// Copyright (C) 2007-2023 CEA/DEN, EDF R&D, OPEN CASCADE
//
// Copyright (C) 2003-2007 OPEN CASCADE, EADS/CCR, LIP6, CEA/DEN,
// CEDRAT, EDF R&D, LEG, PRINCIPIA R&D, BUREAU VERITAS
//
// 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, or (at your option) any later version.
//
// 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.
//
// 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
//
// See http://www.salome-platform.org/ or email : webmaster.salome@opencascade.com
//
#include <GEOMImpl_ShapeDriver.hxx>
#include <GEOMImpl_IExtract.hxx>
#include <GEOMImpl_IIsoline.hxx>
#include <GEOMImpl_IShapes.hxx>
#include <GEOMImpl_IShapeExtend.hxx>
#include <GEOMImpl_IVector.hxx>
#include <GEOMImpl_Types.hxx>
#include <GEOMImpl_Block6Explorer.hxx>
#include <GEOM_Function.hxx>
#include <GEOMUtils_Hatcher.hxx>
#include <GEOMAlgo_State.hxx>
#include <GEOMAlgo_Extractor.hxx>
// OCCT Includes
#include <ShapeFix_Wire.hxx>
#include <ShapeFix_Edge.hxx>
#include <ShapeFix_Shape.hxx>
#include <BRep_Builder.hxx>
#include <BRep_Tool.hxx>
#include <BRepAdaptor_Curve.hxx>
#include <BRepAlgo_FaceRestrictor.hxx>
#include <BRepBuilderAPI_Copy.hxx>
#include <BRepBuilderAPI_Sewing.hxx>
#include <BRepBuilderAPI_MakeFace.hxx>
#include <BRepBuilderAPI_MakeWire.hxx>
#include <BRepBuilderAPI_MakeEdge.hxx>
#include <BRepBuilderAPI_MakeSolid.hxx>
#include <BRepCheck.hxx>
#include <BRepCheck_Analyzer.hxx>
#include <BRepCheck_Shell.hxx>
#include <BRepClass3d_SolidClassifier.hxx>
#include <BRepLib.hxx>
#include <BRepLib_MakeEdge.hxx>
#include <BRepTools_WireExplorer.hxx>
#include <ShapeAnalysis.hxx>
#include <ShapeAnalysis_FreeBounds.hxx>
#include <TNaming_CopyShape.hxx>
#include <TopAbs.hxx>
#include <TopExp.hxx>
#include <TopExp_Explorer.hxx>
#include <TopoDS.hxx>
#include <TopoDS_Shape.hxx>
#include <TopoDS_Edge.hxx>
#include <TopoDS_Wire.hxx>
#include <TopoDS_Shell.hxx>
#include <TopoDS_Solid.hxx>
#include <TopoDS_Compound.hxx>
#include <TopoDS_Iterator.hxx>
#include <TopTools_ListIteratorOfListOfShape.hxx>
#include <TopTools_ListOfShape.hxx>
#include <TopTools_MapOfShape.hxx>
#include <TopTools_HSequenceOfShape.hxx>
#include <ElCLib.hxx>
#include <GCPnts_AbscissaPoint.hxx>
#include <Geom_TrimmedCurve.hxx>
#include <Geom_RectangularTrimmedSurface.hxx>
#include <Geom_Surface.hxx>
#include <GeomAbs_CurveType.hxx>
#include <GeomConvert_CompCurveToBSplineCurve.hxx>
#include <GeomConvert.hxx>
#include <GeomLProp.hxx>
#include <TColStd_IndexedDataMapOfTransientTransient.hxx>
#include <TColStd_SequenceOfReal.hxx>
#include <TColStd_HSequenceOfTransient.hxx>
#include <TColStd_Array1OfReal.hxx>
#include <TColGeom_SequenceOfCurve.hxx>
#include <TColGeom_Array1OfBSplineCurve.hxx>
#include <TColGeom_HArray1OfBSplineCurve.hxx>
#include <Precision.hxx>
#include <Standard_NullObject.hxx>
#include <Standard_TypeMismatch.hxx>
#include <Standard_ConstructionError.hxx>
#include <BOPAlgo_PaveFiller.hxx>
#include <BOPAlgo_MakerVolume.hxx>
#include <list>
/**
* \brief This static function converts the list of shapes into an array
* of their IDs. If the input list is empty, null handle will be returned.
