#include "HYDROData_NaturalObject.h"
#include "HYDROData_PolylineXY.h"
#include "HYDROData_StricklerTable.h"
-#include "HYDROData_SplittedShapesGroup.h"
+#include "HYDROData_LandCoverMap.h"
+#include "HYDROData_SplitShapesGroup.h"
#include "HYDROData_Region.h"
#include "HYDROData_Tool.h"
#include "HYDROData_GeomTool.h"
#define EXPORT_NAME "HYDRO_" + GetName()
+#include <SALOME_NamingService.hxx>
+#include <SALOME_LifeCycleCORBA.hxx>
+
+#define _DEVDEBUG_
+#include "HYDRO_trace.hxx"
+
IMPLEMENT_STANDARD_HANDLE(HYDROData_CalculationCase, HYDROData_Entity)
IMPLEMENT_STANDARD_RTTIEXT(HYDROData_CalculationCase, HYDROData_Entity)
// Update names of regions and its zones
UpdateRegionsNames( GetRegions(), anOldCaseName, theName );
- HYDROData_SequenceOfObjects aGroups = GetSplittedGroups();
+ HYDROData_SequenceOfObjects aGroups = GetSplitGroups();
HYDROData_SequenceOfObjects::Iterator anIter;
anIter.Init( aGroups );
for ( ; anIter.More(); anIter.Next() )
{
- Handle(HYDROData_SplittedShapesGroup) aGroup =
- Handle(HYDROData_SplittedShapesGroup)::DownCast( anIter.Value() );
+ Handle(HYDROData_SplitShapesGroup) aGroup =
+ Handle(HYDROData_SplitShapesGroup)::DownCast( anIter.Value() );
if ( aGroup.IsNull() )
continue;
HYDROData_Entity::SetName( theName );
}
-QStringList HYDROData_CalculationCase::DumpToPython( MapOfTreatedObjects& theTreatedObjects ) const
+QStringList HYDROData_CalculationCase::DumpToPython( const QString& thePyScriptPath,
+ MapOfTreatedObjects& theTreatedObjects ) const
{
QStringList aResList = dumpObjectCreation( theTreatedObjects );
aResList.prepend( "# Calculation case" );
{
Handle(HYDROData_Object) aRefGeomObj =
Handle(HYDROData_Object)::DownCast( anIter.Value() );
- setPythonReferenceObject( theTreatedObjects, aResList, aRefGeomObj, "AddGeometryObject" );
+ setPythonReferenceObject( thePyScriptPath, theTreatedObjects, aResList, aRefGeomObj, "AddGeometryObject" );
}
aResList << QString( "" );
}
Handle(HYDROData_PolylineXY) aBoundaryPolyline = GetBoundaryPolyline();
- setPythonReferenceObject( theTreatedObjects, aResList, aBoundaryPolyline, "SetBoundaryPolyline" );
+ setPythonReferenceObject( thePyScriptPath, theTreatedObjects, aResList, aBoundaryPolyline, "SetBoundaryPolyline" );
if( aMode==AUTOMATIC )
DumpRulesToPython( aCalculName, aResList );
{
// Now we restore the
// - regions and zones order
- DumpRegionsToPython( aResList, theTreatedObjects, GetRegions() );
+ DumpRegionsToPython( aResList, thePyScriptPath, theTreatedObjects, GetRegions() );
}
// Export calculation case
// At first we remove previously created objects
RemoveRegions();
- RemoveSplittedGroups();
+ RemoveSplitGroups();
Handle(HYDROData_Document) aDocument = HYDROData_Document::Document( myLab );
if ( aDocument.IsNull() )
void HYDROData_CalculationCase::CreateRegionsAuto( const Handle(HYDROData_Document)& theDoc,
const HYDROData_SplitToZonesTool::SplitDataList& theZones )
{
+ DEBTRACE("HYDROData_CalculationCase::CreateRegionsAuto");
QMap<QString, Handle(HYDROData_Region)> aRegionsMap; //object name to region
QMap<QString, QString> aRegionNameToObjNameMap;
QString aZonesPref = CALCULATION_ZONES_PREF;
Handle(HYDROData_Entity) aMergeEntity = aRegObj;
Handle(HYDROData_Object) aMergeObject = Handle(HYDROData_Object)::DownCast( aMergeEntity );
if ( !aMergeObject.IsNull() ) {
+ DEBTRACE("aMergeEntity " << aMergeEntity->GetName().toStdString());
aMergeEntity = aMergeObject->GetAltitudeObject();
}
void HYDROData_CalculationCase::CreateEdgeGroupsDef( const Handle(HYDROData_Document)& theDoc,
const HYDROData_SplitToZonesTool::SplitDataList& theEdges )
{
- QMap<QString,Handle(HYDROData_SplittedShapesGroup)> aSplittedEdgesGroupsMap;
+ QMap<QString,Handle(HYDROData_SplitShapesGroup)> aSplitEdgesGroupsMap;
HYDROData_SplitToZonesTool::SplitDataListIterator anIter( theEdges );
