geom/src/GEOMImpl/GEOMImpl_IMeasureOperations.cxx

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// Copyright (C) 2007-2012 CEA/DEN, EDF R&D, OPEN CASCADE
//
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// Copyright (C) 2003-2007 OPEN CASCADE, EADS/CCR, LIP6, CEA/DEN,
// CEDRAT, EDF R&D, LEG, PRINCIPIA R&D, BUREAU VERITAS
//
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// This library is free software; you can redistribute it and/or
// modify it under the terms of the GNU Lesser General Public
// License as published by the Free Software Foundation; either
// version 2.1 of the License.
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//
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// This library 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
// Lesser General Public License for more details.
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//
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// You should have received a copy of the GNU Lesser General Public
// License along with this library; if not, write to the Free Software
// Foundation, Inc., 59 Temple Place, Suite 330, Boston, MA 02111-1307 USA
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//
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// See http://www.salome-platform.org/ or email : webmaster.salome@opencascade.com
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#include <Standard_Stream.hxx>
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#include <GEOMImpl_IMeasureOperations.hxx>
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#include <GEOMImpl_Types.hxx>
#include <GEOMImpl_MeasureDriver.hxx>
#include <GEOMImpl_IMeasure.hxx>
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#include <GEOMImpl_IShapesOperations.hxx>
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#include <GEOMAlgo_ShapeInfo.hxx>
#include <GEOMAlgo_ShapeInfoFiller.hxx>
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#include <GEOM_Function.hxx>
#include <GEOM_PythonDump.hxx>
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#include <NMTTools_CheckerSI.hxx>
#include <NMTDS_Tools.hxx>
#include <NMTDS_InterfPool.hxx>
#include <NMTDS_PInterfPool.hxx>
#include <NMTDS_PairBoolean.hxx>
#include <NMTDS_ShapesDataStructure.hxx>
#include <NMTDS_ListIteratorOfListOfPairBoolean.hxx>
#include <Basics_OCCTVersion.hxx>
#include <utilities.h>
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#include <OpUtil.hxx>
#include <Utils_ExceptHandlers.hxx>
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// OCCT Includes
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#include <TFunction_DriverTable.hxx>
#include <TFunction_Driver.hxx>
#include <TFunction_Logbook.hxx>
#include <TDF_Tool.hxx>
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#include <BRep_Builder.hxx>
#include <BRep_TFace.hxx>
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#include <BRep_Tool.hxx>
#include <BRepAdaptor_Surface.hxx>
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#include <BRepBuilderAPI_Copy.hxx>
#include <BRepBndLib.hxx>
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#include <BRepCheck.hxx>
#include <BRepCheck_ListIteratorOfListOfStatus.hxx>
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#include <BRepCheck_Result.hxx>
#include <BRepCheck_Shell.hxx>
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#include <BRepClass3d_SolidClassifier.hxx>
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#include <BRepExtrema_DistShapeShape.hxx>
#include <BRepGProp.hxx>
#include <BRepTools.hxx>
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#include <Bnd_Box.hxx>
#include <TopAbs.hxx>
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#include <TopExp.hxx>
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#include <TopoDS.hxx>
#include <TopoDS_Edge.hxx>
#include <TopoDS_Face.hxx>
#include <TopoDS_Shape.hxx>
#include <TopoDS_Vertex.hxx>
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#include <TopoDS_Compound.hxx>
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#include <TopoDS_Iterator.hxx>
#include <TopExp_Explorer.hxx>
#include <TopTools_MapOfShape.hxx>
#include <TopTools_ListOfShape.hxx>
#include <TopTools_ListIteratorOfListOfShape.hxx>
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#include <ShapeAnalysis.hxx>
#include <ShapeAnalysis_Surface.hxx>
#include <ShapeFix_Shape.hxx>
#include <GeomAPI_IntSS.hxx>
#include <GeomAPI_ProjectPointOnCurve.hxx>
#include <GeomAbs_SurfaceType.hxx>
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#include <Geom_BezierSurface.hxx>
#include <Geom_BSplineSurface.hxx>
#include <Geom_Circle.hxx>
#include <Geom_ConicalSurface.hxx>
#include <Geom_CylindricalSurface.hxx>
#include <Geom_Line.hxx>
#include <Geom_OffsetSurface.hxx>
#include <Geom_Plane.hxx>
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#include <Geom_RectangularTrimmedSurface.hxx>
#include <Geom_SphericalSurface.hxx>
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#include <Geom_Surface.hxx>
#include <Geom_SurfaceOfLinearExtrusion.hxx>
#include <Geom_SurfaceOfRevolution.hxx>
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#include <Geom_ToroidalSurface.hxx>
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#include <GeomLProp_CLProps.hxx>
#include <GeomLProp_SLProps.hxx>
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#include <GProp_GProps.hxx>
#include <GProp_PrincipalProps.hxx>
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#include <gp_Pln.hxx>
#include <gp_Lin.hxx>
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#include <Standard_Failure.hxx>
#include <Standard_ErrorHandler.hxx> // CAREFUL ! position of this file is critic : see Lucien PIGNOLONI / OCC
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//=============================================================================
/*!
* Constructor
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*/
//=============================================================================
GEOMImpl_IMeasureOperations::GEOMImpl_IMeasureOperations (GEOM_Engine* theEngine, int theDocID)
: GEOM_IOperations(theEngine, theDocID)
{
MESSAGE("GEOMImpl_IMeasureOperations::GEOMImpl_IMeasureOperations");
}
//=============================================================================
/*!
* Destructor
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*/
//=============================================================================
GEOMImpl_IMeasureOperations::~GEOMImpl_IMeasureOperations()
{
MESSAGE("GEOMImpl_IMeasureOperations::~GEOMImpl_IMeasureOperations");
}
//=============================================================================
/*! Get kind and parameters of the given shape.
*/
//=============================================================================
GEOMImpl_IMeasureOperations::ShapeKind GEOMImpl_IMeasureOperations::KindOfShape
(Handle(GEOM_Object) theShape,
Handle(TColStd_HSequenceOfInteger)& theIntegers,
Handle(TColStd_HSequenceOfReal)& theDoubles)
{
SetErrorCode(KO);
ShapeKind aKind = SK_NO_SHAPE;
if (theIntegers.IsNull()) theIntegers = new TColStd_HSequenceOfInteger;
else theIntegers->Clear();
if (theDoubles.IsNull()) theDoubles = new TColStd_HSequenceOfReal;
else theDoubles->Clear();
if (theShape.IsNull())
return aKind;
Handle(GEOM_Function) aRefShape = theShape->GetLastFunction();
if (aRefShape.IsNull()) return aKind;
TopoDS_Shape aShape = aRefShape->GetValue();
if (aShape.IsNull()) return aKind;
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int geom_type = theShape->GetType();
// check if it's advanced shape
if ( geom_type > ADVANCED_BASE ) {
SetErrorCode(OK);
return SK_ADVANCED;
}
// Call algorithm
GEOMAlgo_ShapeInfoFiller aSF;
aSF.SetShape(aShape);
aSF.Perform();
Standard_Integer iErr = aSF.ErrorStatus();
if (iErr) {
SetErrorCode("Error in GEOMAlgo_ShapeInfoFiller");
return SK_NO_SHAPE;
}
const GEOMAlgo_ShapeInfo& anInfo = aSF.Info();
// Interprete results
TopAbs_ShapeEnum aType = anInfo.Type();
switch (aType)
{
case TopAbs_COMPOUND:
case TopAbs_COMPSOLID:
{
// (+) geompy.kind.COMPOUND nb_solids nb_faces nb_edges nb_vertices
// (+) geompy.kind.COMPSOLID nb_solids nb_faces nb_edges nb_vertices
// ??? "nb_faces" - all faces or only 'standalone' faces?
if (aType == TopAbs_COMPOUND)
aKind = SK_COMPOUND;
else
aKind = SK_COMPSOLID;
//theIntegers->Append(anInfo.NbSubShapes(TopAbs_COMPOUND));
//theIntegers->Append(anInfo.NbSubShapes(TopAbs_COMPSOLID));
theIntegers->Append(anInfo.NbSubShapes(TopAbs_SOLID));
theIntegers->Append(anInfo.NbSubShapes(TopAbs_FACE));
theIntegers->Append(anInfo.NbSubShapes(TopAbs_EDGE));
theIntegers->Append(anInfo.NbSubShapes(TopAbs_VERTEX));
}
break;
case TopAbs_SHELL:
{
// (+) geompy.kind.SHELL geompy.info.closed nb_faces nb_edges nb_vertices
// (+) geompy.kind.SHELL geompy.info.unclosed nb_faces nb_edges nb_vertices
aKind = SK_SHELL;
theIntegers->Append((int)anInfo.KindOfClosed());
theIntegers->Append(anInfo.NbSubShapes(TopAbs_FACE));
theIntegers->Append(anInfo.NbSubShapes(TopAbs_EDGE));
theIntegers->Append(anInfo.NbSubShapes(TopAbs_VERTEX));
}
break;
case TopAbs_WIRE:
{
// (+) geompy.kind.WIRE geompy.info.closed nb_edges nb_vertices
// (+) geompy.kind.WIRE geompy.info.unclosed nb_edges nb_vertices
aKind = SK_WIRE;
theIntegers->Append((int)anInfo.KindOfClosed());
theIntegers->Append(anInfo.NbSubShapes(TopAbs_EDGE));
theIntegers->Append(anInfo.NbSubShapes(TopAbs_VERTEX));
}
break;
case TopAbs_SOLID:
{
aKind = SK_SOLID;
GEOMAlgo_KindOfName aKN = anInfo.KindOfName();
switch (aKN)
{
case GEOMAlgo_KN_SPHERE:
// (+) geompy.kind.SPHERE xc yc zc R
{
aKind = SK_SPHERE;
gp_Pnt aC = anInfo.Location();
theDoubles->Append(aC.X());
theDoubles->Append(aC.Y());
theDoubles->Append(aC.Z());
theDoubles->Append(anInfo.Radius1());
}
break;
case GEOMAlgo_KN_CYLINDER:
// (+) geompy.kind.CYLINDER xb yb zb dx dy dz R H
{
aKind = SK_CYLINDER;
gp_Pnt aC = anInfo.Location();
theDoubles->Append(aC.X());
theDoubles->Append(aC.Y());
theDoubles->Append(aC.Z());
gp_Ax3 anAx3 = anInfo.Position();
gp_Dir aD = anAx3.Direction();
theDoubles->Append(aD.X());
theDoubles->Append(aD.Y());
theDoubles->Append(aD.Z());
theDoubles->Append(anInfo.Radius1());
theDoubles->Append(anInfo.Height());
}
break;
case GEOMAlgo_KN_BOX:
// (+) geompy.kind.BOX xc yc zc ax ay az
{
aKind = SK_BOX;
gp_Pnt aC = anInfo.Location();
theDoubles->Append(aC.X());
theDoubles->Append(aC.Y());
theDoubles->Append(aC.Z());
gp_Ax3 anAx3 = anInfo.Position();
gp_Dir aD = anAx3.Direction();
gp_Dir aX = anAx3.XDirection();
// ax ay az
if (aD.IsParallel(gp::DZ(), Precision::Angular()) &&
aX.IsParallel(gp::DX(), Precision::Angular())) {
theDoubles->Append(anInfo.Length()); // ax'
theDoubles->Append(anInfo.Width()); // ay'
theDoubles->Append(anInfo.Height()); // az'
}
else if (aD.IsParallel(gp::DZ(), Precision::Angular()) &&
aX.IsParallel(gp::DY(), Precision::Angular())) {
