%ExportedHeaderCode
#include <HYDROData_CalculationCase.h>
+#include <HYDROData_PriorityQueue.h>
%End
-class HYDROData_CalculationCase : HYDROData_Entity
+enum HYDROData_PriorityType
+{
+ LESS,
+ GREATER,
+};
+
+class HYDROData_CalculationCase : public HYDROData_Entity
{
%TypeHeaderCode
POINT_ON ///< point is on the edge of zone face
};
+ enum AssignmentMode
+ {
+ MANUAL = 0,
+ AUTOMATIC,
+ };
+
public:
/**
* Add new one reference geometry object for calculation case.
* \param thePoint the point to examine
* \return result altitude value
*/
- double GetAltitudeForPoint( const gp_XY& thePoint ) const;
+ double GetAltitudeForPoint( const double theCoordX,
+ const double theCoordY ) const [double ( const gp_XY& )];
+ %MethodCode
+ gp_XY aPnt( a0, a1 );
+
+ Py_BEGIN_ALLOW_THREADS
+ sipRes = sipSelfWasArg ? sipCpp->HYDROData_CalculationCase::GetAltitudeForPoint( aPnt ) :
+ sipCpp->GetAltitudeForPoint( aPnt );
+ Py_END_ALLOW_THREADS
+ %End
+
+ /**
+ * Returns altitude for given point on given region.
+ * \param thePoint the point to examine
+ * \param theRegion reference region to check
+ * \return result altitude value
+ */
+ double GetAltitudeForPoint( const double theCoordX,
+ const double theCoordY,
+ HYDROData_Region theRegion ) const
+ [double ( const gp_XY&, const Handle_HYDROData_Region& )];
+ %MethodCode
+ gp_XY aPnt( a0, a1 );
+ Handle(HYDROData_Region) aRefRegion =
+ Handle(HYDROData_Region)::DownCast( createHandle( a2 ) );
+
+ Py_BEGIN_ALLOW_THREADS
+ sipRes = sipSelfWasArg ? sipCpp->HYDROData_CalculationCase::GetAltitudeForPoint( aPnt, aRefRegion ) :
+ sipCpp->GetAltitudeForPoint( aPnt, aRefRegion );
+ Py_END_ALLOW_THREADS
+ %End
+
+ /**
+ * Returns altitude for given point on given zone.
+ * \param thePoint the point to examine
+ * \param theZone reference zone to check
+ * \return result altitude value
+ */
+ double GetAltitudeForPoint( const double theCoordX,
+ const double theCoordY,
+ HYDROData_Zone theZone ) const
+ [double ( const gp_XY&, const Handle_HYDROData_Zone& )];
+ %MethodCode
+ gp_XY aPnt( a0, a1 );
+ Handle(HYDROData_Zone) aRefZone =
+ Handle(HYDROData_Zone)::DownCast( createHandle( a2 ) );
+
+ Py_BEGIN_ALLOW_THREADS
+ sipRes = sipSelfWasArg ? sipCpp->HYDROData_CalculationCase::GetAltitudeForPoint( aPnt, aRefZone ) :
+ sipCpp->GetAltitudeForPoint( aPnt, aRefZone );
+ Py_END_ALLOW_THREADS
+ %End
+
+ /**
+ * Returns altitudes for given points on given region.
+ * \param thePoints the points to examine
+ * \param theZone reference region to check
+ * \return result altitude value
+ */
+ NCollection_Sequence<double> GetAltitudesForPoints( const NCollection_Sequence<double>& theCoordsX,
+ const NCollection_Sequence<double>& theCoordsY,
+ HYDROData_Region theRegion ) const
+ [NCollection_Sequence<double> ( const NCollection_Sequence<gp_XY>&, const Handle_HYDROData_Region& )];
+ %MethodCode
+
+ NCollection_Sequence<gp_XY> aPnts;
+
+ int aLen = qMin( a0->Length(), a1->Length() );
+ for ( int i = 1; i <= aLen; ++i )
+ {
+ gp_XY aPnt( a0->Value( i ), a1->Value( i ) );
+ aPnts.Append( aPnt );
+ }
+
+ Handle(HYDROData_Region) aRefRegion =
+ Handle(HYDROData_Region)::DownCast( createHandle( a2 ) );
+
+ NCollection_Sequence<double> aRes;
+ Py_BEGIN_ALLOW_THREADS
+ aRes = sipSelfWasArg ? sipCpp->HYDROData_CalculationCase::GetAltitudesForPoints( aPnts, aRefRegion ) :
+ sipCpp->GetAltitudesForPoints( aPnts, aRefRegion );
+ Py_END_ALLOW_THREADS
+
+ sipRes = new NCollection_Sequence<double>( aRes );
+ %End
+
+ /**
+ * Returns altitudes for given points on given zone.