* this method doesn't check if a shape presents in theIndices map.
*
* \param theListOfShapes the list of shapes.
* \param theIndices the indexed map of shapes.
* \return the array of shape IDs.
*/
static Handle(TColStd_HArray1OfInteger) GetShapeIDs
(const TopTools_ListOfShape &theListOfShapes,
const TopTools_IndexedMapOfShape &theIndices)
{
Handle(TColStd_HArray1OfInteger) aResult;
if (!theListOfShapes.IsEmpty()) {
const Standard_Integer aNbShapes = theListOfShapes.Extent();
TopTools_ListIteratorOfListOfShape anIter(theListOfShapes);
Standard_Integer i;
aResult = new TColStd_HArray1OfInteger(1, aNbShapes);
for (i = 1; anIter.More(); anIter.Next(), ++i) {
const TopoDS_Shape &aShape = anIter.Value();
const Standard_Integer anIndex = theIndices.FindIndex(aShape);
aResult->SetValue(i, anIndex);
}
}
return aResult;
}
namespace
{
// check that compound includes only shapes of expected type
bool checkCompound( TopoDS_Shape& c, TopAbs_ShapeEnum t )
{
TopoDS_Iterator it( c, Standard_True, Standard_True );
// empty compound is OK only if we explicitly create a compound of shapes
bool result = true;
// => if expected type is TopAbs_SHAPE, we allow compound consisting of any shapes, this above check is enough
// => otherwise we have to check compound's content
// => compound sometimes can contain enclosed compound(s), we process them recursively and rebuild initial compound
if ( t != TopAbs_SHAPE ) {
result = it.More();
std::list<TopoDS_Shape> compounds, shapes;
compounds.push_back( c );
while ( !compounds.empty() && result ) {
// check that compound contains only shapes of expected type
TopoDS_Shape cc = compounds.front();
compounds.pop_front();
it.Initialize( cc, Standard_True, Standard_True );
for ( ; it.More() && result; it.Next() ) {
TopAbs_ShapeEnum tt = it.Value().ShapeType();
if ( tt == TopAbs_COMPOUND || tt == TopAbs_COMPSOLID ) {
compounds.push_back( it.Value() );
continue;
}
shapes.push_back( it.Value() );
result = tt == t;
}
}
if ( result ) {
if ( shapes.empty() ) {
result = false;
}
else if ( shapes.size() == 1 ) {
c = shapes.front();
}
else {
BRep_Builder b;
TopoDS_Compound newc;
b.MakeCompound( newc );
std::list<TopoDS_Shape> ::const_iterator sit;
for ( sit = shapes.begin(); sit != shapes.end(); ++sit )
b.Add( newc, *sit );
c = newc;
}
}
}
return result;
}
/**
* This function adds faces from the input shape into the list of faces. If
* the input shape is a face, it is added itself. If it is a shell, its
* sub-shapes (faces) are added. If it is a compound, its sub-shapes
* (faces or shells) are added in the list. For null shapes and for other
* types of shapes an exception is thrown.
*
* @param theShape the shape to be added. Either face or shell or a compound
* of faces and/or shells.
* @param theListFaces the list of faces that is modified on output.
* @param theMapFence the map that protects from adding the same faces in
* the list.
*/
void addFaces(const TopoDS_Shape &theShape,
TopTools_ListOfShape &theListFaces,
TopTools_MapOfShape &theMapFence)
{
if (theShape.IsNull()) {
Standard_NullObject::Raise("Face for shell construction is null");
}
// Append the shape is the mapFence
if (theMapFence.Add(theShape)) {
// Shape type
const TopAbs_ShapeEnum aType = theShape.ShapeType();
if (aType == TopAbs_FACE) {
theListFaces.Append(theShape);
} else if (aType == TopAbs_SHELL || aType == TopAbs_COMPOUND) {
TopoDS_Iterator anIter(theShape);
for (; anIter.More(); anIter.Next()) {
// Add sub-shapes: faces for shell or faces/shells for compound.
const TopoDS_Shape &aSubShape = anIter.Value();
addFaces(aSubShape, theListFaces, theMapFence);
}
} else {
Standard_TypeMismatch::Raise
("Shape for shell construction is neither a shell nor a face");
}
}
}
/**
* This function constructs a shell or a compound of shells
* from a set of faces and/or shells.