theDoubles->Append(anInfo.Width()); // ay'
theDoubles->Append(anInfo.Length()); // ax'
theDoubles->Append(anInfo.Height()); // az'
}
else if (aD.IsParallel(gp::DX(), Precision::Angular()) &&
aX.IsParallel(gp::DZ(), Precision::Angular())) {
theDoubles->Append(anInfo.Height()); // az'
theDoubles->Append(anInfo.Width()); // ay'
theDoubles->Append(anInfo.Length()); // ax'
}
else if (aD.IsParallel(gp::DX(), Precision::Angular()) &&
aX.IsParallel(gp::DY(), Precision::Angular())) {
theDoubles->Append(anInfo.Height()); // az'
theDoubles->Append(anInfo.Length()); // ax'
theDoubles->Append(anInfo.Width()); // ay'
}
else if (aD.IsParallel(gp::DY(), Precision::Angular()) &&
aX.IsParallel(gp::DZ(), Precision::Angular())) {
theDoubles->Append(anInfo.Width()); // ay'
theDoubles->Append(anInfo.Height()); // az'
theDoubles->Append(anInfo.Length()); // ax'
}
else if (aD.IsParallel(gp::DY(), Precision::Angular()) &&
aX.IsParallel(gp::DX(), Precision::Angular())) {
theDoubles->Append(anInfo.Length()); // ax'
theDoubles->Append(anInfo.Height()); // az'
theDoubles->Append(anInfo.Width()); // ay'
}
else {
// (+) geompy.kind.ROTATED_BOX xo yo zo zx zy zz xx xy xz ax ay az
aKind = SK_ROTATED_BOX;
// Direction and XDirection
theDoubles->Append(aD.X());
theDoubles->Append(aD.Y());
theDoubles->Append(aD.Z());
theDoubles->Append(aX.X());
theDoubles->Append(aX.Y());
theDoubles->Append(aX.Z());
// ax ay az
theDoubles->Append(anInfo.Length());
theDoubles->Append(anInfo.Width());
theDoubles->Append(anInfo.Height());
}
}
break;
case GEOMAlgo_KN_TORUS:
// (+) geompy.kind.TORUS xc yc zc dx dy dz R_1 R_2
{
aKind = SK_TORUS;
gp_Pnt aO = anInfo.Location();
theDoubles->Append(aO.X());
theDoubles->Append(aO.Y());
theDoubles->Append(aO.Z());
gp_Ax3 anAx3 = anInfo.Position();
gp_Dir aD = anAx3.Direction();
theDoubles->Append(aD.X());
theDoubles->Append(aD.Y());
theDoubles->Append(aD.Z());
theDoubles->Append(anInfo.Radius1());
theDoubles->Append(anInfo.Radius2());
}
break;
case GEOMAlgo_KN_CONE:
// (+) geompy.kind.CONE xb yb zb dx dy dz R_1 R_2 H
{
aKind = SK_CONE;
gp_Pnt aO = anInfo.Location();
theDoubles->Append(aO.X());
theDoubles->Append(aO.Y());
theDoubles->Append(aO.Z());
gp_Ax3 anAx3 = anInfo.Position();
gp_Dir aD = anAx3.Direction();
theDoubles->Append(aD.X());
theDoubles->Append(aD.Y());
theDoubles->Append(aD.Z());
theDoubles->Append(anInfo.Radius1());
theDoubles->Append(anInfo.Radius2());
theDoubles->Append(anInfo.Height());
}
break;
case GEOMAlgo_KN_POLYHEDRON:
// (+) geompy.kind.POLYHEDRON nb_faces nb_edges nb_vertices
{
aKind = SK_POLYHEDRON;
theIntegers->Append(anInfo.NbSubShapes(TopAbs_FACE));
theIntegers->Append(anInfo.NbSubShapes(TopAbs_EDGE));
theIntegers->Append(anInfo.NbSubShapes(TopAbs_VERTEX));
}
break;
default:
// (+) geompy.kind.SOLID nb_faces nb_edges nb_vertices
{
theIntegers->Append(anInfo.NbSubShapes(TopAbs_FACE));
theIntegers->Append(anInfo.NbSubShapes(TopAbs_EDGE));
theIntegers->Append(anInfo.NbSubShapes(TopAbs_VERTEX));
}
}
}
break;
case TopAbs_FACE:
{
aKind = SK_FACE;
GEOMAlgo_KindOfName aKN = anInfo.KindOfName();
switch (aKN) {
case GEOMAlgo_KN_SPHERE:
// (+) geompy.kind.SPHERE2D xc yc zc R
{
aKind = SK_SPHERE2D;
gp_Pnt aC = anInfo.Location();
theDoubles->Append(aC.X());
theDoubles->Append(aC.Y());
theDoubles->Append(aC.Z());
theDoubles->Append(anInfo.Radius1());
}
break;
case GEOMAlgo_KN_CYLINDER:
// (+) geompy.kind.CYLINDER2D xb yb zb dx dy dz R H
{
aKind = SK_CYLINDER2D;
gp_Pnt aO = anInfo.Location();
theDoubles->Append(aO.X());
theDoubles->Append(aO.Y());
theDoubles->Append(aO.Z());
gp_Ax3 anAx3 = anInfo.Position();
gp_Dir aD = anAx3.Direction();
theDoubles->Append(aD.X());
theDoubles->Append(aD.Y());
theDoubles->Append(aD.Z());
theDoubles->Append(anInfo.Radius1());
theDoubles->Append(anInfo.Height());
}
break;
case GEOMAlgo_KN_TORUS:
// (+) geompy.kind.TORUS2D xc yc zc dx dy dz R_1 R_2
{
aKind = SK_TORUS2D;
gp_Pnt aO = anInfo.Location();
theDoubles->Append(aO.X());
theDoubles->Append(aO.Y());
theDoubles->Append(aO.Z());
gp_Ax3 anAx3 = anInfo.Position();
gp_Dir aD = anAx3.Direction();
theDoubles->Append(aD.X());
theDoubles->Append(aD.Y());
theDoubles->Append(aD.Z());
theDoubles->Append(anInfo.Radius1());
theDoubles->Append(anInfo.Radius2());
}
break;
case GEOMAlgo_KN_CONE:
// (+) geompy.kind.CONE2D xc yc zc dx dy dz R_1 R_2 H
{
aKind = SK_CONE2D;
gp_Pnt aO = anInfo.Location();
theDoubles->Append(aO.X());
theDoubles->Append(aO.Y());
theDoubles->Append(aO.Z());
gp_Ax3 anAx3 = anInfo.Position();
gp_Dir aD = anAx3.Direction();
theDoubles->Append(aD.X());
theDoubles->Append(aD.Y());
theDoubles->Append(aD.Z());
theDoubles->Append(anInfo.Radius1());
theDoubles->Append(anInfo.Radius2());
theDoubles->Append(anInfo.Height());
}
break;
case GEOMAlgo_KN_DISKCIRCLE:
// (+) geompy.kind.DISK_CIRCLE xc yc zc dx dy dz R
{
aKind = SK_DISK_CIRCLE;
gp_Pnt aC = anInfo.Location();
theDoubles->Append(aC.X());
theDoubles->Append(aC.Y());
theDoubles->Append(aC.Z());
gp_Ax3 anAx3 = anInfo.Position();
gp_Dir aD = anAx3.Direction();
theDoubles->Append(aD.X());
theDoubles->Append(aD.Y());
theDoubles->Append(aD.Z());
theDoubles->Append(anInfo.Radius1());
}
break;
case GEOMAlgo_KN_DISKELLIPSE:
// (+) geompy.kind.DISK_ELLIPSE xc yc zc dx dy dz R_1 R_2
{
aKind = SK_DISK_ELLIPSE;
gp_Pnt aC = anInfo.Location();
theDoubles->Append(aC.X());
theDoubles->Append(aC.Y());
theDoubles->Append(aC.Z());
gp_Ax3 anAx3 = anInfo.Position();
gp_Dir aD = anAx3.Direction();
theDoubles->Append(aD.X());
theDoubles->Append(aD.Y());
theDoubles->Append(aD.Z());
theDoubles->Append(anInfo.Radius1());
theDoubles->Append(anInfo.Radius2());
}
break;
case GEOMAlgo_KN_RECTANGLE:
case GEOMAlgo_KN_TRIANGLE:
case GEOMAlgo_KN_QUADRANGLE:
case GEOMAlgo_KN_POLYGON:
// (+) geompy.kind.POLYGON xo yo zo dx dy dz nb_edges nb_vertices
{
aKind = SK_POLYGON;
gp_Pnt aO = anInfo.Location();
theDoubles->Append(aO.X());
theDoubles->Append(aO.Y());
theDoubles->Append(aO.Z());
gp_Ax3 anAx3 = anInfo.Position();
gp_Dir aD = anAx3.Direction();
theDoubles->Append(aD.X());
theDoubles->Append(aD.Y());
theDoubles->Append(aD.Z());
theIntegers->Append(anInfo.NbSubShapes(TopAbs_EDGE));
theIntegers->Append(anInfo.NbSubShapes(TopAbs_VERTEX));
}
break;
case GEOMAlgo_KN_PLANE: // infinite
// (+) geompy.kind.PLANE xo yo zo dx dy dz
{
aKind = SK_PLANE;
gp_Pnt aC = anInfo.Location();
theDoubles->Append(aC.X());
theDoubles->Append(aC.Y());
theDoubles->Append(aC.Z());
gp_Ax3 anAx3 = anInfo.Position();
gp_Dir aD = anAx3.Direction();
theDoubles->Append(aD.X());
theDoubles->Append(aD.Y());
theDoubles->Append(aD.Z());
}
break;
default:
if (anInfo.KindOfShape() == GEOMAlgo_KS_PLANE) {
// (+) geompy.kind.PLANAR xo yo zo dx dy dz nb_edges nb_vertices
aKind = SK_PLANAR;
gp_Pnt aC = anInfo.Location();
theDoubles->Append(aC.X());
theDoubles->Append(aC.Y());
theDoubles->Append(aC.Z());
gp_Ax3 anAx3 = anInfo.Position();
gp_Dir aD = anAx3.Direction();
theDoubles->Append(aD.X());
theDoubles->Append(aD.Y());
theDoubles->Append(aD.Z());
theIntegers->Append(anInfo.NbSubShapes(TopAbs_EDGE));
theIntegers->Append(anInfo.NbSubShapes(TopAbs_VERTEX));
}
else {
// ??? geompy.kind.FACE nb_edges nb_vertices _surface_type_id_
// (+) geompy.kind.FACE nb_edges nb_vertices
theIntegers->Append(anInfo.NbSubShapes(TopAbs_EDGE));
theIntegers->Append(anInfo.NbSubShapes(TopAbs_VERTEX));
}
}
}
break;
case TopAbs_EDGE:
{
aKind = SK_EDGE;
GEOMAlgo_KindOfName aKN = anInfo.KindOfName();
switch (aKN) {
case GEOMAlgo_KN_CIRCLE:
{
// (+) geompy.kind.CIRCLE xc yc zc dx dy dz R
aKind = SK_CIRCLE;
gp_Pnt aC = anInfo.Location();
theDoubles->Append(aC.X());
theDoubles->Append(aC.Y());
theDoubles->Append(aC.Z());
gp_Ax3 anAx3 = anInfo.Position();
gp_Dir aD = anAx3.Direction();
theDoubles->Append(aD.X());
theDoubles->Append(aD.Y());
theDoubles->Append(aD.Z());
theDoubles->Append(anInfo.Radius1());
}
break;
case GEOMAlgo_KN_ARCCIRCLE:
{
// (+) geompy.kind.ARC_CIRCLE xc yc zc dx dy dz R x1 y1 z1 x2 y2 z2
aKind = SK_ARC_CIRCLE;
gp_Pnt aC = anInfo.Location();
theDoubles->Append(aC.X());
theDoubles->Append(aC.Y());
theDoubles->Append(aC.Z());
gp_Ax3 anAx3 = anInfo.Position();
gp_Dir aD = anAx3.Direction();
theDoubles->Append(aD.X());
theDoubles->Append(aD.Y());
theDoubles->Append(aD.Z());
theDoubles->Append(anInfo.Radius1());
gp_Pnt aP1 = anInfo.Pnt1();
theDoubles->Append(aP1.X());
theDoubles->Append(aP1.Y());
theDoubles->Append(aP1.Z());
gp_Pnt aP2 = anInfo.Pnt2();
theDoubles->Append(aP2.X());
theDoubles->Append(aP2.Y());
theDoubles->Append(aP2.Z());
}
break;
case GEOMAlgo_KN_ELLIPSE:
{
// (+) geompy.kind.ELLIPSE xc yc zc dx dy dz R_1 R_2
aKind = SK_ELLIPSE;
gp_Pnt aC = anInfo.Location();
theDoubles->Append(aC.X());
theDoubles->Append(aC.Y());
theDoubles->Append(aC.Z());
gp_Ax3 anAx3 = anInfo.Position();
gp_Dir aD = anAx3.Direction();
theDoubles->Append(aD.X());
theDoubles->Append(aD.Y());
theDoubles->Append(aD.Z());
theDoubles->Append(anInfo.Radius1());
theDoubles->Append(anInfo.Radius2());
}
break;
case GEOMAlgo_KN_ARCELLIPSE:
{
// (+) geompy.kind.ARC_ELLIPSE xc yc zc dx dy dz R_1 R_2 x1 y1 z1 x2 y2 z2
aKind = SK_ARC_ELLIPSE;
gp_Pnt aC = anInfo.Location();
theDoubles->Append(aC.X());
theDoubles->Append(aC.Y());
theDoubles->Append(aC.Z());
gp_Ax3 anAx3 = anInfo.Position();
gp_Dir aD = anAx3.Direction();
theDoubles->Append(aD.X());
theDoubles->Append(aD.Y());
theDoubles->Append(aD.Z());
theDoubles->Append(anInfo.Radius1());
theDoubles->Append(anInfo.Radius2());
gp_Pnt aP1 = anInfo.Pnt1();
theDoubles->Append(aP1.X());
theDoubles->Append(aP1.Y());
theDoubles->Append(aP1.Z());
gp_Pnt aP2 = anInfo.Pnt2();
theDoubles->Append(aP2.X());
theDoubles->Append(aP2.Y());
theDoubles->Append(aP2.Z());
}
break;
case GEOMAlgo_KN_LINE:
{
// ??? geompy.kind.LINE x1 y1 z1 x2 y2 z2
// (+) geompy.kind.LINE x1 y1 z1 dx dy dz
aKind = SK_LINE;
gp_Pnt aO = anInfo.Location();
theDoubles->Append(aO.X());
theDoubles->Append(aO.Y());
theDoubles->Append(aO.Z());
gp_Dir aD = anInfo.Direction();
theDoubles->Append(aD.X());
theDoubles->Append(aD.Y());
theDoubles->Append(aD.Z());
}
break;
case GEOMAlgo_KN_SEGMENT:
{
// (+) geompy.kind.SEGMENT x1 y1 z1 x2 y2 z2
aKind = SK_SEGMENT;
gp_Pnt aP1 = anInfo.Pnt1();
theDoubles->Append(aP1.X());
theDoubles->Append(aP1.Y());
theDoubles->Append(aP1.Z());
gp_Pnt aP2 = anInfo.Pnt2();
theDoubles->Append(aP2.X());
theDoubles->Append(aP2.Y());
theDoubles->Append(aP2.Z());
}
break;
default:
// ??? geompy.kind.EDGE nb_vertices _curve_type_id_
// (+) geompy.kind.EDGE nb_vertices
theIntegers->Append(anInfo.NbSubShapes(TopAbs_VERTEX));
}
}
break;
case TopAbs_VERTEX:
{
// (+) geompy.kind.VERTEX x y z
aKind = SK_VERTEX;
gp_Pnt aP = anInfo.Location();
theDoubles->Append(aP.X());
theDoubles->Append(aP.Y());
theDoubles->Append(aP.Z());
}
break;
}
SetErrorCode(OK);
return aKind;
}
//=============================================================================
/*! Get LCS, corresponding to the given shape.
