, "SelectedTimeStepsUi", "" );
CAF_PDM_InitFieldNoDefault( &m_applyTimeSteps, "ApplyTimeSteps", "" );
caf::PdmUiPushButtonEditor::configureEditorForField( &m_applyTimeSteps );
CAF_PDM_InitField( &m_maxPvFraction,
"CellPVThreshold",
0.1,
"Aquifer Cell Threshold",
"",
"Exclude Aquifer Effects by adding a Cell Pore Volume Threshold as Fraction of Total Pore "
"Volume.",
"" );
CAF_PDM_InitField( &m_showLegend, "ShowLegend", true, "Legend" );
// Region group
CAF_PDM_InitFieldNoDefault( &m_cellFilter, "CellFilter", "Cell Filter" );
CAF_PDM_InitFieldNoDefault( &m_cellFilterView, "CellFilterView", "View" );
CAF_PDM_InitField( &m_tracerFilter, "TracerFilter", QString(), "Tracer Filter" );
CAF_PDM_InitFieldNoDefault( &m_selectedTracerNames, "SelectedTracerNames", " " );
CAF_PDM_InitFieldNoDefault( &m_showRegion, "ShowRegion", "" );
caf::PdmUiPushButtonEditor::configureEditorForField( &m_showRegion );
CAF_PDM_InitField( &m_minCommunication, "MinCommunication", 0.0, "Min Communication" );
CAF_PDM_InitField( &m_maxTof, "MaxTof", 146000, "Max Time of Flight [days]" );
this->m_showWindow = false;
setAsPlotMdiWindow();
setDeletable( true );
}
//--------------------------------------------------------------------------------------------------
///
//--------------------------------------------------------------------------------------------------
RimFlowCharacteristicsPlot::~RimFlowCharacteristicsPlot()
{
removeMdiWindowFromMdiArea();
if ( m_flowCharPlotWidget )
{
m_flowCharPlotWidget->hide();
m_flowCharPlotWidget->setParent( nullptr );
delete m_flowCharPlotWidget;
m_flowCharPlotWidget = nullptr;
}
}
//--------------------------------------------------------------------------------------------------
/// TODO: implement properly
//--------------------------------------------------------------------------------------------------
int RimFlowCharacteristicsPlot::id() const
{
return -1;
}
//--------------------------------------------------------------------------------------------------
///
//--------------------------------------------------------------------------------------------------
void RimFlowCharacteristicsPlot::setFromFlowSolution( RimFlowDiagSolution* flowSolution )
{
if ( !flowSolution )
{
m_case = nullptr;
m_cellFilterView = nullptr;
}
else
{
auto eclCase = flowSolution->firstAncestorOrThisOfType<RimEclipseResultCase>();
m_case = eclCase;
if ( !eclCase->reservoirViews.empty() )
{
m_cellFilterView = eclCase->reservoirViews()[0];
}
}
m_flowDiagSolution = flowSolution;
m_showWindow = true;
m_timeStepToFlowResultMap.clear();
m_currentlyPlottedTimeSteps.clear();
onLoadDataAndUpdate();
}
//--------------------------------------------------------------------------------------------------
///
//--------------------------------------------------------------------------------------------------
void RimFlowCharacteristicsPlot::deleteViewWidget()
{
if ( m_flowCharPlotWidget )
{
m_flowCharPlotWidget->hide();
m_flowCharPlotWidget->setParent( nullptr );
delete m_flowCharPlotWidget;
m_flowCharPlotWidget = nullptr;
}
}
//--------------------------------------------------------------------------------------------------
///
//--------------------------------------------------------------------------------------------------
void RimFlowCharacteristicsPlot::updateCurrentTimeStep()
{
if ( m_timeStepSelectionType() != ALL_AVAILABLE ) return;
if ( !m_flowDiagSolution() ) return;