while( anIter.hasNext() )
QString aStr = aSplitData.ObjectNames.join(" ");
cout << " CCase: Names = "<<aStr.toStdString() << " size = " <<aSplitData.ObjectNames.size() <<endl;
#endif
- Handle(HYDROData_SplittedShapesGroup) aSplittedGroup;
- if ( !aSplittedEdgesGroupsMap.contains( anObjName ) )
+ Handle(HYDROData_SplitShapesGroup) aSplitGroup;
+ if ( !aSplitEdgesGroupsMap.contains( anObjName ) )
{
- aSplittedGroup = addNewSplittedGroup( CALCULATION_GROUPS_PREF + anObjName );
- aSplittedEdgesGroupsMap.insert( anObjName, aSplittedGroup );
+ aSplitGroup = addNewSplitGroup( CALCULATION_GROUPS_PREF + anObjName );
+ aSplitEdgesGroupsMap.insert( anObjName, aSplitGroup );
}
else
{
- aSplittedGroup = aSplittedEdgesGroupsMap[ anObjName ];
+ aSplitGroup = aSplitEdgesGroupsMap[ anObjName ];
}
- if ( aSplittedGroup.IsNull() )
+ if ( aSplitGroup.IsNull() )
continue;
- aSplittedGroup->AddShape( aSplitData.Shape );
+ aSplitGroup->AddShape( aSplitData.Shape );
}
}
Changed( Geom_No );
}
+Handle(HYDROData_LandCoverMap) HYDROData_CalculationCase::GetLandCoverMap() const
+{
+ Handle(HYDROData_LandCoverMap) aMap = Handle(HYDROData_LandCoverMap)::DownCast(
+ GetReferenceObject( DataTag_LandCoverMap ) );
+ return aMap;
+}
+
+void HYDROData_CalculationCase::SetLandCoverMap( const Handle(HYDROData_LandCoverMap)& theMap )
+{
+ SetReferenceObject( theMap, DataTag_LandCoverMap );
+}
+
Handle(HYDROData_Region) HYDROData_CalculationCase::AddNewRegion( const Handle(HYDROData_Zone)& theZone )
{
Changed( Geom_No );
myLab.FindChild( DataTag_ChildRegion ).ForgetAllAttributes();
}
-HYDROData_SequenceOfObjects HYDROData_CalculationCase::GetSplittedGroups() const
+HYDROData_SequenceOfObjects HYDROData_CalculationCase::GetSplitGroups() const
{
- return GetReferenceObjects( DataTag_SplittedGroups );
+ return GetReferenceObjects( DataTag_SplitGroups );
}
-void HYDROData_CalculationCase::RemoveSplittedGroups()
+void HYDROData_CalculationCase::RemoveSplitGroups()
{
- myLab.FindChild( DataTag_SplittedGroups ).ForgetAllAttributes();
+ myLab.FindChild( DataTag_SplitGroups ).ForgetAllAttributes();
}
double HYDROData_CalculationCase::GetAltitudeForPoint( const gp_XY& thePoint ) const
Handle(HYDROData_Zone) aZone = GetZoneFromPoint( thePoint );
if ( !aZone.IsNull() )
{
+ //DEBTRACE("GetAltitudeForPoint Region " << theRegion->GetName().toStdString() << " Zone " << aZone->GetName().toStdString());
Handle(HYDROData_Region) aRefRegion = Handle(HYDROData_Region)::DownCast( aZone->GetFatherObject() );
if ( IsEqual( aRefRegion, theRegion ) )
aResAltitude = GetAltitudeForPoint( thePoint, aZone );
+ else
+ {
+ DEBTRACE("GetAltitudeForPoint Region " << aRefRegion->GetName().toStdString() << " Zone " << aZone->GetName().toStdString() << " ---------------------------");
+ aResAltitude = GetAltitudeForPoint( thePoint, aZone );
+ }
}
+ else
+ {
+ DEBTRACE(" --- GetAltitudeForPoint No Zone ---");
+ }
return aResAltitude;
}
double HYDROData_CalculationCase::GetAltitudeForPoint( const gp_XY& thePoint,
const Handle(HYDROData_Zone)& theZone ) const
{
+ //DEBTRACE("GetAltitudeForPoint Zone " << theZone->GetName().toStdString());
double aResAltitude = HYDROData_IAltitudeObject::GetInvalidAltitude();
if ( theZone.IsNull() )
+ {
+ DEBTRACE("Zone nulle");
return aResAltitude;
+ }
HYDROData_Zone::MergeType aZoneMergeType = theZone->GetMergeType();
+ //DEBTRACE("aZoneMergeType " << aZoneMergeType);
if ( !theZone->IsMergingNeed() )
{
aZoneMergeType = HYDROData_Zone::Merge_UNKNOWN;
+ //DEBTRACE("---");
}
else if ( aZoneMergeType == HYDROData_Zone::Merge_UNKNOWN )
{
+ DEBTRACE("GetAltitudeForPoint Zone " << theZone->GetName().toStdString() << " Merge_UNKNOWN");
return aResAltitude;
}
{
if ( aZoneInterpolator != NULL )
{
+ DEBTRACE("aZoneInterpolator != NULL");