* Origin of the LCS is situated at the shape's center of mass.
* Axes of the LCS are obtained from shape's location or,
* if the shape is a planar face, from position of its plane.
*/
//=============================================================================
gp_Ax3 GEOMImpl_IMeasureOperations::GetPosition (const TopoDS_Shape& theShape)
{
gp_Ax3 aResult;
if (theShape.IsNull())
return aResult;
// Axes
aResult.Transform(theShape.Location().Transformation());
if (theShape.ShapeType() == TopAbs_FACE) {
Handle(Geom_Surface) aGS = BRep_Tool::Surface(TopoDS::Face(theShape));
if (!aGS.IsNull() && aGS->IsKind(STANDARD_TYPE(Geom_Plane))) {
Handle(Geom_Plane) aGPlane = Handle(Geom_Plane)::DownCast(aGS);
gp_Pln aPln = aGPlane->Pln();
aResult = aPln.Position();
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// In case of reverse orinetation of the face invert the plane normal
// (the face's normal does not mathc the plane's normal in this case)
if(theShape.Orientation() == TopAbs_REVERSED)
{
gp_Dir Vx = aResult.XDirection();
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gp_Dir N = aResult.Direction().Mirrored(Vx);
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gp_Pnt P = aResult.Location();
aResult = gp_Ax3(P, N, Vx);
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}
}
}
// Origin
gp_Pnt aPnt;
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TopAbs_ShapeEnum aShType = theShape.ShapeType();
if (aShType == TopAbs_VERTEX) {
aPnt = BRep_Tool::Pnt(TopoDS::Vertex(theShape));
}
else {
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if (aShType == TopAbs_COMPOUND) {
aShType = GEOMImpl_IShapesOperations::GetTypeOfSimplePart(theShape);
}
GProp_GProps aSystem;
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if (aShType == TopAbs_EDGE || aShType == TopAbs_WIRE)
BRepGProp::LinearProperties(theShape, aSystem);
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else if (aShType == TopAbs_FACE || aShType == TopAbs_SHELL)
BRepGProp::SurfaceProperties(theShape, aSystem);
else
BRepGProp::VolumeProperties(theShape, aSystem);
aPnt = aSystem.CentreOfMass();
}
aResult.SetLocation(aPnt);
return aResult;
}
//=============================================================================
/*!
* GetPosition
*/
//=============================================================================
void GEOMImpl_IMeasureOperations::GetPosition
(Handle(GEOM_Object) theShape,
Standard_Real& Ox, Standard_Real& Oy, Standard_Real& Oz,
Standard_Real& Zx, Standard_Real& Zy, Standard_Real& Zz,
Standard_Real& Xx, Standard_Real& Xy, Standard_Real& Xz)
{
SetErrorCode(KO);
//Set default values: global CS
Ox = Oy = Oz = Zx = Zy = Xy = Xz = 0.;
Zz = Xx = 1.;
if (theShape.IsNull()) return;
Handle(GEOM_Function) aRefShape = theShape->GetLastFunction();
if (aRefShape.IsNull()) return;
TopoDS_Shape aShape = aRefShape->GetValue();
if (aShape.IsNull()) {
SetErrorCode("The Objects has NULL Shape");
return;
}
try {
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#if OCC_VERSION_LARGE > 0x06010000
OCC_CATCH_SIGNALS;
#endif
gp_Ax3 anAx3 = GetPosition(aShape);
gp_Pnt anOri = anAx3.Location();
gp_Dir aDirZ = anAx3.Direction();
gp_Dir aDirX = anAx3.XDirection();
// Output values
anOri.Coord(Ox, Oy, Oz);
aDirZ.Coord(Zx, Zy, Zz);
aDirX.Coord(Xx, Xy, Xz);
}
catch (Standard_Failure) {
Handle(Standard_Failure) aFail = Standard_Failure::Caught();
SetErrorCode(aFail->GetMessageString());
return;
}
SetErrorCode(OK);
}
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//=============================================================================
/*!
* GetCentreOfMass
*/
//=============================================================================
Handle(GEOM_Object) GEOMImpl_IMeasureOperations::GetCentreOfMass
(Handle(GEOM_Object) theShape)
{
SetErrorCode(KO);
if (theShape.IsNull()) return NULL;
//Add a new CentreOfMass object
Handle(GEOM_Object) aCDG = GetEngine()->AddObject(GetDocID(), GEOM_CDG);
//Add a new CentreOfMass function
Handle(GEOM_Function) aFunction =
aCDG->AddFunction(GEOMImpl_MeasureDriver::GetID(), CDG_MEASURE);
if (aFunction.IsNull()) return NULL;
//Check if the function is set correctly
if (aFunction->GetDriverGUID() != GEOMImpl_MeasureDriver::GetID()) return NULL;
GEOMImpl_IMeasure aCI (aFunction);
Handle(GEOM_Function) aRefShape = theShape->GetLastFunction();
if (aRefShape.IsNull()) return NULL;
aCI.SetBase(aRefShape);
//Compute the CentreOfMass value
try {
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#if OCC_VERSION_LARGE > 0x06010000
OCC_CATCH_SIGNALS;
#endif
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if (!GetSolver()->ComputeFunction(aFunction)) {
SetErrorCode("Measure driver failed to compute centre of mass");
return NULL;
}
}
catch (Standard_Failure) {
Handle(Standard_Failure) aFail = Standard_Failure::Caught();
SetErrorCode(aFail->GetMessageString());
return NULL;
}
//Make a Python command
GEOM::TPythonDump(aFunction) << aCDG << " = geompy.MakeCDG(" << theShape << ")";
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SetErrorCode(OK);
return aCDG;
}
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//=============================================================================
/*!
* GetVertexByIndex
*/
//=============================================================================
Handle(GEOM_Object) GEOMImpl_IMeasureOperations::GetVertexByIndex
(Handle(GEOM_Object) theShape,
Standard_Integer theIndex)
{
SetErrorCode(KO);
if (theShape.IsNull()) return NULL;
Handle(GEOM_Function) aRefShape = theShape->GetLastFunction();
if (aRefShape.IsNull()) return NULL;
//Add a new Vertex object
Handle(GEOM_Object) aVertex = GetEngine()->AddObject(GetDocID(), GEOM_POINT);
//Add a function
Handle(GEOM_Function) aFunction =
aVertex->AddFunction(GEOMImpl_MeasureDriver::GetID(), VERTEX_BY_INDEX);
if (aFunction.IsNull()) return NULL;
//Check if the function is set correctly
if (aFunction->GetDriverGUID() != GEOMImpl_MeasureDriver::GetID()) return NULL;
GEOMImpl_IMeasure aCI (aFunction);
aCI.SetBase(aRefShape);
aCI.SetIndex(theIndex);
//Compute
try {
#if OCC_VERSION_LARGE > 0x06010000
OCC_CATCH_SIGNALS;
#endif
if (!GetSolver()->ComputeFunction(aFunction)) {
SetErrorCode("Vertex by index driver failed.");
return NULL;
}
}
catch (Standard_Failure) {
Handle(Standard_Failure) aFail = Standard_Failure::Caught();
SetErrorCode(aFail->GetMessageString());
return NULL;
}
//Make a Python command
GEOM::TPythonDump(aFunction) << aVertex << " = geompy.GetVertexByIndex(" << theShape << ", " << theIndex << ")";
SetErrorCode(OK);
return aVertex;
}
//=============================================================================
/*!
* GetNormal
*/
//=============================================================================
Handle(GEOM_Object) GEOMImpl_IMeasureOperations::GetNormal
(Handle(GEOM_Object) theFace,
Handle(GEOM_Object) theOptionalPoint)
{
SetErrorCode(KO);
if (theFace.IsNull()) return NULL;
//Add a new Normale object
Handle(GEOM_Object) aNorm = GetEngine()->AddObject(GetDocID(), GEOM_VECTOR);
//Add a new Normale function
Handle(GEOM_Function) aFunction =
aNorm->AddFunction(GEOMImpl_MeasureDriver::GetID(), VECTOR_FACE_NORMALE);
if (aFunction.IsNull()) return NULL;
//Check if the function is set correctly
if (aFunction->GetDriverGUID() != GEOMImpl_MeasureDriver::GetID()) return NULL;
GEOMImpl_IMeasure aCI (aFunction);
Handle(GEOM_Function) aFace = theFace->GetLastFunction();
if (aFace.IsNull()) return NULL;
aCI.SetBase(aFace);
if (!theOptionalPoint.IsNull()) {
Handle(GEOM_Function) anOptPnt = theOptionalPoint->GetLastFunction();
aCI.SetPoint(anOptPnt);
}
//Compute the Normale value
try {
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#if OCC_VERSION_LARGE > 0x06010000
OCC_CATCH_SIGNALS;
#endif
if (!GetSolver()->ComputeFunction(aFunction)) {
SetErrorCode("Measure driver failed to compute normake of face");
return NULL;
}
}
catch (Standard_Failure) {
Handle(Standard_Failure) aFail = Standard_Failure::Caught();
SetErrorCode(aFail->GetMessageString());
return NULL;
}
//Make a Python command
GEOM::TPythonDump pd (aFunction);
pd << aNorm << " = geompy.GetNormal(" << theFace;
if (!theOptionalPoint.IsNull()) {
pd << ", " << theOptionalPoint;
}
pd << ")";
SetErrorCode(OK);
return aNorm;
}
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//=============================================================================
/*!
* GetBasicProperties
*/
//=============================================================================
void GEOMImpl_IMeasureOperations::GetBasicProperties (Handle(GEOM_Object) theShape,
Standard_Real& theLength,
Standard_Real& theSurfArea,
Standard_Real& theVolume)
{
SetErrorCode(KO);
if (theShape.IsNull()) return;
Handle(GEOM_Function) aRefShape = theShape->GetLastFunction();
if (aRefShape.IsNull()) return;
TopoDS_Shape aShape = aRefShape->GetValue();
if (aShape.IsNull()) {
SetErrorCode("The Objects has NULL Shape");
return;
}
//Compute the parameters
GProp_GProps LProps, SProps;
try {
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#if OCC_VERSION_LARGE > 0x06010000
OCC_CATCH_SIGNALS;
#endif
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BRepGProp::LinearProperties(aShape, LProps);
theLength = LProps.Mass();
BRepGProp::SurfaceProperties(aShape, SProps);
theSurfArea = SProps.Mass();
theVolume = 0.0;
if (aShape.ShapeType() < TopAbs_SHELL) {
for (TopExp_Explorer Exp (aShape, TopAbs_SOLID); Exp.More(); Exp.Next()) {
2012-08-09 13:58:02 +06:00
GProp_GProps VProps;
BRepGProp::VolumeProperties(Exp.Current(), VProps);
theVolume += VProps.Mass();
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}
}
}
catch (Standard_Failure) {
Handle(Standard_Failure) aFail = Standard_Failure::Caught();
SetErrorCode(aFail->GetMessageString());
return;
}
SetErrorCode(OK);
}
//=============================================================================
/*!