RigFlowDiagResults* flowResult = m_flowDiagSolution->flowDiagResults();
std::vector<int> calculatedTimesteps = flowResult->calculatedTimeSteps( RigFlowDiagResultAddress::PHASE_ALL );
if ( m_currentlyPlottedTimeSteps == calculatedTimesteps ) return;
this->onLoadDataAndUpdate();
}
//--------------------------------------------------------------------------------------------------
///
//--------------------------------------------------------------------------------------------------
void RimFlowCharacteristicsPlot::setTimeSteps( const std::vector<int>& timeSteps )
{
m_selectedTimeSteps = timeSteps;
}
//--------------------------------------------------------------------------------------------------
///
//--------------------------------------------------------------------------------------------------
void RimFlowCharacteristicsPlot::setInjectorsAndProducers( const std::vector<QString>& injectors, const std::vector<QString>& producers )
{
std::vector<QString> allTracers;
allTracers = producers;
allTracers.insert( allTracers.end(), injectors.begin(), injectors.end() );
if ( producers.empty() && !injectors.empty() )
{
m_cellFilter = RigFlowDiagResults::CELLS_FLOODED;
}
else if ( !producers.empty() && injectors.empty() )
{
m_cellFilter = RigFlowDiagResults::CELLS_DRAINED;
}
else if ( !producers.empty() && !injectors.empty() )
{
m_cellFilter = RigFlowDiagResults::CELLS_COMMUNICATION;
}
m_selectedTracerNames = allTracers;
}
//--------------------------------------------------------------------------------------------------
///
//--------------------------------------------------------------------------------------------------
void RimFlowCharacteristicsPlot::setMinimumCommunication( double minimumCommunication )
{
m_minCommunication = minimumCommunication;
}
//--------------------------------------------------------------------------------------------------
///
//--------------------------------------------------------------------------------------------------
void RimFlowCharacteristicsPlot::setAquiferCellThreshold( double aquiferCellThreshold )
{
m_maxPvFraction = aquiferCellThreshold;
}
//--------------------------------------------------------------------------------------------------
///
//--------------------------------------------------------------------------------------------------
int RimFlowCharacteristicsPlot::fontSize() const
{
return caf::FontTools::absolutePointSize( RiaPreferences::current()->defaultPlotFontSize() );
}
//--------------------------------------------------------------------------------------------------
///
//--------------------------------------------------------------------------------------------------
void RimFlowCharacteristicsPlot::updateFonts()
{
}
//--------------------------------------------------------------------------------------------------
///
//--------------------------------------------------------------------------------------------------
QList<caf::PdmOptionItemInfo> RimFlowCharacteristicsPlot::calculateValueOptions( const caf::PdmFieldHandle* fieldNeedingOptions )
{
QList<caf::PdmOptionItemInfo> options;
if ( fieldNeedingOptions == &m_case )
{
auto resultCases = RimEclipseCaseTools::eclipseResultCases();
for ( RimEclipseResultCase* c : resultCases )
{
if ( c->defaultFlowDiagSolution() )
{
options.push_back( caf::PdmOptionItemInfo( c->caseUserDescription(), c, false, c->uiIconProvider() ) );
}
}
}
else if ( fieldNeedingOptions == &m_cellFilterView )
{
if ( m_case )
{