*
* @param theShapes is a set of faces, shells and/or
* compounds of faces/shells.
* @return a shell or a compound of shells.
*/
TopoDS_Shape makeShellFromFaces
(const Handle(TColStd_HSequenceOfTransient) &theShapes)
{
const Standard_Integer aNbShapes = theShapes->Length();
Standard_Integer i;
TopTools_ListOfShape aListFaces;
TopTools_MapOfShape aMapFence;
BRep_Builder aBuilder;
// Fill the list of unique faces
for (i = 1; i <= aNbShapes; ++i) {
// Function
const Handle(GEOM_Function) aRefShape =
Handle(GEOM_Function)::DownCast(theShapes->Value(i));
if (aRefShape.IsNull()) {
Standard_NullObject::Raise("Face for shell construction is null");
}
// Shape
const TopoDS_Shape aShape = aRefShape->GetValue();
addFaces(aShape, aListFaces, aMapFence);
}
// Perform computation of shells.
TopTools_ListOfShape aListShells;
TopTools_ListIteratorOfListOfShape anIter;
while (!aListFaces.IsEmpty()) {
// Perform sewing
BRepBuilderAPI_Sewing aSewing(Precision::Confusion()*10.0);
for (anIter.Initialize(aListFaces); anIter.More(); anIter.Next()) {
aSewing.Add(anIter.Value());
}
aSewing.Perform();
// Fill list of shells.
const TopoDS_Shape &aSewed = aSewing.SewedShape();
TopExp_Explorer anExp(aSewed, TopAbs_SHELL);
Standard_Boolean isNewShells = Standard_False;
// Append shells
for (; anExp.More(); anExp.Next()) {
aListShells.Append(anExp.Current());
isNewShells = Standard_True;
}
// Append single faces.
anExp.Init(aSewed, TopAbs_FACE, TopAbs_SHELL);
for (; anExp.More(); anExp.Next()) {
TopoDS_Shell aShell;
aBuilder.MakeShell(aShell);
aBuilder.Add(aShell, anExp.Current());
aListShells.Append(aShell);
isNewShells = Standard_True;
}
if (!isNewShells) {
// There are no more shell can be obtained. Break the loop.
break;
}
// Remove faces that are in the result from the list.
TopTools_IndexedMapOfShape aMapFaces;
TopExp::MapShapes(aSewed, TopAbs_FACE, aMapFaces);
// Add deleted faces to the map
const Standard_Integer aNbDelFaces = aSewing.NbDeletedFaces();
for (i = 1; i <= aNbDelFaces; ++i) {
aMapFaces.Add(aSewing.DeletedFace(i));
}
for (anIter.Initialize(aListFaces); anIter.More();) {
const TopoDS_Shape &aFace = anIter.Value();
//Standard_Boolean isFaceUsed = Standard_False;
if (aMapFaces.Contains(aFace) || aSewing.IsModified(aFace)) {
// Remove face from the list.
aListFaces.Remove(anIter);
} else {
// Go to the next face.
anIter.Next();
}
}
}
// If there are faces not used in shells create a shell for each face.
for (anIter.Initialize(aListFaces); anIter.More(); anIter.Next()) {
TopoDS_Shell aShell;
aBuilder.MakeShell(aShell);
aBuilder.Add(aShell, anIter.Value());
aListShells.Append(aShell);
}
// Construct the result that can be either a shell or a compound of shells
TopoDS_Shape aResult;
if (!aListShells.IsEmpty()) {
if (aListShells.Extent() == 1) {
aResult = aListShells.First();
} else {
// There are more then one shell.