* GetInertia
*/
//=============================================================================
void GEOMImpl_IMeasureOperations::GetInertia
(Handle(GEOM_Object) theShape,
Standard_Real& I11, Standard_Real& I12, Standard_Real& I13,
Standard_Real& I21, Standard_Real& I22, Standard_Real& I23,
Standard_Real& I31, Standard_Real& I32, Standard_Real& I33,
Standard_Real& Ix , Standard_Real& Iy , Standard_Real& Iz)
{
SetErrorCode(KO);
if (theShape.IsNull()) return;
Handle(GEOM_Function) aRefShape = theShape->GetLastFunction();
if (aRefShape.IsNull()) return;
TopoDS_Shape aShape = aRefShape->GetValue();
if (aShape.IsNull()) {
SetErrorCode("The Objects has NULL Shape");
return;
}
//Compute the parameters
GProp_GProps System;
try {
2012-08-09 13:58:02 +06:00
#if OCC_VERSION_LARGE > 0x06010000
OCC_CATCH_SIGNALS;
#endif
2004-12-01 15:39:14 +05:00
if (aShape.ShapeType() == TopAbs_VERTEX ||
aShape.ShapeType() == TopAbs_EDGE ||
aShape.ShapeType() == TopAbs_WIRE) {
BRepGProp::LinearProperties(aShape, System);
} else if (aShape.ShapeType() == TopAbs_FACE ||
aShape.ShapeType() == TopAbs_SHELL) {
BRepGProp::SurfaceProperties(aShape, System);
} else {
BRepGProp::VolumeProperties(aShape, System);
}
gp_Mat I = System.MatrixOfInertia();
I11 = I(1,1);
I12 = I(1,2);
I13 = I(1,3);
I21 = I(2,1);
I22 = I(2,2);
I23 = I(2,3);
I31 = I(3,1);
I32 = I(3,2);
I33 = I(3,3);
GProp_PrincipalProps Pr = System.PrincipalProperties();
Pr.Moments(Ix,Iy,Iz);
}
catch (Standard_Failure) {
Handle(Standard_Failure) aFail = Standard_Failure::Caught();
SetErrorCode(aFail->GetMessageString());
return;
}
SetErrorCode(OK);
}
//=============================================================================
/*!
* GetBoundingBox
*/
//=============================================================================
void GEOMImpl_IMeasureOperations::GetBoundingBox
(Handle(GEOM_Object) theShape,
Standard_Real& Xmin, Standard_Real& Xmax,
Standard_Real& Ymin, Standard_Real& Ymax,
Standard_Real& Zmin, Standard_Real& Zmax)
{
SetErrorCode(KO);
if (theShape.IsNull()) return;
Handle(GEOM_Function) aRefShape = theShape->GetLastFunction();
if (aRefShape.IsNull()) return;
TopoDS_Shape aShape = aRefShape->GetValue();
if (aShape.IsNull()) {
SetErrorCode("The Objects has NULL Shape");
return;
}
//Compute the parameters
Bnd_Box B;
try {
2012-08-09 13:58:02 +06:00
#if OCC_VERSION_LARGE > 0x06010000
OCC_CATCH_SIGNALS;
#endif
2012-10-08 17:16:36 +06:00
BRepBuilderAPI_Copy aCopyTool (aShape);
if (!aCopyTool.IsDone()) {
SetErrorCode("GetBoundingBox Error: Bad shape detected");
return;
}
aShape = aCopyTool.Shape();
// remove triangulation to obtain more exact boundaries
BRepTools::Clean(aShape);
2004-12-01 15:39:14 +05:00
BRepBndLib::Add(aShape, B);
B.Get(Xmin, Ymin, Zmin, Xmax, Ymax, Zmax);
}
catch (Standard_Failure) {
Handle(Standard_Failure) aFail = Standard_Failure::Caught();
SetErrorCode(aFail->GetMessageString());
return;
}
SetErrorCode(OK);
}
//=============================================================================
/*!
* GetTolerance
*/
//=============================================================================
void GEOMImpl_IMeasureOperations::GetTolerance
(Handle(GEOM_Object) theShape,
Standard_Real& FaceMin, Standard_Real& FaceMax,
Standard_Real& EdgeMin, Standard_Real& EdgeMax,
Standard_Real& VertMin, Standard_Real& VertMax)
{
SetErrorCode(KO);
if (theShape.IsNull()) return;
Handle(GEOM_Function) aRefShape = theShape->GetLastFunction();
if (aRefShape.IsNull()) return;
TopoDS_Shape aShape = aRefShape->GetValue();
if (aShape.IsNull()) {
SetErrorCode("The Objects has NULL Shape");
return;
}
//Compute the parameters
Standard_Real T;
FaceMin = EdgeMin = VertMin = RealLast();
FaceMax = EdgeMax = VertMax = -RealLast();
try {
2012-08-09 13:58:02 +06:00
#if OCC_VERSION_LARGE > 0x06010000
OCC_CATCH_SIGNALS;
#endif
2004-12-01 15:39:14 +05:00
for (TopExp_Explorer ExF (aShape, TopAbs_FACE); ExF.More(); ExF.Next()) {
TopoDS_Face Face = TopoDS::Face(ExF.Current());
T = BRep_Tool::Tolerance(Face);
if (T > FaceMax)
2012-08-09 13:58:02 +06:00
FaceMax = T;
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if (T < FaceMin)
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FaceMin = T;
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}
for (TopExp_Explorer ExE (aShape, TopAbs_EDGE); ExE.More(); ExE.Next()) {
TopoDS_Edge Edge = TopoDS::Edge(ExE.Current());
T = BRep_Tool::Tolerance(Edge);
if (T > EdgeMax)
2012-08-09 13:58:02 +06:00
EdgeMax = T;
2004-12-01 15:39:14 +05:00
if (T < EdgeMin)
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EdgeMin = T;
2004-12-01 15:39:14 +05:00
}
for (TopExp_Explorer ExV (aShape, TopAbs_VERTEX); ExV.More(); ExV.Next()) {
TopoDS_Vertex Vertex = TopoDS::Vertex(ExV.Current());
T = BRep_Tool::Tolerance(Vertex);
if (T > VertMax)
2012-08-09 13:58:02 +06:00
VertMax = T;
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if (T < VertMin)
2012-08-09 13:58:02 +06:00
VertMin = T;
2004-12-01 15:39:14 +05:00
}
}
catch (Standard_Failure) {
Handle(Standard_Failure) aFail = Standard_Failure::Caught();
SetErrorCode(aFail->GetMessageString());
return;
}
SetErrorCode(OK);
}
//=============================================================================
/*!
* CheckShape
*/
//=============================================================================
bool GEOMImpl_IMeasureOperations::CheckShape (Handle(GEOM_Object) theShape,
const Standard_Boolean theIsCheckGeom,
2004-12-01 15:39:14 +05:00
TCollection_AsciiString& theDump)
{
SetErrorCode(KO);
if (theShape.IsNull()) return false;
Handle(GEOM_Function) aRefShape = theShape->GetLastFunction();
if (aRefShape.IsNull()) return false;
TopoDS_Shape aShape = aRefShape->GetValue();
if (aShape.IsNull()) {
SetErrorCode("The Objects has NULL Shape");
return false;
}
//Compute the parameters
bool isValid = false;
try {
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#if OCC_VERSION_LARGE > 0x06010000
OCC_CATCH_SIGNALS;
#endif
BRepCheck_Analyzer ana (aShape, theIsCheckGeom);
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if (ana.IsValid()) {
theDump.Clear();
isValid = true;
} else {
StructuralDump(ana, aShape, theDump);
}
}
catch (Standard_Failure) {
Handle(Standard_Failure) aFail = Standard_Failure::Caught();
SetErrorCode(aFail->GetMessageString());
return false;
}
SetErrorCode(OK);
return isValid;
}
2012-08-09 13:58:02 +06:00
//=============================================================================
/*!
* CheckSelfIntersections
*/
//=============================================================================
bool GEOMImpl_IMeasureOperations::CheckSelfIntersections
(Handle(GEOM_Object) theShape,
Handle(TColStd_HSequenceOfInteger)& theIntersections)
{
SetErrorCode(KO);
bool isGood = false;
if (theIntersections.IsNull())
theIntersections = new TColStd_HSequenceOfInteger;
else
theIntersections->Clear();
if (theShape.IsNull())
return isGood;
Handle(GEOM_Function) aRefShape = theShape->GetLastFunction();
if (aRefShape.IsNull()) return isGood;
TopoDS_Shape aShape = aRefShape->GetValue();
if (aShape.IsNull()) return isGood;
// 0. Prepare data
BRep_Builder aBB;
TopoDS_Compound aCS;
TopoDS_Shape aScopy;
NMTDS_Tools::CopyShape(aShape, aScopy);
// Map sub-shapes and their indices
TopTools_IndexedMapOfShape anIndices;
TopExp::MapShapes(aScopy, anIndices);
aBB.MakeCompound(aCS);
aBB.Add(aCS, aScopy);
NMTTools_CheckerSI aCSI; // checker of self-interferences
aCSI.SetCompositeShape(aCS);
// 1. Launch the checker
aCSI.Perform();
Standard_Integer iErr = aCSI.StopStatus();
if (iErr) {
return false; // Error
}
isGood = true;
// 2. Take the shapes from DS
const NMTDS_ShapesDataStructure& aDS = *(aCSI.DS());
Standard_Integer aNbS = aDS.NumberOfShapesOfTheObject();
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// 3. Get the pairs of interfered shapes
2012-08-09 13:58:02 +06:00
NMTDS_PInterfPool pIP = aCSI.IP();
//const NMTDS_ListOfPassKeyBoolean& aLPKB = pIP->Get();
const NMTDS_ListOfPairBoolean& aLPKB = pIP->Get();
Standard_Integer n1, n2;
//NMTDS_ListIteratorOfListOfPassKeyBoolean aIt;
NMTDS_ListIteratorOfListOfPairBoolean aIt;
aIt.Initialize(aLPKB);
for (; aIt.More(); aIt.Next()) {
//const NMTDS_PassKeyBoolean& aPKB = aIt.Value();
const NMTDS_PairBoolean& aPKB = aIt.Value();
aPKB.Ids(n1, n2);
if (n1 > aNbS || n2 > aNbS)
return false; // Error
const TopoDS_Shape& aS1 = aDS.Shape(n1);
const TopoDS_Shape& aS2 = aDS.Shape(n2);
theIntersections->Append(anIndices.FindIndex(aS1));
theIntersections->Append(anIndices.FindIndex(aS2));
isGood = false;
}
SetErrorCode(OK);
return isGood;
}
//=============================================================================
/*!
* IsGoodForSolid
*/
//=============================================================================
TCollection_AsciiString GEOMImpl_IMeasureOperations::IsGoodForSolid (Handle(GEOM_Object) theShape)
{
SetErrorCode(KO);
TCollection_AsciiString aRes = "";
if (theShape.IsNull()) {
aRes = "WRN_NULL_OBJECT_OR_SHAPE";
}
else {
Handle(GEOM_Function) aRefShape = theShape->GetLastFunction();
if (aRefShape.IsNull()) {
aRes = "WRN_NULL_OBJECT_OR_SHAPE";
}
else {
TopoDS_Shape aShape = aRefShape->GetValue();
if (aShape.IsNull()) {
aRes = "WRN_NULL_OBJECT_OR_SHAPE";
}
else {
if (aShape.ShapeType() == TopAbs_COMPOUND) {
TopoDS_Iterator It (aShape, Standard_True, Standard_True);
if (It.More()) aShape = It.Value();
}
if (aShape.ShapeType() == TopAbs_SHELL) {
BRepCheck_Shell chkShell (TopoDS::Shell(aShape));
if (chkShell.Closed() == BRepCheck_NotClosed) {
aRes = "WRN_SHAPE_UNCLOSED";
}
}
else {
aRes = "WRN_SHAPE_NOT_SHELL";
}
}
}
}
if (aRes.IsEmpty())
SetErrorCode(OK);
return aRes;
}
2004-12-01 15:39:14 +05:00
//=============================================================================
/*!