+ * \param thePoints the points to examine
+ * \param theZone reference zone to check
+ * \return result altitude value
+ */
+ NCollection_Sequence<double> GetAltitudesForPoints( const NCollection_Sequence<double>& theCoordsX,
+ const NCollection_Sequence<double>& theCoordsY,
+ HYDROData_Zone theZone ) const
+ [NCollection_Sequence<double> ( const NCollection_Sequence<gp_XY>&, const Handle_HYDROData_Zone& )];
+ %MethodCode
+
+ NCollection_Sequence<gp_XY> aPnts;
+
+ int aLen = qMin( a0->Length(), a1->Length() );
+ for ( int i = 1; i <= aLen; ++i )
+ {
+ gp_XY aPnt( a0->Value( i ), a1->Value( i ) );
+ aPnts.Append( aPnt );
+ }
+
+ Handle(HYDROData_Zone) aRefZone =
+ Handle(HYDROData_Zone)::DownCast( createHandle( a2 ) );
+
+ NCollection_Sequence<double> aRes;
+ Py_BEGIN_ALLOW_THREADS
+ aRes = sipSelfWasArg ? sipCpp->HYDROData_CalculationCase::GetAltitudesForPoints( aPnts, aRefZone ) :
+ sipCpp->GetAltitudesForPoints( aPnts, aRefZone );
+ Py_END_ALLOW_THREADS
+
+ sipRes = new NCollection_Sequence<double>( aRes );
+ %End
+
+ /**
+ * Returns region to which the point is belongs.
+ * \param thePoint the point to examine
+ * \return result region
+ */
+ HYDROData_Region GetRegionFromPoint( const double theCoordX,
+ const double theCoordY ) const
+ [Handle_HYDROData_Region ( const gp_XY& )];
+ %MethodCode
+ Handle(HYDROData_Region) aRes;
+
+ gp_XY aPnt( a0, a1 );
+
+ Py_BEGIN_ALLOW_THREADS
+ aRes = sipSelfWasArg ? sipCpp->HYDROData_CalculationCase::GetRegionFromPoint( aPnt ) :
+ sipCpp->GetRegionFromPoint( aPnt );
+ Py_END_ALLOW_THREADS
+
+ sipRes = (HYDROData_Region*)createPointer( aRes );
+ %End
/**
* Returns zone to which the point is belongs.
* \param thePoint the point to examine
* \return result zone
*/
- HYDROData_Zone GetZoneFromPoint( const gp_XY& thePoint ) const [Handle_HYDROData_Zone ( const gp_XY& )];
+ HYDROData_Zone GetZoneFromPoint( const double theCoordX,
+ const double theCoordY ) const
+ [Handle_HYDROData_Zone ( const gp_XY& )];
%MethodCode
Handle(HYDROData_Zone) aRes;
+ gp_XY aPnt( a0, a1 );
+
Py_BEGIN_ALLOW_THREADS
- aRes = sipSelfWasArg ? sipCpp->HYDROData_CalculationCase::GetZoneFromPoint( *a0 ) :
- sipCpp->GetZoneFromPoint( *a0 );
+ aRes = sipSelfWasArg ? sipCpp->HYDROData_CalculationCase::GetZoneFromPoint( aPnt ) :
+ sipCpp->GetZoneFromPoint( aPnt );
Py_END_ALLOW_THREADS
sipRes = (HYDROData_Zone*)createPointer( aRes );
* \param theZone the zone to examine
* \return result classification
*/
- PointClassification GetPointClassification(
- const gp_XY& thePoint,
- HYDROData_Zone theZone ) const
- [PointClassification ( const gp_XY&, const Handle_HYDROData_Zone& )];
-
+ PointClassification GetPointClassification( const double theCoordX,
+ const double theCoordY,
+ HYDROData_Zone theZone ) const
+ [PointClassification ( const gp_XY&, const Handle_HYDROData_Zone& )];
%MethodCode
+ gp_XY aPnt( a0, a1 );
+
Handle(HYDROData_Zone) aRef =
- Handle(HYDROData_Zone)::DownCast( createHandle( a1 ) );
-
- if ( !aRef.IsNull() )
- {
- Py_BEGIN_ALLOW_THREADS
- sipRes = sipSelfWasArg ? sipCpp->HYDROData_CalculationCase::GetPointClassification( *a0, aRef ) :
- sipCpp->GetPointClassification( *a0, aRef );
- Py_END_ALLOW_THREADS
- }
+ Handle(HYDROData_Zone)::DownCast( createHandle( a2 ) );
+
+ Py_BEGIN_ALLOW_THREADS
+ sipRes = sipSelfWasArg ? sipCpp->HYDROData_CalculationCase::GetPointClassification( aPnt, aRef ) :
+ sipCpp->GetPointClassification( aPnt, aRef );
+ Py_END_ALLOW_THREADS
+ %End
+
+
+ void ClearRules();
+
+ void AddRule( HYDROData_Object theObject1,
+ HYDROData_PriorityType thePriority,
+ HYDROData_Object theObject2,
+ HYDROData_Zone::MergeAltitudesType theMergeType )
+ [void ( const Handle_HYDROData_Object&, HYDROData_PriorityType, const Handle_HYDROData_Object&, HYDROData_Zone::MergeAltitudesType )];
+ %MethodCode
+ Handle(HYDROData_Object) anObject1 =
+ Handle(HYDROData_Object)::DownCast( createHandle( a0 ) );
+ Handle(HYDROData_Object) anObject2 =
+ Handle(HYDROData_Object)::DownCast( createHandle( a2 ) );
+
+ Py_BEGIN_ALLOW_THREADS
+ sipSelfWasArg ? sipCpp->HYDROData_CalculationCase::AddRule( anObject1, a1, anObject2, a3 ) :
+ sipCpp->AddRule( anObject1, a1, anObject2, a3 );
+ Py_END_ALLOW_THREADS
%End
+ QString DumpRules();
+
+ void SetAssignmentMode( AssignmentMode theMode );
+ AssignmentMode GetAssignmentMode() const;
+
protected:
/**