TopoDS_Compound aCompound;
aBuilder.MakeCompound(aCompound);
for (anIter.Initialize(aListShells); anIter.More(); anIter.Next()) {
aBuilder.Add(aCompound, anIter.Value());
}
aResult = aCompound;
}
}
return aResult;
}
// End of namespace
}
//modified by NIZNHY-PKV Wed Dec 28 13:48:20 2011f
//static
// void KeepEdgesOrder(const Handle(TopTools_HSequenceOfShape)& aEdges,
// const Handle(TopTools_HSequenceOfShape)& aWires);
//modified by NIZNHY-PKV Wed Dec 28 13:48:23 2011t
//=======================================================================
//function : GetID
//purpose :
//=======================================================================
const Standard_GUID& GEOMImpl_ShapeDriver::GetID()
{
static Standard_GUID aShapeDriver("FF1BBB54-5D14-4df2-980B-3A668264EA16");
return aShapeDriver;
}
//=======================================================================
//function : GEOMImpl_ShapeDriver
//purpose :
//=======================================================================
GEOMImpl_ShapeDriver::GEOMImpl_ShapeDriver()
{
}
//=======================================================================
//function : Execute
//purpose :
//=======================================================================
Standard_Integer GEOMImpl_ShapeDriver::Execute(Handle(TFunction_Logbook)& log) const
{
if (Label().IsNull()) return 0;
Handle(GEOM_Function) aFunction = GEOM_Function::GetFunction(Label());
GEOMImpl_IShapes aCI (aFunction);
Standard_Integer aType = aFunction->GetType();
TopoDS_Shape aShape;
TCollection_AsciiString aWarning;
// this is an exact type of expected shape, or shape in a compound if compound is allowed as a result (see below)
TopAbs_ShapeEnum anExpectedType = TopAbs_SHAPE;
// this should be true if result can be a compound of shapes of strict type (see above)
bool allowCompound = false;
BRep_Builder B;
if (aType == WIRE_EDGES) {
// result may be only a single wire
anExpectedType = TopAbs_WIRE;
Handle(TColStd_HSequenceOfTransient) aShapes = aCI.GetShapes();
Standard_Real aTolerance = aCI.GetTolerance();
if (aTolerance < Precision::Confusion())
aTolerance = Precision::Confusion();
aShape = MakeWireFromEdges(aShapes, aTolerance);
}
else if (aType == FACE_WIRE) {
// result may be a face or a compound of faces
anExpectedType = TopAbs_FACE;
allowCompound = true;
Handle(GEOM_Function) aRefBase = aCI.GetBase();
TopoDS_Shape aShapeBase = aRefBase->GetValue();
if (aShapeBase.IsNull()) Standard_NullObject::Raise("Argument Shape is null");
TopoDS_Wire W;
if (aShapeBase.ShapeType() == TopAbs_WIRE) {
W = TopoDS::Wire(aShapeBase);
// check the wire is closed
TopoDS_Vertex aV1, aV2;
TopExp::Vertices(W, aV1, aV2);
if ( !aV1.IsNull() && !aV2.IsNull() && aV1.IsSame(aV2) )
aShapeBase.Closed(true);
else
Standard_NullObject::Raise
("Shape for face construction is not closed");
}
else if (aShapeBase.ShapeType() == TopAbs_EDGE && BRep_Tool::IsClosed(aShapeBase)) {
BRepBuilderAPI_MakeWire MW;
MW.Add(TopoDS::Edge(aShapeBase));
if (!MW.IsDone()) {
Standard_ConstructionError::Raise("Wire construction failed");
}
W = MW;
}
else {
Standard_NullObject::Raise
("Shape for face construction is neither a wire nor a closed edge");
}
aWarning = GEOMImpl_Block6Explorer::MakeFace(W, aCI.GetIsPlanar(), aShape);
if (aShape.IsNull()) {
Standard_ConstructionError::Raise("Face construction failed");
}
}
else if (aType == FACE_WIRES) {
// result may be a face or a compound of faces
anExpectedType = TopAbs_FACE;
allowCompound = true;
// Try to build a face from a set of wires and edges
int ind;
Handle(TColStd_HSequenceOfTransient) aShapes = aCI.GetShapes();
int nbshapes = aShapes->Length();
if (nbshapes < 1) {
Standard_ConstructionError::Raise("No wires or edges given");
}
// 1. Extract all edges from the given arguments
TopTools_MapOfShape aMapEdges;
Handle(TopTools_HSequenceOfShape) aSeqEdgesIn = new TopTools_HSequenceOfShape;
TColStd_IndexedDataMapOfTransientTransient aMapTShapes;
for (ind = 1; ind <= nbshapes; ind++) {
Handle(GEOM_Function) aRefSh_i = Handle(GEOM_Function)::DownCast(aShapes->Value(ind));
TopoDS_Shape aSh_i = aRefSh_i->GetValue();
TopExp_Explorer anExpE_i (aSh_i, TopAbs_EDGE);
for (; anExpE_i.More(); anExpE_i.Next()) {
if (aMapEdges.Add(anExpE_i.Current())) {
// Copy the original shape.