* WhatIs
*/
//=============================================================================
TCollection_AsciiString GEOMImpl_IMeasureOperations::WhatIs (Handle(GEOM_Object) theShape)
{
SetErrorCode(KO);
TCollection_AsciiString Astr;
if (theShape.IsNull()) return Astr;
Handle(GEOM_Function) aRefShape = theShape->GetLastFunction();
if (aRefShape.IsNull()) return Astr;
TopoDS_Shape aShape = aRefShape->GetValue();
if (aShape.IsNull()) {
SetErrorCode("The Objects has NULL Shape");
return Astr;
}
//Compute the parameters
if (aShape.ShapeType() == TopAbs_EDGE) {
if (BRep_Tool::Degenerated(TopoDS::Edge(aShape))) {
Astr = Astr + " It is a degenerated edge \n";
}
}
Astr = Astr + " Number of sub-shapes : \n";
try {
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#if OCC_VERSION_LARGE > 0x06010000
OCC_CATCH_SIGNALS;
#endif
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int iType, nbTypes [TopAbs_SHAPE];
for (iType = 0; iType < TopAbs_SHAPE; ++iType)
nbTypes[iType] = 0;
nbTypes[aShape.ShapeType()]++;
TopTools_MapOfShape aMapOfShape;
aMapOfShape.Add(aShape);
TopTools_ListOfShape aListOfShape;
aListOfShape.Append(aShape);
TopTools_ListIteratorOfListOfShape itL (aListOfShape);
for (; itL.More(); itL.Next()) {
TopoDS_Iterator it (itL.Value());
for (; it.More(); it.Next()) {
TopoDS_Shape s = it.Value();
if (aMapOfShape.Add(s)) {
aListOfShape.Append(s);
nbTypes[s.ShapeType()]++;
}
}
}
Astr = Astr + " VERTEX : " + TCollection_AsciiString(nbTypes[TopAbs_VERTEX]) + "\n";
Astr = Astr + " EDGE : " + TCollection_AsciiString(nbTypes[TopAbs_EDGE]) + "\n";
Astr = Astr + " WIRE : " + TCollection_AsciiString(nbTypes[TopAbs_WIRE]) + "\n";
Astr = Astr + " FACE : " + TCollection_AsciiString(nbTypes[TopAbs_FACE]) + "\n";
Astr = Astr + " SHELL : " + TCollection_AsciiString(nbTypes[TopAbs_SHELL]) + "\n";
Astr = Astr + " SOLID : " + TCollection_AsciiString(nbTypes[TopAbs_SOLID]) + "\n";
Astr = Astr + " COMPSOLID : " + TCollection_AsciiString(nbTypes[TopAbs_COMPSOLID]) + "\n";
Astr = Astr + " COMPOUND : " + TCollection_AsciiString(nbTypes[TopAbs_COMPOUND]) + "\n";
Astr = Astr + " SHAPE : " + TCollection_AsciiString(aMapOfShape.Extent());
}
catch (Standard_Failure) {
Handle(Standard_Failure) aFail = Standard_Failure::Caught();
SetErrorCode(aFail->GetMessageString());
return Astr;
}
SetErrorCode(OK);
return Astr;
}
2009-02-13 17:16:39 +05:00
//=======================================================================
//function : CheckSingularCase
//purpose : auxilary for GetMinDistance()
// workaround for bugs 19899, 19908 and 19910 from Mantis
//=======================================================================
static double CheckSingularCase(const TopoDS_Shape& aSh1,
const TopoDS_Shape& aSh2,
gp_Pnt& Ptmp1, gp_Pnt& Ptmp2)
{
bool IsChange1 = false;
double AddDist1 = 0.0;
TopExp_Explorer anExp;
TopoDS_Shape tmpSh1, tmpSh2;
int nbf = 0;
for ( anExp.Init( aSh1, TopAbs_FACE ); anExp.More(); anExp.Next() ) {
nbf++;
tmpSh1 = anExp.Current();
}
if(nbf==1) {
TopoDS_Shape sh = aSh1;
while(sh.ShapeType()==TopAbs_COMPOUND) {
TopoDS_Iterator it(sh);
sh = it.Value();
}
Handle(Geom_Surface) S = BRep_Tool::Surface(TopoDS::Face(tmpSh1));
if( S->IsKind(STANDARD_TYPE(Geom_SphericalSurface)) ||
S->IsKind(STANDARD_TYPE(Geom_ToroidalSurface)) ) {
if( sh.ShapeType()==TopAbs_SHELL || sh.ShapeType()==TopAbs_FACE ) {
// non solid case
double U1,U2,V1,V2;
2012-08-09 13:58:02 +06:00
// changes for 0020677: EDF 1219 GEOM: MinDistance gives 0 instead of 20.88
//S->Bounds(U1,U2,V1,V2); changed by
ShapeAnalysis::GetFaceUVBounds(TopoDS::Face(tmpSh1),U1,U2,V1,V2);
// end of changes for 020677 (dmv)
Handle(Geom_RectangularTrimmedSurface) TrS1 =
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new Geom_RectangularTrimmedSurface(S,U1,(U1+U2)/2.,V1,V2);
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Handle(Geom_RectangularTrimmedSurface) TrS2 =
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new Geom_RectangularTrimmedSurface(S,(U1+U2)/2.,U2,V1,V2);
BRep_Builder B;
TopoDS_Face F1,F2;
TopoDS_Compound Comp;
B.MakeCompound(Comp);
B.MakeFace(F1,TrS1,1.e-7);
B.Add(Comp,F1);
B.MakeFace(F2,TrS2,1.e-7);
B.Add(Comp,F2);
Handle(ShapeFix_Shape) sfs = new ShapeFix_Shape;
sfs->Init(Comp);
sfs->SetPrecision(1.e-6);
sfs->SetMaxTolerance(1.0);
sfs->Perform();
tmpSh1 = sfs->Shape();
IsChange1 = true;
}
else {
if( S->IsKind(STANDARD_TYPE(Geom_SphericalSurface)) ) {
Handle(Geom_SphericalSurface) SS = Handle(Geom_SphericalSurface)::DownCast(S);
gp_Pnt PC = SS->Location();
BRep_Builder B;
TopoDS_Vertex V;
B.MakeVertex(V,PC,1.e-7);
tmpSh1 = V;
AddDist1 = SS->Radius();
IsChange1 = true;
}
else {
Handle(Geom_ToroidalSurface) TS = Handle(Geom_ToroidalSurface)::DownCast(S);
gp_Ax3 ax3 = TS->Position();
Handle(Geom_Circle) C = new Geom_Circle(ax3.Ax2(),TS->MajorRadius());
BRep_Builder B;
TopoDS_Edge E;
B.MakeEdge(E,C,1.e-7);
tmpSh1 = E;
AddDist1 = TS->MinorRadius();
IsChange1 = true;
}
}
}
else
tmpSh1 = aSh1;
}
else
tmpSh1 = aSh1;
bool IsChange2 = false;
double AddDist2 = 0.0;
nbf = 0;
for ( anExp.Init( aSh2, TopAbs_FACE ); anExp.More(); anExp.Next() ) {
nbf++;
tmpSh2 = anExp.Current();
}
if(nbf==1) {
TopoDS_Shape sh = aSh2;
while(sh.ShapeType()==TopAbs_COMPOUND) {
TopoDS_Iterator it(sh);
sh = it.Value();
}
Handle(Geom_Surface) S = BRep_Tool::Surface(TopoDS::Face(tmpSh2));
if( S->IsKind(STANDARD_TYPE(Geom_SphericalSurface)) ||
S->IsKind(STANDARD_TYPE(Geom_ToroidalSurface)) ) {
if( sh.ShapeType()==TopAbs_SHELL || sh.ShapeType()==TopAbs_FACE ) {
// non solid case
double U1,U2,V1,V2;
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//S->Bounds(U1,U2,V1,V2);
ShapeAnalysis::GetFaceUVBounds(TopoDS::Face(tmpSh2),U1,U2,V1,V2);
Handle(Geom_RectangularTrimmedSurface) TrS1 =
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new Geom_RectangularTrimmedSurface(S,U1,(U1+U2)/2.,V1,V2);
2012-08-09 13:58:02 +06:00
Handle(Geom_RectangularTrimmedSurface) TrS2 =
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new Geom_RectangularTrimmedSurface(S,(U1+U2)/2.,U2,V1,V2);
BRep_Builder B;
TopoDS_Face F1,F2;
TopoDS_Compound Comp;
B.MakeCompound(Comp);
B.MakeFace(F1,TrS1,1.e-7);
B.Add(Comp,F1);
B.MakeFace(F2,TrS2,1.e-7);
B.Add(Comp,F2);
Handle(ShapeFix_Shape) sfs = new ShapeFix_Shape;
sfs->Init(Comp);
sfs->SetPrecision(1.e-6);
sfs->SetMaxTolerance(1.0);
sfs->Perform();
tmpSh2 = sfs->Shape();
IsChange2 = true;
}
else {
if( S->IsKind(STANDARD_TYPE(Geom_SphericalSurface)) ) {
Handle(Geom_SphericalSurface) SS = Handle(Geom_SphericalSurface)::DownCast(S);
gp_Pnt PC = SS->Location();
BRep_Builder B;
TopoDS_Vertex V;
B.MakeVertex(V,PC,1.e-7);
tmpSh2 = V;
AddDist2 = SS->Radius();
IsChange2 = true;
}
else if( S->IsKind(STANDARD_TYPE(Geom_ToroidalSurface)) ) {
Handle(Geom_ToroidalSurface) TS = Handle(Geom_ToroidalSurface)::DownCast(S);
gp_Ax3 ax3 = TS->Position();
Handle(Geom_Circle) C = new Geom_Circle(ax3.Ax2(),TS->MajorRadius());
BRep_Builder B;
TopoDS_Edge E;
B.MakeEdge(E,C,1.e-7);
tmpSh2 = E;
AddDist2 = TS->MinorRadius();
IsChange2 = true;
}
}
}
else
tmpSh2 = aSh2;
}
else
tmpSh2 = aSh2;
if( !IsChange1 && !IsChange2 )
return -2.0;
BRepExtrema_DistShapeShape dst(tmpSh1,tmpSh2);
if (dst.IsDone()) {
double MinDist = 1.e9;
gp_Pnt PMin1, PMin2, P1, P2;
for (int i = 1; i <= dst.NbSolution(); i++) {
P1 = dst.PointOnShape1(i);
P2 = dst.PointOnShape2(i);
Standard_Real Dist = P1.Distance(P2);
if (MinDist > Dist) {
MinDist = Dist;
PMin1 = P1;
PMin2 = P2;
}
}
if(MinDist<1.e-7) {
Ptmp1 = PMin1;
Ptmp2 = PMin2;
}
else {
gp_Dir aDir(gp_Vec(PMin1,PMin2));
if( MinDist > (AddDist1+AddDist2) ) {
Ptmp1 = gp_Pnt( PMin1.X() + aDir.X()*AddDist1,
PMin1.Y() + aDir.Y()*AddDist1,
PMin1.Z() + aDir.Z()*AddDist1 );
Ptmp2 = gp_Pnt( PMin2.X() - aDir.X()*AddDist2,
PMin2.Y() - aDir.Y()*AddDist2,
PMin2.Z() - aDir.Z()*AddDist2 );
return (MinDist - AddDist1 - AddDist2);
}
else {
if( AddDist1 > 0 ) {
Ptmp1 = gp_Pnt( PMin1.X() + aDir.X()*AddDist1,
PMin1.Y() + aDir.Y()*AddDist1,
PMin1.Z() + aDir.Z()*AddDist1 );
Ptmp2 = Ptmp1;
}
else {
Ptmp2 = gp_Pnt( PMin2.X() - aDir.X()*AddDist2,
PMin2.Y() - aDir.Y()*AddDist2,
PMin2.Z() - aDir.Z()*AddDist2 );
Ptmp1 = Ptmp2;
}
}
}
double res = MinDist - AddDist1 - AddDist2;
if(res<0.) res = 0.0;
return res;
}
return -2.0;
}
/* old variant
static bool CheckSingularCase(const TopoDS_Shape& aSh1,
const TopoDS_Shape& aSh2,
gp_Pnt& Ptmp)
{
TopExp_Explorer anExp;
TopoDS_Shape tmpSh1, tmpSh2;
int nbf = 0;
for ( anExp.Init( aSh1, TopAbs_FACE ); anExp.More(); anExp.Next() ) {
nbf++;
tmpSh1 = anExp.Current();
}
if(nbf==1) {
Handle(Geom_Surface) S1 = BRep_Tool::Surface(TopoDS::Face(tmpSh1));
if( S1->IsKind(STANDARD_TYPE(Geom_SphericalSurface)) ||
S1->IsKind(STANDARD_TYPE(Geom_ToroidalSurface)) ) {
nbf = 0;
for ( anExp.Init( aSh2, TopAbs_FACE ); anExp.More(); anExp.Next() ) {
nbf++;
tmpSh2 = anExp.Current();
Handle(Geom_Surface) S2 = BRep_Tool::Surface(TopoDS::Face(tmpSh2));
GeomAPI_IntSS ISS(S1,S2,1.e-7);
if(ISS.IsDone()) {
for(int i=1; i<=ISS.NbLines(); i++) {
Handle(Geom_Curve) C3d = ISS.Line(i);
BRep_Builder B;
TopoDS_Edge E;
B.MakeEdge(E,C3d,1.e-7);
BRepExtrema_DistShapeShape dst(tmpSh2,E);
if (dst.IsDone()) {
gp_Pnt PMin1, PMin2, P1, P2;
double MinDist = 1.e9;
for (int i = 1; i <= dst.NbSolution(); i++) {
P1 = dst.PointOnShape1(i);
P2 = dst.PointOnShape2(i);
Standard_Real Dist = P1.Distance(P2);
if (MinDist > Dist) {
MinDist = Dist;
Ptmp = P1;
}
}
if(MinDist<1.e-7)
return true;
}
}
}
}
}
}
nbf = 0;
for ( anExp.Init( aSh2, TopAbs_FACE ); anExp.More(); anExp.Next() ) {
nbf++;
tmpSh1 = anExp.Current();
}
if(nbf==1) {
Handle(Geom_Surface) S1 = BRep_Tool::Surface(TopoDS::Face(tmpSh1));
if( S1->IsKind(STANDARD_TYPE(Geom_SphericalSurface)) ||
S1->IsKind(STANDARD_TYPE(Geom_ToroidalSurface)) ) {
nbf = 0;
for ( anExp.Init( aSh1, TopAbs_FACE ); anExp.More(); anExp.Next() ) {
nbf++;
tmpSh2 = anExp.Current();
Handle(Geom_Surface) S2 = BRep_Tool::Surface(TopoDS::Face(tmpSh2));
GeomAPI_IntSS ISS(S1,S2,1.e-7);
if(ISS.IsDone()) {
for(int i=1; i<=ISS.NbLines(); i++) {
Handle(Geom_Curve) C3d = ISS.Line(i);
BRep_Builder B;
TopoDS_Edge E;
B.MakeEdge(E,C3d,1.e-7);
BRepExtrema_DistShapeShape dst(tmpSh2,E);
if (dst.IsDone()) {
gp_Pnt P1,P2;
double MinDist = 1.e9;
for (int i = 1; i <= dst.NbSolution(); i++) {
P1 = dst.PointOnShape1(i);
P2 = dst.PointOnShape2(i);
Standard_Real Dist = P1.Distance(P2);
if (MinDist > Dist) {
MinDist = Dist;
Ptmp = P1;
}
}
if(MinDist<1.e-7)
return true;
}
}
}
}
}
}
return false;
}
*/
2012-08-09 13:58:02 +06:00
//=============================================================================
/*!