for ( RimEclipseView* view : m_case()->reservoirViews() )
{
options.push_back( caf::PdmOptionItemInfo( view->name(), view, false, view->uiIconProvider() ) );
}
}
}
else if ( fieldNeedingOptions == &m_flowDiagSolution )
{
if ( m_case )
{
std::vector<RimFlowDiagSolution*> flowSols = m_case->flowDiagSolutions();
options.push_back( caf::PdmOptionItemInfo( "None", nullptr ) );
for ( RimFlowDiagSolution* flowSol : flowSols )
{
options.push_back( caf::PdmOptionItemInfo( flowSol->userDescription(), flowSol, false, flowSol->uiIconProvider() ) );
}
}
}
else if ( fieldNeedingOptions == &m_selectedTimeStepsUi )
{
if ( m_flowDiagSolution && m_case )
{
QStringList timeStepDates = m_case->timeStepStrings();
std::vector<int> calculatedTimeSteps =
m_flowDiagSolution()->flowDiagResults()->calculatedTimeSteps( RigFlowDiagResultAddress::PHASE_ALL );
for ( int tsIdx = 0; tsIdx < timeStepDates.size(); ++tsIdx )
{
auto it = std::find( calculatedTimeSteps.begin(), calculatedTimeSteps.end(), tsIdx );
QString itemText = timeStepDates[tsIdx];
if ( it != calculatedTimeSteps.end() )
{
itemText = itemText + " *";
}
options.push_back( caf::PdmOptionItemInfo( itemText, tsIdx ) );
}
}
}
else if ( fieldNeedingOptions == &m_selectedTracerNames )
{
if ( m_flowDiagSolution )
{
std::vector<QString> tracerNames = m_flowDiagSolution->tracerNames();
std::vector<std::pair<QString, QString>> sortedTracerNames;
for ( QString tracerName : tracerNames )
{
if ( !caf::Utils::isStringMatch( m_tracerFilter, tracerName ) ) continue;
RimFlowDiagSolution::TracerStatusType tracerStatus = m_flowDiagSolution->tracerStatusOverall( tracerName );
if ( tracerStatus == RimFlowDiagSolution::TracerStatusType::CLOSED ) continue;
if ( m_cellFilter() == RigFlowDiagResults::CELLS_FLOODED )
{
if ( tracerStatus == RimFlowDiagSolution::TracerStatusType::INJECTOR ||
tracerStatus == RimFlowDiagSolution::TracerStatusType::VARYING )
{
sortedTracerNames.push_back( std::make_pair( tracerName, tracerName ) );
}
}
else if ( m_cellFilter() == RigFlowDiagResults::CELLS_DRAINED )
{
if ( tracerStatus == RimFlowDiagSolution::TracerStatusType::PRODUCER ||
tracerStatus == RimFlowDiagSolution::TracerStatusType::VARYING )
{
sortedTracerNames.push_back( std::make_pair( tracerName, tracerName ) );
}
}
else if ( m_cellFilter() == RigFlowDiagResults::CELLS_COMMUNICATION )
{
QString prefix;
switch ( tracerStatus )
{
case RimFlowDiagSolution::TracerStatusType::INJECTOR:
prefix = "I : ";
break;
case RimFlowDiagSolution::TracerStatusType::PRODUCER:
prefix = "P : ";
break;
case RimFlowDiagSolution::TracerStatusType::VARYING:
prefix = "I/P: ";
break;
case RimFlowDiagSolution::TracerStatusType::UNDEFINED:
prefix = "U : ";
break;
}
sortedTracerNames.push_back( std::make_pair( prefix + tracerName, tracerName ) );
}
}
std::sort( sortedTracerNames.begin(),
sortedTracerNames.end(),
[]( const std::pair<QString, QString>& a, const std::pair<QString, QString>& b ) -> bool { return a.first < b.first; } );
for ( auto& tracer : sortedTracerNames )
{
options.push_back( caf::PdmOptionItemInfo( tracer.first, tracer.second ) );
}
}
}
return options;
}
//--------------------------------------------------------------------------------------------------
///
//--------------------------------------------------------------------------------------------------
void RimFlowCharacteristicsPlot::defineUiOrdering( QString uiConfigName, caf::PdmUiOrdering& uiOrdering )
{
{
RimEclipseResultCase* defaultCase = nullptr;