TopoDS_Shape aShapeCopy;
TNaming_CopyShape::CopyTool
(anExpE_i.Current(), aMapTShapes, aShapeCopy);
aSeqEdgesIn->Append(aShapeCopy);
}
}
}
if (aSeqEdgesIn->IsEmpty()) {
Standard_ConstructionError::Raise("No edges given");
}
// 2. Connect edges to wires of maximum length
Handle(TopTools_HSequenceOfShape) aSeqWiresOut;
ShapeAnalysis_FreeBounds::ConnectEdgesToWires(aSeqEdgesIn, Precision::Confusion(),
/*shared*/Standard_False, aSeqWiresOut);
//modified by NIZNHY-PKV Wed Dec 28 13:46:55 2011f
//KeepEdgesOrder(aSeqEdgesIn, aSeqWiresOut);
//modified by NIZNHY-PKV Wed Dec 28 13:46:59 2011t
// 3. Separate closed wires
Handle(TopTools_HSequenceOfShape) aSeqClosedWires = new TopTools_HSequenceOfShape;
Handle(TopTools_HSequenceOfShape) aSeqOpenWires = new TopTools_HSequenceOfShape;
for (ind = 1; ind <= aSeqWiresOut->Length(); ind++) {
if (aSeqWiresOut->Value(ind).Closed())
aSeqClosedWires->Append(aSeqWiresOut->Value(ind));
else
aSeqOpenWires->Append(aSeqWiresOut->Value(ind));
}
if (aSeqClosedWires->Length() < 1) {
Standard_ConstructionError::Raise
("There is no closed contour can be built from the given arguments");
}
// 4. Build a face / list of faces from all the obtained closed wires
// 4.a. Basic face
TopoDS_Shape aFFace;
TopoDS_Wire aW1 = TopoDS::Wire(aSeqClosedWires->Value(1));
aWarning = GEOMImpl_Block6Explorer::MakeFace(aW1, aCI.GetIsPlanar(), aFFace);
if (aFFace.IsNull()) {
Standard_ConstructionError::Raise("Face construction failed");
}
// 4.b. Add other wires
if (aSeqClosedWires->Length() == 1) {
aShape = aFFace;
}
else {
TopoDS_Compound C;
BRep_Builder aBuilder;
aBuilder.MakeCompound(C);
BRepAlgo_FaceRestrictor FR;
TopAbs_Orientation OriF = aFFace.Orientation();
TopoDS_Shape aLocalS = aFFace.Oriented(TopAbs_FORWARD);
FR.Init(TopoDS::Face(aLocalS), Standard_False, Standard_True);
for (ind = 1; ind <= aSeqClosedWires->Length(); ind++) {
TopoDS_Wire aW = TopoDS::Wire(aSeqClosedWires->Value(ind));
FR.Add(aW);
}
FR.Perform();
if (FR.IsDone()) {
int k = 0;
TopoDS_Shape aFace;
for (; FR.More(); FR.Next()) {
aFace = FR.Current().Oriented(OriF);
aBuilder.Add(C, aFace);
k++;
}
if (k == 1) {
aShape = aFace;
} else {
aShape = C;
}
}
}
// 5. Add all open wires to the result
if (aSeqOpenWires->Length() > 0) {
//Standard_ConstructionError::Raise("There are some open wires");
TopoDS_Compound C;
BRep_Builder aBuilder;
if (aSeqClosedWires->Length() == 1) {
aBuilder.MakeCompound(C);
aBuilder.Add(C, aShape);
}
else {
C = TopoDS::Compound(aShape);
}
for (ind = 1; ind <= aSeqOpenWires->Length(); ind++) {
aBuilder.Add(C, aSeqOpenWires->Value(ind));
}
aShape = C;
}
}
else if (aType == FACE_FROM_SURFACE) {
// result may be only a face
anExpectedType = TopAbs_FACE;
Handle(TColStd_HSequenceOfTransient) aShapes = aCI.GetShapes();
if (aShapes.IsNull() == Standard_False) {
Standard_Integer aNbShapes = aShapes->Length();
if (aNbShapes == 2) {
Handle(GEOM_Function) aRefFace =
Handle(GEOM_Function)::DownCast(aShapes->Value(1));
Handle(GEOM_Function) aRefWire =
Handle(GEOM_Function)::DownCast(aShapes->Value(2));