* AreCoordsInside
*/
//=============================================================================
std::vector<bool> GEOMImpl_IMeasureOperations::AreCoordsInside(Handle(GEOM_Object) theShape,
const std::vector<double>& coords,
double tolerance)
{
std::vector<bool> res;
if (!theShape.IsNull()) {
Handle(GEOM_Function) aRefShape = theShape->GetLastFunction();
if (!aRefShape.IsNull()) {
TopoDS_Shape aShape = aRefShape->GetValue();
if (!aShape.IsNull()) {
BRepClass3d_SolidClassifier SC(aShape);
unsigned int nb_points = coords.size()/3;
for (int i = 0; i < nb_points; i++) {
double x = coords[3*i];
double y = coords[3*i+1];
double z = coords[3*i+2];
gp_Pnt aPnt(x, y, z);
SC.Perform(aPnt, tolerance);
res.push_back( ( SC.State() == TopAbs_IN ) || ( SC.State() == TopAbs_ON ) );
}
}
}
}
return res;
}
2004-12-01 15:39:14 +05:00
//=============================================================================
/*!
* GetMinDistance
*/
//=============================================================================
Standard_Real GEOMImpl_IMeasureOperations::GetMinDistance
(Handle(GEOM_Object) theShape1, Handle(GEOM_Object) theShape2,
Standard_Real& X1, Standard_Real& Y1, Standard_Real& Z1,
Standard_Real& X2, Standard_Real& Y2, Standard_Real& Z2)
{
SetErrorCode(KO);
Standard_Real MinDist = 1.e9;
if (theShape1.IsNull() || theShape2.IsNull()) return MinDist;
Handle(GEOM_Function) aRefShape1 = theShape1->GetLastFunction();
Handle(GEOM_Function) aRefShape2 = theShape2->GetLastFunction();
if (aRefShape1.IsNull() || aRefShape2.IsNull()) return MinDist;
TopoDS_Shape aShape1 = aRefShape1->GetValue();
TopoDS_Shape aShape2 = aRefShape2->GetValue();
if (aShape1.IsNull() || aShape2.IsNull()) {
SetErrorCode("One of Objects has NULL Shape");
return MinDist;
}
//Compute the parameters
try {
2012-08-09 13:58:02 +06:00
#if OCC_VERSION_LARGE > 0x06010000
OCC_CATCH_SIGNALS;
#endif
2009-02-13 17:16:39 +05:00
2012-08-09 13:58:02 +06:00
// Issue 0020231: A min distance bug with torus and vertex.
// Make GetMinDistance() return zero if a sole VERTEX is inside any of SOLIDs
// which of shapes consists of only one vertex?
TopExp_Explorer exp1(aShape1,TopAbs_VERTEX), exp2(aShape2,TopAbs_VERTEX);
TopoDS_Shape V1 = exp1.More() ? exp1.Current() : TopoDS_Shape();
TopoDS_Shape V2 = exp2.More() ? exp2.Current() : TopoDS_Shape();
exp1.Next(); exp2.Next();
if ( exp1.More() ) V1.Nullify();
if ( exp2.More() ) V2.Nullify();
// vertex and container of solids
TopoDS_Shape V = V1.IsNull() ? V2 : V1;
TopoDS_Shape S = V1.IsNull() ? aShape1 : aShape2;
if ( !V.IsNull() ) {
// classify vertex against solids
gp_Pnt p = BRep_Tool::Pnt( TopoDS::Vertex( V ) );
for ( exp1.Init( S, TopAbs_SOLID ); exp1.More(); exp1.Next() ) {
BRepClass3d_SolidClassifier classifier( exp1.Current(), p, 1e-6);
if ( classifier.State() == TopAbs_IN ) {
p.Coord(X1, Y1, Z1);
p.Coord(X2, Y2, Z2);
SetErrorCode(OK);
return 0.0;
}
}
}
// End Issue 0020231
2009-02-13 17:16:39 +05:00
// skl 30.06.2008
// additional workaround for bugs 19899, 19908 and 19910 from Mantis
gp_Pnt Ptmp1, Ptmp2;
double dist = CheckSingularCase(aShape1, aShape2, Ptmp1, Ptmp2);
if(dist>-1.0) {
Ptmp1.Coord(X1, Y1, Z1);
Ptmp2.Coord(X2, Y2, Z2);
SetErrorCode(OK);
return dist;
}
2004-12-01 15:39:14 +05:00
BRepExtrema_DistShapeShape dst (aShape1, aShape2);
if (dst.IsDone()) {
gp_Pnt PMin1, PMin2, P1, P2;
for (int i = 1; i <= dst.NbSolution(); i++) {
2012-08-09 13:58:02 +06:00
P1 = dst.PointOnShape1(i);
P2 = dst.PointOnShape2(i);
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2012-08-09 13:58:02 +06:00
Standard_Real Dist = P1.Distance(P2);
if (MinDist > Dist) {
MinDist = Dist;
2004-12-01 15:39:14 +05:00
PMin1 = P1;
PMin2 = P2;
}
}
PMin1.Coord(X1, Y1, Z1);
PMin2.Coord(X2, Y2, Z2);
}
}
catch (Standard_Failure) {
Handle(Standard_Failure) aFail = Standard_Failure::Caught();
SetErrorCode(aFail->GetMessageString());
return MinDist;
}
SetErrorCode(OK);
return MinDist;
}
//=======================================================================
/*!
* Get coordinates of point
*/
2004-12-01 15:39:14 +05:00
//=======================================================================
void GEOMImpl_IMeasureOperations::PointCoordinates (Handle(GEOM_Object) theShape,
Standard_Real& theX, Standard_Real& theY, Standard_Real& theZ)
2004-12-01 15:39:14 +05:00
{
SetErrorCode(KO);
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if (theShape.IsNull())
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return;
Handle(GEOM_Function) aRefShape = theShape->GetLastFunction();
if (aRefShape.IsNull())
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return;
TopoDS_Shape aShape = aRefShape->GetValue();
if (aShape.IsNull() || aShape.ShapeType() != TopAbs_VERTEX)
2004-12-01 15:39:14 +05:00
{
SetErrorCode( "Shape must be a vertex" );
return;
}
try {
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#if OCC_VERSION_LARGE > 0x06010000
OCC_CATCH_SIGNALS;
#endif
2004-12-01 15:39:14 +05:00
gp_Pnt aPnt = BRep_Tool::Pnt( TopoDS::Vertex( aShape ) );
theX = aPnt.X();
theY = aPnt.Y();
theZ = aPnt.Z();
SetErrorCode(OK);
2004-12-01 15:39:14 +05:00
}
catch (Standard_Failure)
2004-12-01 15:39:14 +05:00
{
Handle(Standard_Failure) aFail = Standard_Failure::Caught();
SetErrorCode( aFail->GetMessageString() );
}
}
//=======================================================================
/*!
* Compute angle (in degrees) between two lines
*/
//=======================================================================
Standard_Real GEOMImpl_IMeasureOperations::GetAngle (Handle(GEOM_Object) theLine1,
Handle(GEOM_Object) theLine2)
{
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if (theLine1->GetType() == GEOM_VECTOR &&
theLine2->GetType() == GEOM_VECTOR)
return GetAngleBtwVectors(theLine1, theLine2);
SetErrorCode(KO);
Standard_Real anAngle = -1.0;
if (theLine1.IsNull() || theLine2.IsNull())
return anAngle;
Handle(GEOM_Function) aRefLine1 = theLine1->GetLastFunction();
Handle(GEOM_Function) aRefLine2 = theLine2->GetLastFunction();
if (aRefLine1.IsNull() || aRefLine2.IsNull())
return anAngle;
TopoDS_Shape aLine1 = aRefLine1->GetValue();
TopoDS_Shape aLine2 = aRefLine2->GetValue();
if (aLine1.IsNull() || aLine2.IsNull() ||
aLine1.ShapeType() != TopAbs_EDGE ||
aLine2.ShapeType() != TopAbs_EDGE)
{
SetErrorCode("Two edges must be given");
return anAngle;
}
try {
2012-08-09 13:58:02 +06:00
#if OCC_VERSION_LARGE > 0x06010000
OCC_CATCH_SIGNALS;
#endif
TopoDS_Edge E1 = TopoDS::Edge(aLine1);
TopoDS_Edge E2 = TopoDS::Edge(aLine2);
double fp,lp;
Handle(Geom_Curve) C1 = BRep_Tool::Curve(E1,fp,lp);
Handle(Geom_Curve) C2 = BRep_Tool::Curve(E2,fp,lp);
2009-02-13 17:16:39 +05:00
if ( C1.IsNull() || C2.IsNull() ||
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!C1->IsKind(STANDARD_TYPE(Geom_Line)) ||
!C2->IsKind(STANDARD_TYPE(Geom_Line)))
{
SetErrorCode("The edges must be linear");
return anAngle;
}
Handle(Geom_Line) L1 = Handle(Geom_Line)::DownCast(C1);
Handle(Geom_Line) L2 = Handle(Geom_Line)::DownCast(C2);
gp_Lin aLin1 = L1->Lin();
gp_Lin aLin2 = L2->Lin();
anAngle = aLin1.Angle(aLin2);
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anAngle *= 180. / M_PI; // convert radians into degrees
if (anAngle > 90.0) {
anAngle = 180.0 - anAngle;
}
SetErrorCode(OK);
}
catch (Standard_Failure)
{
Handle(Standard_Failure) aFail = Standard_Failure::Caught();
SetErrorCode(aFail->GetMessageString());
}
return anAngle;
}
//=======================================================================
/*!
* Compute angle (in degrees) between two vectors
*/
//=======================================================================
Standard_Real GEOMImpl_IMeasureOperations::GetAngleBtwVectors (Handle(GEOM_Object) theVec1,
Handle(GEOM_Object) theVec2)
{
SetErrorCode(KO);
Standard_Real anAngle = -1.0;
if (theVec1.IsNull() || theVec2.IsNull())
return anAngle;
if (theVec1->GetType() != GEOM_VECTOR || theVec2->GetType() != GEOM_VECTOR) {
SetErrorCode("Two vectors must be given");
return anAngle;
}
Handle(GEOM_Function) aRefVec1 = theVec1->GetLastFunction();
Handle(GEOM_Function) aRefVec2 = theVec2->GetLastFunction();
if (aRefVec1.IsNull() || aRefVec2.IsNull())
return anAngle;
TopoDS_Shape aVec1 = aRefVec1->GetValue();
TopoDS_Shape aVec2 = aRefVec2->GetValue();
if (aVec1.IsNull() || aVec2.IsNull() ||
aVec1.ShapeType() != TopAbs_EDGE ||
aVec2.ShapeType() != TopAbs_EDGE)
{
SetErrorCode("Two edges must be given");
return anAngle;
}
try {
#if OCC_VERSION_LARGE > 0x06010000
OCC_CATCH_SIGNALS;
#endif
TopoDS_Edge aE1 = TopoDS::Edge(aVec1);
TopoDS_Edge aE2 = TopoDS::Edge(aVec2);
TopoDS_Vertex aP11, aP12, aP21, aP22;
TopExp::Vertices(aE1, aP11, aP12, Standard_True);
TopExp::Vertices(aE2, aP21, aP22, Standard_True);
if (aP11.IsNull() || aP12.IsNull() || aP21.IsNull() || aP22.IsNull()) {
SetErrorCode("Bad edge given");
return anAngle;
}
gp_Vec aV1 (BRep_Tool::Pnt(aP11), BRep_Tool::Pnt(aP12));
gp_Vec aV2 (BRep_Tool::Pnt(aP21), BRep_Tool::Pnt(aP22)) ;
anAngle = aV1.Angle(aV2);
anAngle *= 180. / M_PI; // convert radians into degrees
SetErrorCode(OK);
}
catch (Standard_Failure)
{
Handle(Standard_Failure) aFail = Standard_Failure::Caught();
SetErrorCode(aFail->GetMessageString());
}
return anAngle;
}
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//=============================================================================
/*!