auto resultCases = RimEclipseCaseTools::eclipseResultCases();
for ( RimEclipseResultCase* c : resultCases )
{
if ( c->defaultFlowDiagSolution() )
{
if ( !defaultCase ) defaultCase = c; // Select first
}
}
if ( !m_case() && defaultCase )
{
m_case = defaultCase;
m_flowDiagSolution = m_case->defaultFlowDiagSolution();
if ( !m_case()->reservoirViews.empty() )
{
m_cellFilterView = m_case()->reservoirViews()[0];
}
}
}
uiOrdering.add( &m_case );
{
caf::PdmUiGroup* timeStepsGroup = uiOrdering.addNewGroup( "Time Steps" );
timeStepsGroup->add( &m_timeStepSelectionType );
if ( m_timeStepSelectionType == SELECTED )
{
timeStepsGroup->add( &m_selectedTimeStepsUi );
timeStepsGroup->add( &m_applyTimeSteps );
}
}
{
caf::PdmUiGroup* regionGroup = uiOrdering.addNewGroup( "Region" );
regionGroup->add( &m_cellFilter );
if ( m_cellFilter() == RigFlowDiagResults::CELLS_COMMUNICATION || m_cellFilter() == RigFlowDiagResults::CELLS_DRAINED ||
m_cellFilter() == RigFlowDiagResults::CELLS_FLOODED )
{
regionGroup->add( &m_tracerFilter );
regionGroup->add( &m_selectedTracerNames );
regionGroup->add( &m_showRegion );
}
else if ( m_cellFilter() == RigFlowDiagResults::CELLS_VISIBLE )
{
regionGroup->add( &m_cellFilterView );
}
if ( m_cellFilter() == RigFlowDiagResults::CELLS_COMMUNICATION )
{
regionGroup->add( &m_minCommunication );
}
else if ( m_cellFilter() == RigFlowDiagResults::CELLS_DRAINED || m_cellFilter() == RigFlowDiagResults::CELLS_FLOODED )
{
regionGroup->add( &m_maxTof );
}
}
{
caf::PdmUiGroup* optionsGroup = uiOrdering.addNewGroup( "Options" );
optionsGroup->add( &m_flowDiagSolution );
optionsGroup->add( &m_showLegend );
optionsGroup->add( &m_maxPvFraction );
}
uiOrdering.skipRemainingFields();
}
//--------------------------------------------------------------------------------------------------
///
//--------------------------------------------------------------------------------------------------
void RimFlowCharacteristicsPlot::defineEditorAttribute( const caf::PdmFieldHandle* field, QString uiConfigName, caf::PdmUiEditorAttribute* attribute )
{
if ( field == &m_applyTimeSteps )
{
caf::PdmUiPushButtonEditorAttribute* attrib = dynamic_cast<caf::PdmUiPushButtonEditorAttribute*>( attribute );
if ( attrib )
{
attrib->m_buttonText = "Apply";
}
}
else if ( field == &m_showRegion )
{
caf::PdmUiPushButtonEditorAttribute* attrib = dynamic_cast<caf::PdmUiPushButtonEditorAttribute*>( attribute );
if ( attrib )
{
attrib->m_buttonText = "Show Region";
}
}
}
//--------------------------------------------------------------------------------------------------
///
//--------------------------------------------------------------------------------------------------
QWidget* RimFlowCharacteristicsPlot::viewWidget()
{
return m_flowCharPlotWidget;
}
//--------------------------------------------------------------------------------------------------
///
//--------------------------------------------------------------------------------------------------
void RimFlowCharacteristicsPlot::zoomAll()
{
if ( m_flowCharPlotWidget ) m_flowCharPlotWidget->zoomAll();
}
//--------------------------------------------------------------------------------------------------
///
//--------------------------------------------------------------------------------------------------
void RimFlowCharacteristicsPlot::fieldChangedByUi( const caf::PdmFieldHandle* changedField, const QVariant& oldValue, const QVariant& newValue )
{