if (aRefFace.IsNull() == Standard_False &&
aRefWire.IsNull() == Standard_False) {
TopoDS_Shape aShFace = aRefFace->GetValue();
TopoDS_Shape aShWire = aRefWire->GetValue();
if (aShFace.IsNull() == Standard_False &&
aShFace.ShapeType() == TopAbs_FACE &&
aShWire.IsNull() == Standard_False &&
aShWire.ShapeType() == TopAbs_WIRE) {
TopoDS_Face aFace = TopoDS::Face(aShFace);
TopoDS_Wire aWire = TopoDS::Wire(aShWire);
Handle(Geom_Surface) aSurf = BRep_Tool::Surface(aFace);
BRepBuilderAPI_MakeFace aMkFace(aSurf, aWire);
if (aMkFace.IsDone()) {
aShape = aMkFace.Shape();
}
}
}
}
}
}
else if (aType == SHELL_FACES) {
// result may be only a shell or a compound of shells
anExpectedType = TopAbs_SHELL;
allowCompound = true;
Handle(TColStd_HSequenceOfTransient) aShapes = aCI.GetShapes();
if (aShapes.IsNull()) {
Standard_NullObject::Raise("Argument Shapes is null");
}
// Compute a shell or a compound of shells.
aShape = makeShellFromFaces(aShapes);
}
else if (aType == SOLID_SHELLS) {
// result may be only a solid or a compound of solids
anExpectedType = TopAbs_SOLID;
allowCompound = true;
Handle(TColStd_HSequenceOfTransient) aShapes = aCI.GetShapes();
unsigned int ind, nbshapes = aShapes->Length();
Standard_Integer ish = 0;
BRepBuilderAPI_MakeSolid aMkSolid;
// add shapes
for (ind = 1; ind <= nbshapes; ind++) {
Handle(GEOM_Function) aRefShape = Handle(GEOM_Function)::DownCast(aShapes->Value(ind));
TopoDS_Shape aShapeShell = aRefShape->GetValue();
if (aShapeShell.IsNull()) {
Standard_NullObject::Raise("Shell for solid construction is null");
}
if (aShapeShell.ShapeType() == TopAbs_COMPOUND) {
TopoDS_Iterator It (aShapeShell, Standard_True, Standard_True);
for (; It.More(); It.Next()) {
TopoDS_Shape aSubShape = It.Value();
if (aSubShape.ShapeType() == TopAbs_SHELL) {
aMkSolid.Add(TopoDS::Shell(aSubShape));
ish++;
}
else
Standard_TypeMismatch::Raise
("Shape for solid construction is neither a shell nor a compound of shells");
}
}
else if (aShapeShell.ShapeType() == TopAbs_SHELL) {
aMkSolid.Add(TopoDS::Shell(aShapeShell));
ish++;
}
}
if (ish == 0 || !aMkSolid.IsDone()) return 0;
TopoDS_Solid Sol = aMkSolid.Solid();
BRepClass3d_SolidClassifier SC (Sol);
SC.PerformInfinitePoint(Precision::Confusion());
if (SC.State() == TopAbs_IN)
aShape = Sol.Reversed();
else
aShape = Sol;
}
else if (aType == COMPOUND_SHAPES) {
// result may be only a compound of any shapes
allowCompound = true;
Handle(TColStd_HSequenceOfTransient) aShapes = aCI.GetShapes();
unsigned int ind, nbshapes = aShapes->Length();
// add shapes
TopoDS_Compound C;
B.MakeCompound(C);
for (ind = 1; ind <= nbshapes; ind++) {
Handle(GEOM_Function) aRefShape = Handle(GEOM_Function)::DownCast(aShapes->Value(ind));
TopoDS_Shape aShape_i = aRefShape->GetValue();
if (aShape_i.IsNull()) {
Standard_NullObject::Raise("Shape for compound construction is null");
}
B.Add(C, aShape_i);
}
aShape = C;
}
else if (aType == EDGE_WIRE) {
// result may be only an edge
anExpectedType = TopAbs_EDGE;
Handle(GEOM_Function) aRefBase = aCI.GetBase();