* CurveCurvatureByParam
*/
//=============================================================================
Standard_Real GEOMImpl_IMeasureOperations::CurveCurvatureByParam
(Handle(GEOM_Object) theCurve, Standard_Real& theParam)
{
SetErrorCode(KO);
Standard_Real aRes = -1.0;
if(theCurve.IsNull()) return aRes;
Handle(GEOM_Function) aRefShape = theCurve->GetLastFunction();
if(aRefShape.IsNull()) return aRes;
TopoDS_Shape aShape = aRefShape->GetValue();
if(aShape.IsNull()) {
SetErrorCode("One of Objects has NULL Shape");
return aRes;
}
Standard_Real aFP, aLP, aP;
Handle(Geom_Curve) aCurve = BRep_Tool::Curve(TopoDS::Edge(aShape), aFP, aLP);
aP = aFP + (aLP - aFP) * theParam;
if(aCurve.IsNull()) return aRes;
//Compute curvature
try {
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#if OCC_VERSION_LARGE > 0x06010000
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OCC_CATCH_SIGNALS;
#endif
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GeomLProp_CLProps Prop = GeomLProp_CLProps
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(aCurve, aP, 2, Precision::Confusion());
aRes = fabs(Prop.Curvature());
SetErrorCode(OK);
}
catch (Standard_Failure) {
Handle(Standard_Failure) aFail = Standard_Failure::Caught();
SetErrorCode(aFail->GetMessageString());
return aRes;
}
if( aRes > Precision::Confusion() )
aRes = 1/aRes;
else
aRes = RealLast();
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return aRes;
}
//=============================================================================
/*!
* CurveCurvatureByPoint
*/
//=============================================================================
Standard_Real GEOMImpl_IMeasureOperations::CurveCurvatureByPoint
(Handle(GEOM_Object) theCurve, Handle(GEOM_Object) thePoint)
{
SetErrorCode(KO);
Standard_Real aRes = -1.0;
if( theCurve.IsNull() || thePoint.IsNull() ) return aRes;
Handle(GEOM_Function) aRefCurve = theCurve->GetLastFunction();
Handle(GEOM_Function) aRefPoint = thePoint->GetLastFunction();
if( aRefCurve.IsNull() || aRefPoint.IsNull() ) return aRes;
TopoDS_Edge anEdge = TopoDS::Edge(aRefCurve->GetValue());
TopoDS_Vertex aPnt = TopoDS::Vertex(aRefPoint->GetValue());
if( anEdge.IsNull() || aPnt.IsNull() ) {
SetErrorCode("One of Objects has NULL Shape");
return aRes;
}
Standard_Real aFP, aLP;
Handle(Geom_Curve) aCurve = BRep_Tool::Curve(anEdge, aFP, aLP);
if(aCurve.IsNull()) return aRes;
gp_Pnt aPoint = BRep_Tool::Pnt(aPnt);
//Compute curvature
try {
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#if OCC_VERSION_LARGE > 0x06010000
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OCC_CATCH_SIGNALS;
#endif
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GeomAPI_ProjectPointOnCurve PPCurve(aPoint, aCurve, aFP, aLP);
if(PPCurve.NbPoints()>0) {
GeomLProp_CLProps Prop = GeomLProp_CLProps
(aCurve, PPCurve.LowerDistanceParameter(), 2, Precision::Confusion());
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aRes = fabs(Prop.Curvature());
SetErrorCode(OK);
}
}
catch (Standard_Failure) {
Handle(Standard_Failure) aFail = Standard_Failure::Caught();
SetErrorCode(aFail->GetMessageString());
return aRes;
}
if( aRes > Precision::Confusion() )
aRes = 1/aRes;
else
aRes = RealLast();
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return aRes;
}
//=============================================================================
/*!
* getSurfaceCurvatures
*/
//=============================================================================
Standard_Real GEOMImpl_IMeasureOperations::getSurfaceCurvatures
(const Handle(Geom_Surface)& aSurf,
Standard_Real theUParam,
Standard_Real theVParam,
Standard_Boolean theNeedMaxCurv)
{
SetErrorCode(KO);
Standard_Real aRes = 1.0;
if (aSurf.IsNull()) return aRes;
try {
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#if OCC_VERSION_LARGE > 0x06010000
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OCC_CATCH_SIGNALS;
#endif
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GeomLProp_SLProps Prop = GeomLProp_SLProps
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(aSurf, theUParam, theVParam, 2, Precision::Confusion());
if(Prop.IsCurvatureDefined()) {
if(Prop.IsUmbilic()) {
//cout<<"is umbilic"<<endl;
aRes = fabs(Prop.MeanCurvature());
}
else {
//cout<<"is not umbilic"<<endl;
double c1 = fabs(Prop.MaxCurvature());
double c2 = fabs(Prop.MinCurvature());
if(theNeedMaxCurv)
aRes = Max(c1,c2);
else
aRes = Min(c1,c2);
}
SetErrorCode(OK);
}
}
catch (Standard_Failure) {
Handle(Standard_Failure) aFail = Standard_Failure::Caught();
SetErrorCode(aFail->GetMessageString());
return aRes;
}
if( fabs(aRes) > Precision::Confusion() )
aRes = 1/aRes;
else
aRes = RealLast();
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return aRes;
}
//=============================================================================
/*!
* MaxSurfaceCurvatureByParam
*/
//=============================================================================
Standard_Real GEOMImpl_IMeasureOperations::MaxSurfaceCurvatureByParam
(Handle(GEOM_Object) theSurf,
Standard_Real& theUParam,
Standard_Real& theVParam)
{
SetErrorCode(KO);
Standard_Real aRes = -1.0;
if (theSurf.IsNull()) return aRes;
Handle(GEOM_Function) aRefShape = theSurf->GetLastFunction();
if(aRefShape.IsNull()) return aRes;
TopoDS_Shape aShape = aRefShape->GetValue();
if(aShape.IsNull()) {
SetErrorCode("One of Objects has NULL Shape");
return aRes;
}
TopoDS_Face F = TopoDS::Face(aShape);
Handle(Geom_Surface) aSurf = BRep_Tool::Surface(F);
//Compute the parameters
Standard_Real U1,U2,V1,V2;
ShapeAnalysis::GetFaceUVBounds(F,U1,U2,V1,V2);
Standard_Real U = U1 + (U2-U1)*theUParam;
Standard_Real V = V1 + (V2-V1)*theVParam;
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return getSurfaceCurvatures(aSurf, U, V, true);
}
//=============================================================================
/*!
* MaxSurfaceCurvatureByPoint
*/
//=============================================================================
Standard_Real GEOMImpl_IMeasureOperations::MaxSurfaceCurvatureByPoint
(Handle(GEOM_Object) theSurf, Handle(GEOM_Object) thePoint)
{
SetErrorCode(KO);
Standard_Real aRes = -1.0;
if( theSurf.IsNull() || thePoint.IsNull() ) return aRes;
Handle(GEOM_Function) aRefShape = theSurf->GetLastFunction();
Handle(GEOM_Function) aRefPoint = thePoint->GetLastFunction();
if( aRefShape.IsNull() || aRefPoint.IsNull() ) return aRes;
TopoDS_Face aFace = TopoDS::Face(aRefShape->GetValue());
TopoDS_Vertex aPnt = TopoDS::Vertex(aRefPoint->GetValue());
if( aFace.IsNull() || aPnt.IsNull() ) {
SetErrorCode("One of Objects has NULL Shape");
return 0;
}
Handle(Geom_Surface) aSurf = BRep_Tool::Surface(aFace);
if(aSurf.IsNull()) return aRes;
gp_Pnt aPoint = BRep_Tool::Pnt(aPnt);
//Compute the parameters
ShapeAnalysis_Surface sas(aSurf);
gp_Pnt2d UV = sas.ValueOfUV(aPoint,Precision::Confusion());
return getSurfaceCurvatures(aSurf, UV.X(), UV.Y(), true);
}
//=============================================================================
/*!
* MinSurfaceCurvatureByParam
*/
//=============================================================================
Standard_Real GEOMImpl_IMeasureOperations::MinSurfaceCurvatureByParam
(Handle(GEOM_Object) theSurf,
Standard_Real& theUParam,
Standard_Real& theVParam)
{
SetErrorCode(KO);
Standard_Real aRes = -1.0;
if (theSurf.IsNull()) return aRes;
Handle(GEOM_Function) aRefShape = theSurf->GetLastFunction();
if(aRefShape.IsNull()) return aRes;
TopoDS_Shape aShape = aRefShape->GetValue();
if(aShape.IsNull()) {
SetErrorCode("One of Objects has NULL Shape");
return aRes;
}
TopoDS_Face F = TopoDS::Face(aShape);
Handle(Geom_Surface) aSurf = BRep_Tool::Surface(F);
//Compute the parameters
Standard_Real U1,U2,V1,V2;
ShapeAnalysis::GetFaceUVBounds(F,U1,U2,V1,V2);
Standard_Real U = U1 + (U2-U1)*theUParam;
Standard_Real V = V1 + (V2-V1)*theVParam;
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return getSurfaceCurvatures(aSurf, U, V, false);
}
//=============================================================================
/*!
* MinSurfaceCurvatureByPoint
*/
//=============================================================================
Standard_Real GEOMImpl_IMeasureOperations::MinSurfaceCurvatureByPoint
(Handle(GEOM_Object) theSurf, Handle(GEOM_Object) thePoint)
{
SetErrorCode(KO);
Standard_Real aRes = -1.0;
if( theSurf.IsNull() || thePoint.IsNull() ) return aRes;
Handle(GEOM_Function) aRefShape = theSurf->GetLastFunction();
Handle(GEOM_Function) aRefPoint = thePoint->GetLastFunction();
if( aRefShape.IsNull() || aRefPoint.IsNull() ) return aRes;
TopoDS_Face aFace = TopoDS::Face(aRefShape->GetValue());
TopoDS_Vertex aPnt = TopoDS::Vertex(aRefPoint->GetValue());
if( aFace.IsNull() || aPnt.IsNull() ) {
SetErrorCode("One of Objects has NULL Shape");
return 0;
}
Handle(Geom_Surface) aSurf = BRep_Tool::Surface(aFace);
if(aSurf.IsNull()) return aRes;
gp_Pnt aPoint = BRep_Tool::Pnt(aPnt);
//Compute the parameters
ShapeAnalysis_Surface sas(aSurf);
gp_Pnt2d UV = sas.ValueOfUV(aPoint,Precision::Confusion());
return getSurfaceCurvatures(aSurf, UV.X(), UV.Y(), false);
}
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//=======================================================================
//function : StructuralDump
//purpose : Structural (data exchange) style of output.