RimViewWindow::fieldChangedByUi( changedField, oldValue, newValue );
if ( &m_case == changedField )
{
m_flowDiagSolution = m_case->defaultFlowDiagSolution();
m_currentlyPlottedTimeSteps.clear();
if ( !m_case()->reservoirViews.empty() )
{
m_cellFilterView = m_case()->reservoirViews()[0];
}
}
else if ( &m_applyTimeSteps == changedField )
{
if ( m_flowDiagSolution )
{
// Compute any missing time steps from selected
for ( int tsIdx : m_selectedTimeStepsUi() )
{
m_flowDiagSolution()->flowDiagResults()->maxAbsPairFlux( tsIdx );
}
m_selectedTimeSteps = m_selectedTimeStepsUi;
}
m_applyTimeSteps = false;
}
else if ( &m_showRegion == changedField )
{
if ( m_case )
{
if ( m_cellFilter() != RigFlowDiagResults::CELLS_ACTIVE )
{
RimEclipseView* view = RicSelectOrCreateViewFeatureImpl::showViewSelection( m_case,
"FlowCharacteristicsLastUsedView",
"RegionView",
"Show Region in View" );
if ( view != nullptr )
{
view->faultCollection()->showFaultCollection = false;
view->cellResult()->setResultType( RiaDefines::ResultCatType::FLOW_DIAGNOSTICS );
view->cellResult()->setFlowDiagTracerSelectionType(
RimEclipseResultDefinition::FlowTracerSelectionType::FLOW_TR_BY_SELECTION );
view->cellResult()->setSelectedTracers( m_selectedTracerNames );
if ( m_cellFilter() == RigFlowDiagResults::CELLS_COMMUNICATION )
{
view->cellResult()->setResultVariable( RIG_FLD_COMMUNICATION_RESNAME );
}
else
{
view->cellResult()->setResultVariable( RIG_FLD_TOF_RESNAME );
}
int timeStep = 0;
if ( m_timeStepSelectionType() == ALL_AVAILABLE )
{
if ( m_flowDiagSolution )
{
std::vector<int> timeSteps =
m_flowDiagSolution()->flowDiagResults()->calculatedTimeSteps( RigFlowDiagResultAddress::PHASE_ALL );
if ( !timeSteps.empty() )
{
timeStep = timeSteps[0];
}
}
}
else
{
if ( !m_selectedTimeStepsUi().empty() )
{
timeStep = m_selectedTimeStepsUi()[0];
}
}
// Ensure selected time step has computed results
m_flowDiagSolution()->flowDiagResults()->maxAbsPairFlux( timeStep );
view->setCurrentTimeStep( timeStep );
for ( RimEclipsePropertyFilter* f : view->eclipsePropertyFilterCollection()->propertyFilters() )
{
f->setActive( false );
}
RicEclipsePropertyFilterFeatureImpl::addPropertyFilter( view->eclipsePropertyFilterCollection() );
view->loadDataAndUpdate();
m_case->updateConnectedEditors();
RicSelectOrCreateViewFeatureImpl::focusView( view );
}
}
}
}
else if ( changedField == &m_cellFilter )
{
m_selectedTracerNames = std::vector<QString>();
}
// All fields update plot
this->onLoadDataAndUpdate();
}
//--------------------------------------------------------------------------------------------------
///
//--------------------------------------------------------------------------------------------------
QImage RimFlowCharacteristicsPlot::snapshotWindowContent()
{
QImage image;
if ( m_flowCharPlotWidget )
{
QPixmap pix = m_flowCharPlotWidget->grab();
image = pix.toImage();
}
return image;
}
//--------------------------------------------------------------------------------------------------
///
//--------------------------------------------------------------------------------------------------
void RimFlowCharacteristicsPlot::onLoadDataAndUpdate()
{
updateMdiWindowVisibility();
if ( m_flowDiagSolution && m_flowCharPlotWidget )
{
RigFlowDiagResults* flowResult = m_flowDiagSolution->flowDiagResults();
if ( !flowResult ) return;
{
std::vector<int> calculatedTimesteps = flowResult->calculatedTimeSteps( RigFlowDiagResultAddress::PHASE_ALL );