TopoDS_Shape aWire = aRefBase->GetValue();
Standard_Real LinTol = aCI.GetTolerance();
Standard_Real AngTol = aCI.GetAngularTolerance();
if (aWire.IsNull()) Standard_NullObject::Raise("Argument Wire is null");
aShape = MakeEdgeFromWire(aWire, LinTol, AngTol);
}
else if (aType == SOLID_FACES) {
// result may be only a solid or a compound of solids
anExpectedType = TopAbs_SOLID;
allowCompound = true;
Handle(TColStd_HSequenceOfTransient) aShapes = aCI.GetShapes();
unsigned int ind, nbshapes = aShapes->Length();
// add faces
TopTools_ListOfShape aLS;
for (ind = 1; ind <= nbshapes; ind++) {
Handle(GEOM_Function) aRefShape = Handle(GEOM_Function)::DownCast(aShapes->Value(ind));
TopoDS_Shape aShape_i = aRefShape->GetValue();
if (aShape_i.IsNull()) {
Standard_NullObject::Raise("Shape for solid construction is null");
}
if (aShape_i.ShapeType() == TopAbs_COMPOUND) {
TopoDS_Iterator It (aShape_i, Standard_True, Standard_True);
for (; It.More(); It.Next()) {
TopoDS_Shape aSubShape = It.Value();
if (aSubShape.ShapeType() == TopAbs_FACE || aSubShape.ShapeType() == TopAbs_SHELL)
aLS.Append(aSubShape);
else
Standard_TypeMismatch::Raise
("Shape for solid construction is neither a list of faces and/or shells "
"nor a compound of faces and/or shells");
}
}
aLS.Append(aShape_i);
}
BOPAlgo_MakerVolume aMV;
aMV.SetArguments(aLS);
aMV.SetIntersect(aCI.GetIsIntersect());
aMV.Perform();
if (aMV.HasErrors()) return 0;
aShape = aMV.Shape();
}
else if (aType == EDGE_CURVE_LENGTH) {
// result may be only an edge
anExpectedType = TopAbs_EDGE;
GEOMImpl_IVector aVI (aFunction);
// RefCurve
Handle(GEOM_Function) aRefCurve = aVI.GetPoint1();
if (aRefCurve.IsNull()) Standard_NullObject::Raise("Argument Curve is null");
TopoDS_Shape aRefShape1 = aRefCurve->GetValue();
if (aRefShape1.ShapeType() != TopAbs_EDGE) {
Standard_TypeMismatch::Raise
("Edge On Curve creation aborted : curve shape is not an edge");
}
TopoDS_Edge aRefEdge = TopoDS::Edge(aRefShape1);
TopoDS_Vertex V1, V2;
TopExp::Vertices(aRefEdge, V1, V2, Standard_True);
// RefPoint
TopoDS_Vertex aRefVertex;
Handle(GEOM_Function) aRefPoint = aVI.GetPoint2();
if (aRefPoint.IsNull()) {
aRefVertex = V1;
}
else {
TopoDS_Shape aRefShape2 = aRefPoint->GetValue();
if (aRefShape2.ShapeType() != TopAbs_VERTEX) {
Standard_TypeMismatch::Raise
("Edge On Curve creation aborted : start point shape is not a vertex");
}
aRefVertex = TopoDS::Vertex(aRefShape2);
}
gp_Pnt aRefPnt = BRep_Tool::Pnt(aRefVertex);
// Length
Standard_Real aLength = aVI.GetParameter();
//Standard_Real aCurveLength = IntTools::Length(aRefEdge);
//if (aLength > aCurveLength) {
// Standard_ConstructionError::Raise
// ("Edge On Curve creation aborted : given length is greater than edges length");
//}
if (fabs(aLength) < Precision::Confusion()) {
Standard_ConstructionError::Raise
("Edge On Curve creation aborted : given length is smaller than Precision::Confusion()");
}
// Check orientation
Standard_Real UFirst, ULast;
Handle(Geom_Curve) EdgeCurve = BRep_Tool::Curve(aRefEdge, UFirst, ULast);