aZoneInterpolator->SetAltitudeObject( aMergeAltitude );
aResAltitude = aZoneInterpolator->GetAltitudeForPoint( thePoint );
}
else
+ {
+ DEBTRACE("aZoneInterpolator == NULL");
aResAltitude = aMergeAltitude->GetAltitudeForPoint( thePoint );
+ }
}
}
else
{
+ //DEBTRACE("aZoneMergeType != HYDROData_Zone::Merge_Object");
HYDROData_SequenceOfObjects aZoneObjects = theZone->GetObjects();
HYDROData_SequenceOfObjects::Iterator anIter( aZoneObjects );
for ( ; anIter.More(); anIter.Next() )
double aPointAltitude = 0.0;
if ( aZoneInterpolator != NULL )
{
+ DEBTRACE("aZoneInterpolator != NULL");
aZoneInterpolator->SetAltitudeObject( anObjAltitude );
aPointAltitude = aZoneInterpolator->GetAltitudeForPoint( thePoint );
}
else
+ {
+ //DEBTRACE("aZoneInterpolator == NULL");
aPointAltitude = anObjAltitude->GetAltitudeForPoint( thePoint );
+ }
if ( ValuesEquals( aPointAltitude, HYDROData_IAltitudeObject::GetInvalidAltitude() ) )
continue;
const NCollection_Sequence<gp_XY>& thePoints,
const Handle(HYDROData_Region)& theRegion ) const
{
+ //DEBTRACE("HYDROData_CalculationCase::GetAltitudesForPoints " << theRegion->GetName().toStdString());
NCollection_Sequence<double> aResSeq;
for ( int i = 1, n = thePoints.Length(); i <= n; ++i )
double HYDROData_CalculationCase::GetStricklerCoefficientForPoint( const gp_XY& thePoint ) const
{
- //TODO: #652
- return 0.0;
+ Handle( HYDROData_LandCoverMap ) aMap = GetLandCoverMap();
+ Handle( HYDROData_StricklerTable ) aTable = GetStricklerTable();
+ if( aMap.IsNull() )
+ return 0.0;
+
+ QString aType;
+ aMap->FindByPoint( thePoint, aType );
+ double aCoeff = aTable->Get( aType, 0.0 );
+ return aCoeff;
}
Handle(HYDROData_Region) HYDROData_CalculationCase::GetRegionFromPoint( const gp_XY& thePoint ) const
return aNewRegion;
}
-Handle(HYDROData_SplittedShapesGroup) HYDROData_CalculationCase::addNewSplittedGroup( const QString& theName )
+Handle(HYDROData_SplitShapesGroup) HYDROData_CalculationCase::addNewSplitGroup( const QString& theName )
{
- TDF_Label aNewLab = myLab.FindChild( DataTag_SplittedGroups ).NewChild();
+ TDF_Label aNewLab = myLab.FindChild( DataTag_SplitGroups ).NewChild();
- Handle(HYDROData_SplittedShapesGroup) aNewGroup =
- Handle(HYDROData_SplittedShapesGroup)::DownCast(
- HYDROData_Iterator::CreateObject( aNewLab, KIND_SPLITTED_GROUP ) );
- AddReferenceObject( aNewGroup, DataTag_SplittedGroups );
+ Handle(HYDROData_SplitShapesGroup) aNewGroup =
+ Handle(HYDROData_SplitShapesGroup)::DownCast(
+ HYDROData_Iterator::CreateObject( aNewLab, KIND_SPLIT_GROUP ) );
+ AddReferenceObject( aNewGroup, DataTag_SplitGroups );
aNewGroup->SetName( theName );
HYDROData_ShapesGroup::SeqOfGroupsDefs aSeqOfGroupsDefs;
// Get groups definitions
- HYDROData_SequenceOfObjects aSplittedGroups = GetSplittedGroups();
+ HYDROData_SequenceOfObjects aSplitGroups = GetSplitGroups();
- HYDROData_SequenceOfObjects::Iterator anIter( aSplittedGroups );
+ HYDROData_SequenceOfObjects::Iterator anIter( aSplitGroups );
for ( ; anIter.More(); anIter.Next() )
{
// Get shapes group
aRes = Export( theGeomEngine, theStudy, aFaces, aSeqOfGroupsDefs, theGeomObjEntry );;
}
+ if( aRes && !GetLandCoverMap().IsNull() && !GetStricklerTable().IsNull() )
+ {
+ QString aTelemacFileName = GetName() + ".telemac";
+ aRes = GetLandCoverMap()->ExportTelemac( aTelemacFileName, 1E-2, GetStricklerTable() );
+ }
return aRes;
}
}
void HYDROData_CalculationCase::DumpRegionsToPython( QStringList& theResList,
+ const QString& thePyScriptPath,
MapOfTreatedObjects& theTreatedObjects,
const HYDROData_SequenceOfObjects& theRegions ) const
{
continue;
theTreatedObjects.insert( aRegion->GetName(), aRegion );
- QStringList aRegDump = aRegion->DumpToPython( theTreatedObjects );
+ QStringList aRegDump = aRegion->DumpToPython( thePyScriptPath, theTreatedObjects );
theResList << aRegDump;
}
}