if ( m_timeStepSelectionType == SELECTED )
{
for ( int tsIdx : m_selectedTimeSteps() )
{
m_flowDiagSolution()->flowDiagResults()->maxAbsPairFlux( tsIdx );
}
calculatedTimesteps = m_selectedTimeSteps();
}
m_currentlyPlottedTimeSteps = calculatedTimesteps;
}
std::vector<QDateTime> timeStepDates = m_case->timeStepDates();
QStringList timeStepStrings = m_case->timeStepStrings();
std::vector<double> lorenzVals( timeStepDates.size(), HUGE_VAL );
m_flowCharPlotWidget->removeAllCurves();
std::vector<QString> selectedTracerNames = m_selectedTracerNames();
if ( m_cellFilter() == RigFlowDiagResults::CELLS_ACTIVE )
{
if ( m_flowDiagSolution )
{
selectedTracerNames = m_flowDiagSolution->tracerNames();
}
}
std::map<int, RigFlowDiagSolverInterface::FlowCharacteristicsResultFrame> timeStepToFlowResultMap;
for ( int timeStepIdx : m_currentlyPlottedTimeSteps )
{
if ( m_cellFilter() == RigFlowDiagResults::CELLS_VISIBLE )
{
cvf::UByteArray visibleCells;
m_case()->eclipseCaseData()->activeCellInfo( RiaDefines::PorosityModelType::MATRIX_MODEL );
if ( m_cellFilterView )
{
m_cellFilterView()->calculateCurrentTotalCellVisibility( &visibleCells, timeStepIdx );
}
RigActiveCellInfo* activeCellInfo = m_case()->eclipseCaseData()->activeCellInfo( RiaDefines::PorosityModelType::MATRIX_MODEL );
std::vector<char> visibleActiveCells( activeCellInfo->reservoirActiveCellCount(), 0 );
for ( size_t i = 0; i < visibleCells.size(); ++i )
{
size_t cellIndex = activeCellInfo->cellResultIndex( i );
if ( cellIndex != cvf::UNDEFINED_SIZE_T )
{
visibleActiveCells[cellIndex] = visibleCells[i];
}
}
auto flowCharResults = flowResult->flowCharacteristicsResults( timeStepIdx, visibleActiveCells, m_maxPvFraction() );
timeStepToFlowResultMap[timeStepIdx] = flowCharResults;
}
else
{
auto flowCharResults = flowResult->flowCharacteristicsResults( timeStepIdx,
m_cellFilter(),
selectedTracerNames,
m_maxPvFraction(),
m_minCommunication(),
m_maxTof() );
timeStepToFlowResultMap[timeStepIdx] = flowCharResults;
}
lorenzVals[timeStepIdx] = timeStepToFlowResultMap[timeStepIdx].m_lorenzCoefficient;
}
m_timeStepToFlowResultMap = timeStepToFlowResultMap;
m_flowCharPlotWidget->setLorenzCurve( timeStepStrings, timeStepDates, lorenzVals );
for ( int timeStepIdx : m_currentlyPlottedTimeSteps )
{
const auto& flowCharResults = timeStepToFlowResultMap[timeStepIdx];
m_flowCharPlotWidget->addFlowCapStorageCapCurve( timeStepDates[timeStepIdx],
flowCharResults.m_storageCapFlowCapCurve.first,
flowCharResults.m_storageCapFlowCapCurve.second );
m_flowCharPlotWidget->addSweepEfficiencyCurve( timeStepDates[timeStepIdx],
flowCharResults.m_dimensionlessTimeSweepEfficiencyCurve.first,
flowCharResults.m_dimensionlessTimeSweepEfficiencyCurve.second );
}
m_flowCharPlotWidget->showLegend( m_showLegend() );
}
}
//--------------------------------------------------------------------------------------------------
/// TODO: implement properly
//--------------------------------------------------------------------------------------------------
void RimFlowCharacteristicsPlot::assignIdIfNecessary()
{
}
//--------------------------------------------------------------------------------------------------
///
//--------------------------------------------------------------------------------------------------
void RimFlowCharacteristicsPlot::viewGeometryUpdated()
{
if ( m_cellFilter() == RigFlowDiagResults::CELLS_VISIBLE )
{
// Only need to reload data if cell filtering is based on visible cells in view.