//=======================================================================
void GEOMImpl_IMeasureOperations::StructuralDump (const BRepCheck_Analyzer& theAna,
const TopoDS_Shape& theShape,
TCollection_AsciiString& theDump)
{
Standard_Integer i;
theDump.Clear();
theDump += " -- The Shape has problems :\n";
theDump += " Check Count\n";
theDump += " ------------------------------------------------\n";
Standard_Integer last_stat = (Standard_Integer)BRepCheck_CheckFail;
Handle(TColStd_HArray1OfInteger) NbProblems =
new TColStd_HArray1OfInteger(1, last_stat);
for (i = 1; i <= last_stat; i++)
NbProblems->SetValue(i,0);
Handle(TopTools_HSequenceOfShape) sl;
sl = new TopTools_HSequenceOfShape();
TopTools_DataMapOfShapeListOfShape theMap;
theMap.Clear();
GetProblemShapes(theAna, theShape, sl, NbProblems, theMap);
theMap.Clear();
Standard_Integer count = 0;
count = NbProblems->Value((Standard_Integer)BRepCheck_InvalidPointOnCurve);
if (count > 0) {
theDump += " Invalid Point on Curve ................... ";
theDump += TCollection_AsciiString(count) + "\n";
}
count = NbProblems->Value((Standard_Integer)BRepCheck_InvalidPointOnCurveOnSurface);
if (count > 0) {
theDump += " Invalid Point on CurveOnSurface .......... ";
theDump += TCollection_AsciiString(count) + "\n";
}
count = NbProblems->Value((Standard_Integer)BRepCheck_InvalidPointOnSurface);
if (count > 0) {
theDump += " Invalid Point on Surface ................. ";
theDump += TCollection_AsciiString(count) + "\n";
}
count = NbProblems->Value((Standard_Integer)BRepCheck_No3DCurve);
if (count > 0) {
theDump += " No 3D Curve .............................. ";
theDump += TCollection_AsciiString(count) + "\n";
}
count = NbProblems->Value((Standard_Integer)BRepCheck_Multiple3DCurve);
if (count > 0) {
theDump += " Multiple 3D Curve ........................ ";
theDump += TCollection_AsciiString(count) + "\n";
}
count = NbProblems->Value((Standard_Integer)BRepCheck_Invalid3DCurve);
if (count > 0) {
theDump += " Invalid 3D Curve ......................... ";
theDump += TCollection_AsciiString(count) + "\n";
}
count = NbProblems->Value((Standard_Integer)BRepCheck_NoCurveOnSurface);
if (count > 0) {
theDump += " No Curve on Surface ...................... ";
theDump += TCollection_AsciiString(count) + "\n";
}
count = NbProblems->Value((Standard_Integer)BRepCheck_InvalidCurveOnSurface);
if (count > 0) {
theDump += " Invalid Curve on Surface ................. ";
theDump += TCollection_AsciiString(count) + "\n";
}
count = NbProblems->Value((Standard_Integer)BRepCheck_InvalidCurveOnClosedSurface);
if (count > 0) {
theDump += " Invalid Curve on closed Surface .......... ";
theDump += TCollection_AsciiString(count) + "\n";
}
count = NbProblems->Value((Standard_Integer)BRepCheck_InvalidSameRangeFlag);
if (count > 0) {
theDump += " Invalid SameRange Flag ................... ";
theDump += TCollection_AsciiString(count) + "\n";
}
count = NbProblems->Value((Standard_Integer)BRepCheck_InvalidSameParameterFlag);
if (count > 0) {
theDump += " Invalid SameParameter Flag ............... ";
theDump += TCollection_AsciiString(count) + "\n";
}
count = NbProblems->Value((Standard_Integer)BRepCheck_InvalidDegeneratedFlag);
if (count > 0) {
theDump += " Invalid Degenerated Flag ................. ";
theDump += TCollection_AsciiString(count) + "\n";
}
count = NbProblems->Value((Standard_Integer)BRepCheck_FreeEdge);
if (count > 0) {
theDump += " Free Edge ................................ ";
theDump += TCollection_AsciiString(count) + "\n";
}
count = NbProblems->Value((Standard_Integer)BRepCheck_InvalidMultiConnexity);
if (count > 0) {
theDump += " Invalid MultiConnexity ................... ";
theDump += TCollection_AsciiString(count) + "\n";
}
count = NbProblems->Value((Standard_Integer)BRepCheck_InvalidRange);
if (count > 0) {
theDump += " Invalid Range ............................ ";
theDump += TCollection_AsciiString(count) + "\n";
}
count = NbProblems->Value((Standard_Integer)BRepCheck_EmptyWire);
if (count > 0) {
theDump += " Empty Wire ............................... ";
theDump += TCollection_AsciiString(count) + "\n";
}
count = NbProblems->Value((Standard_Integer)BRepCheck_RedundantEdge);
if (count > 0) {
theDump += " Redundant Edge ........................... ";
theDump += TCollection_AsciiString(count) + "\n";
}
count = NbProblems->Value((Standard_Integer)BRepCheck_SelfIntersectingWire);
if (count > 0) {
theDump += " Self Intersecting Wire ................... ";
theDump += TCollection_AsciiString(count) + "\n";
}
count = NbProblems->Value((Standard_Integer)BRepCheck_NoSurface);
if (count > 0) {
theDump += " No Surface ............................... ";
theDump += TCollection_AsciiString(count) + "\n";
}
count = NbProblems->Value((Standard_Integer)BRepCheck_InvalidWire);
if (count > 0) {
theDump += " Invalid Wire ............................. ";
theDump += TCollection_AsciiString(count) + "\n";
}
count = NbProblems->Value((Standard_Integer)BRepCheck_RedundantWire);
if (count > 0) {
theDump += " Redundant Wire ........................... ";
theDump += TCollection_AsciiString(count) + "\n";
}
count = NbProblems->Value((Standard_Integer)BRepCheck_IntersectingWires);
if (count > 0) {
theDump += " Intersecting Wires ....................... ";
theDump += TCollection_AsciiString(count) + "\n";
}
count = NbProblems->Value((Standard_Integer)BRepCheck_InvalidImbricationOfWires);
if (count > 0) {
theDump += " Invalid Imbrication of Wires ............. ";
theDump += TCollection_AsciiString(count) + "\n";
}
count = NbProblems->Value((Standard_Integer)BRepCheck_EmptyShell);
if (count > 0) {
theDump += " Empty Shell .............................. ";
theDump += TCollection_AsciiString(count) + "\n";
}
count = NbProblems->Value((Standard_Integer)BRepCheck_RedundantFace);
if (count > 0) {
theDump += " Redundant Face ........................... ";
theDump += TCollection_AsciiString(count) + "\n";
}
count = NbProblems->Value((Standard_Integer)BRepCheck_UnorientableShape);
if (count > 0) {
theDump += " Unorientable Shape ....................... ";
theDump += TCollection_AsciiString(count) + "\n";
}
count = NbProblems->Value((Standard_Integer)BRepCheck_NotClosed);
if (count > 0) {
theDump += " Not Closed ............................... ";
theDump += TCollection_AsciiString(count) + "\n";
}
count = NbProblems->Value((Standard_Integer)BRepCheck_NotConnected);
if (count > 0) {
theDump += " Not Connected ............................ ";
theDump += TCollection_AsciiString(count) + "\n";
}
count = NbProblems->Value((Standard_Integer)BRepCheck_SubshapeNotInShape);
if (count > 0) {
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theDump += " Sub-shape not in Shape .................... ";
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theDump += TCollection_AsciiString(count) + "\n";
}
count = NbProblems->Value((Standard_Integer)BRepCheck_BadOrientation);
if (count > 0) {
theDump += " Bad Orientation .......................... ";
theDump += TCollection_AsciiString(count) + "\n";
}
count = NbProblems->Value((Standard_Integer)BRepCheck_BadOrientationOfSubshape);
if (count > 0) {
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theDump += " Bad Orientation of Sub-shape .............. ";
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theDump += TCollection_AsciiString(count) + "\n";
}
count = NbProblems->Value((Standard_Integer)BRepCheck_CheckFail);
if (count > 0) {
theDump += " checkshape failure ....................... ";
theDump += TCollection_AsciiString(count) + "\n";
}
theDump += " ------------------------------------------------\n";
theDump += "*** Shapes with problems : ";
theDump += TCollection_AsciiString(sl->Length()) + "\n";
Standard_Integer nbv, nbe, nbw, nbf, nbs, nbo;
nbv = nbe = nbw = nbf = nbs = nbo = 0;
for (i = 1; i <= sl->Length(); i++) {
TopoDS_Shape shi = sl->Value(i);
TopAbs_ShapeEnum sti = shi.ShapeType();
switch (sti) {
case TopAbs_VERTEX : nbv++; break;
case TopAbs_EDGE : nbe++; break;
case TopAbs_WIRE : nbw++; break;
case TopAbs_FACE : nbf++; break;
case TopAbs_SHELL : nbs++; break;
case TopAbs_SOLID : nbo++; break;
default : break;
}
}
if (nbv > 0) {
theDump += "VERTEX : ";
if (nbv < 10) theDump += " ";
theDump += TCollection_AsciiString(nbv) + "\n";
}
if (nbe > 0) {
theDump += "EDGE : ";
if (nbe < 10) theDump += " ";
theDump += TCollection_AsciiString(nbe) + "\n";
}
if (nbw > 0) {
theDump += "WIRE : ";
if (nbw < 10) theDump += " ";
theDump += TCollection_AsciiString(nbw) + "\n";
}
if (nbf > 0) {
theDump += "FACE : ";
if (nbf < 10) theDump += " ";
theDump += TCollection_AsciiString(nbf) + "\n";
}
if (nbs > 0) {
theDump += "SHELL : ";
if (nbs < 10) theDump += " ";
theDump += TCollection_AsciiString(nbs) + "\n";
}
if (nbo > 0) {
theDump += "SOLID : ";
if (nbo < 10) theDump += " ";
theDump += TCollection_AsciiString(nbo) + "\n";
}
}
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2004-12-01 15:39:14 +05:00
//=======================================================================
//function : GetProblemShapes
// purpose : for StructuralDump
//=======================================================================
void GEOMImpl_IMeasureOperations::GetProblemShapes (const BRepCheck_Analyzer& theAna,
const TopoDS_Shape& theShape,
Handle(TopTools_HSequenceOfShape)& sl,
Handle(TColStd_HArray1OfInteger)& NbProblems,
TopTools_DataMapOfShapeListOfShape& theMap)
{
for (TopoDS_Iterator iter(theShape); iter.More(); iter.Next()) {
GetProblemShapes(theAna, iter.Value(), sl, NbProblems, theMap);
}
TopAbs_ShapeEnum styp = theShape.ShapeType();
BRepCheck_ListIteratorOfListOfStatus itl;
TopTools_ListOfShape empty;
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if (!theMap.IsBound(theShape)) {
theMap.Bind(theShape,empty);
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if (!theAna.Result(theShape).IsNull()) {
itl.Initialize(theAna.Result(theShape)->Status());
// !!! May be, we have to print all the problems, not only the first one ?
if (itl.Value() != BRepCheck_NoError) {
sl->Append(theShape);
BRepCheck_Status stat = itl.Value();
NbProblems->SetValue((Standard_Integer)stat,
NbProblems->Value((Standard_Integer)stat) + 1);
}
}
}
switch (styp) {
case TopAbs_EDGE:
GetProblemSub(theAna, theShape, sl, NbProblems, TopAbs_VERTEX, theMap);
break;
case TopAbs_FACE:
GetProblemSub(theAna, theShape, sl, NbProblems, TopAbs_WIRE, theMap);
GetProblemSub(theAna, theShape, sl, NbProblems, TopAbs_EDGE, theMap);
GetProblemSub(theAna, theShape, sl, NbProblems, TopAbs_VERTEX, theMap);
break;
case TopAbs_SHELL:
break;
case TopAbs_SOLID:
GetProblemSub(theAna, theShape, sl, NbProblems, TopAbs_SHELL, theMap);
break;
default:
break;
}
}
//=======================================================================
//function : Contains
//=======================================================================
static Standard_Boolean Contains (const TopTools_ListOfShape& L,
const TopoDS_Shape& S)
{
TopTools_ListIteratorOfListOfShape it;
for (it.Initialize(L); it.More(); it.Next()) {
if (it.Value().IsSame(S)) {
return Standard_True;
}
}
return Standard_False;
}
//=======================================================================
//function : GetProblemSub
// purpose : for StructuralDump
//=======================================================================
void GEOMImpl_IMeasureOperations::GetProblemSub (const BRepCheck_Analyzer& theAna,
const TopoDS_Shape& theShape,
Handle(TopTools_HSequenceOfShape)& sl,
Handle(TColStd_HArray1OfInteger)& NbProblems,
const TopAbs_ShapeEnum Subtype,
TopTools_DataMapOfShapeListOfShape& theMap)
{
BRepCheck_ListIteratorOfListOfStatus itl;
TopExp_Explorer exp;
for (exp.Init(theShape, Subtype); exp.More(); exp.Next()) {
const TopoDS_Shape& sub = exp.Current();
const Handle(BRepCheck_Result)& res = theAna.Result(sub);
for (res->InitContextIterator();
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res->MoreShapeInContext();
res->NextShapeInContext()) {
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if (res->ContextualShape().IsSame(theShape) && !Contains(theMap(sub), theShape)) {
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theMap(sub).Append(theShape);
itl.Initialize(res->StatusOnShape());
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if (itl.Value() != BRepCheck_NoError) {
Standard_Integer ii = 0;
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for (ii = 1; ii <= sl->Length(); ii++)
if (sl->Value(ii).IsSame(sub)) break;
if (ii > sl->Length()) {
sl->Append(sub);
BRepCheck_Status stat = itl.Value();
NbProblems->SetValue((Standard_Integer)stat,
NbProblems->Value((Standard_Integer)stat) + 1);
}
for (ii = 1; ii <= sl->Length(); ii++)
if (sl->Value(ii).IsSame(theShape)) break;
if (ii > sl->Length()) {
sl->Append(theShape);
BRepCheck_Status stat = itl.Value();
NbProblems->SetValue((Standard_Integer)stat,
NbProblems->Value((Standard_Integer)stat) + 1);
}
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}
break;
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}
}
}
}