onLoadDataAndUpdate();
}
}
//--------------------------------------------------------------------------------------------------
///
//--------------------------------------------------------------------------------------------------
double interpolate( const std::vector<double>& xData, const std::vector<double>& yData, double x, bool extrapolate )
{
size_t itemCount = xData.size();
size_t index = 0;
if ( x >= xData[itemCount - 2] )
{
index = itemCount - 2;
}
else
{
while ( x > xData[index + 1] )
index++;
}
double xLeft = xData[index];
double yLeft = yData[index];
double xRight = xData[index + 1];
double yRight = yData[index + 1];
if ( !extrapolate )
{
if ( x < xLeft ) yRight = yLeft;
if ( x > xRight ) yLeft = yRight;
}
double dydx = ( yRight - yLeft ) / ( xRight - xLeft );
return yLeft + dydx * ( x - xLeft );
}
//--------------------------------------------------------------------------------------------------
///
//--------------------------------------------------------------------------------------------------
QString RimFlowCharacteristicsPlot::curveDataAsText() const
{
QString fieldSeparator = RiaPreferences::current()->csvTextExportFieldSeparator;
QString tableText;
QTextStream stream( &tableText );
RifCsvDataTableFormatter formatter( stream, fieldSeparator );
std::vector<RifTextDataTableColumn> header = {
RifTextDataTableColumn( "Date" ),
RifTextDataTableColumn( "StorageCapacity" ),
RifTextDataTableColumn( "FlowCapacity" ),
RifTextDataTableColumn( "SweepEfficiency" ),
RifTextDataTableColumn( "DimensionlessTime" ),
RifTextDataTableColumn( "LorentzCoefficient" ),
};
formatter.header( header );
std::vector<QDateTime> timeStepDates = m_case->timeStepDates();
std::vector<double> storageCapacitySamplingValues = { 0.08, 0.1, 0.2, 0.3, 0.4 };
size_t sampleCount = storageCapacitySamplingValues.size();
for ( const auto& timeIndex : m_currentlyPlottedTimeSteps )
{
QString dateString = timeStepDates[timeIndex].toString( "yyyy-MM-dd" );
auto a = m_timeStepToFlowResultMap.find( timeIndex );
if ( a != m_timeStepToFlowResultMap.end() )
{
auto storageCapacityValues = a->second.m_storageCapFlowCapCurve.first;
auto flowCapacityValues = a->second.m_storageCapFlowCapCurve.second;
bool extrapolate = false;
std::vector<double> flowCapacitySamplingValues;
for ( const auto storageCapacity : storageCapacitySamplingValues )
{
{
double flowCapacity = interpolate( storageCapacityValues, flowCapacityValues, storageCapacity, extrapolate );
flowCapacitySamplingValues.push_back( flowCapacity );
}
}
auto dimensionLessTimeValues = a->second.m_dimensionlessTimeSweepEfficiencyCurve.first;
auto sweepEffValues = a->second.m_dimensionlessTimeSweepEfficiencyCurve.second;
std::vector<double> dimensionLessTimeSamplingValues;
std::vector<double> sweepEffSamplingValues;
double range = dimensionLessTimeValues.back() - dimensionLessTimeValues[0];
double step = range / sampleCount;
for ( size_t i = 0; i < sampleCount; i++ )
{
double dimensionLessTimeValue = i * step;
dimensionLessTimeSamplingValues.push_back( dimensionLessTimeValue );
double sweepEffValue = interpolate( dimensionLessTimeValues, sweepEffValues, dimensionLessTimeValue, extrapolate );
sweepEffSamplingValues.push_back( sweepEffValue );
}
auto lorentz = a->second.m_lorenzCoefficient;
for ( size_t i = 0; i < sampleCount; i++ )
{
formatter.add( dateString );
formatter.add( storageCapacitySamplingValues[i] );
formatter.add( flowCapacitySamplingValues[i] );
formatter.add( sweepEffSamplingValues[i] );
formatter.add( dimensionLessTimeSamplingValues[i] );
formatter.add( lorentz );
formatter.rowCompleted();
}
}
}
formatter.tableCompleted();
return tableText;
}
//--------------------------------------------------------------------------------------------------
///
//--------------------------------------------------------------------------------------------------
QWidget* RimFlowCharacteristicsPlot::createViewWidget( QWidget* mainWindowParent )
{
m_flowCharPlotWidget = new RiuFlowCharacteristicsPlot( this, mainWindowParent );
return m_flowCharPlotWidget;
}
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