Handle(Geom_Curve) ReOrientedCurve = EdgeCurve;
Standard_Real dU = ULast - UFirst;
Standard_Real par1 = UFirst + 0.1 * dU;
Standard_Real par2 = ULast - 0.1 * dU;
gp_Pnt P1 = EdgeCurve->Value(par1);
gp_Pnt P2 = EdgeCurve->Value(par2);
if (aRefPnt.SquareDistance(P2) < aRefPnt.SquareDistance(P1)) {
ReOrientedCurve = EdgeCurve->Reversed();
UFirst = EdgeCurve->ReversedParameter(ULast);
}
// Get the point by length
GeomAdaptor_Curve AdapCurve = GeomAdaptor_Curve(ReOrientedCurve);
GCPnts_AbscissaPoint anAbsPnt (AdapCurve, aLength, UFirst);
Standard_Real aParam = anAbsPnt.Parameter();
if (AdapCurve.IsClosed() && aLength < 0.0) {
Standard_Real aTmp = aParam;
aParam = UFirst;
UFirst = aTmp;
}
BRepBuilderAPI_MakeEdge aME (ReOrientedCurve, UFirst, aParam);
if (aME.IsDone())
aShape = aME.Shape();
}
else if (aType == SHAPE_ISOLINE) {
// result may be only an edge or compound of edges
anExpectedType = TopAbs_EDGE;
allowCompound = true;
GEOMImpl_IIsoline aII (aFunction);
Handle(GEOM_Function) aRefFace = aII.GetFace();
TopoDS_Shape aShapeFace = aRefFace->GetValue();
if (aShapeFace.ShapeType() == TopAbs_FACE) {
TopoDS_Face aFace = TopoDS::Face(aShapeFace);
bool isUIso = aII.GetIsUIso();
Standard_Real aParam = aII.GetParameter();
Standard_Real U1,U2,V1,V2;
// Construct a real geometric parameter.
aFace.Orientation(TopAbs_FORWARD);
ShapeAnalysis::GetFaceUVBounds(aFace,U1,U2,V1,V2);
if (isUIso) {
aParam = U1 + (U2 - U1)*aParam;
} else {
aParam = V1 + (V2 - V1)*aParam;
}
aShape = MakeIsoline(aFace, isUIso, aParam);
} else {
Standard_NullObject::Raise
("Shape for isoline construction is not a face");
}
}
else if (aType == EDGE_UV) {
// result may be only an edge
anExpectedType = TopAbs_EDGE;
GEOMImpl_IShapeExtend aSE (aFunction);
Handle(GEOM_Function) aRefEdge = aSE.GetShape();
TopoDS_Shape aShapeEdge = aRefEdge->GetValue();
if (aShapeEdge.ShapeType() == TopAbs_EDGE) {
TopoDS_Edge anEdge = TopoDS::Edge(aShapeEdge);
aShape = ExtendEdge(anEdge, aSE.GetUMin(), aSE.GetUMax());
}
}
else if (aType == FACE_UV) {
// result may be only a face
anExpectedType = TopAbs_FACE;
GEOMImpl_IShapeExtend aSE (aFunction);
Handle(GEOM_Function) aRefFace = aSE.GetShape();
TopoDS_Shape aShapeFace = aRefFace->GetValue();
if (aShapeFace.ShapeType() == TopAbs_FACE) {
TopoDS_Face aFace = TopoDS::Face(aShapeFace);
aFace.Orientation(TopAbs_FORWARD);
aShape = ExtendFace(aFace, aSE.GetUMin(), aSE.GetUMax(),
aSE.GetVMin(), aSE.GetVMax());
}
}
else if (aType == SURFACE_FROM_FACE) {
// result may be only a face
anExpectedType = TopAbs_FACE;
GEOMImpl_IShapeExtend aSE (aFunction);
Handle(GEOM_Function) aRefFace = aSE.GetShape();
TopoDS_Shape aShapeFace = aRefFace->GetValue();
if (aShapeFace.ShapeType() == TopAbs_FACE) {
TopoDS_Face aFace = TopoDS::Face(aShapeFace);
Handle(Geom_Surface) aSurface = BRep_Tool::Surface(aFace);
if (aSurface.IsNull() == Standard_False) {
Handle(Standard_Type) aType = aSurface->DynamicType();
Standard_Real aU1;
Standard_Real aU2;
Standard_Real aV1;
Standard_Real aV2;
// Get U, V bounds of the face.
aFace.Orientation(TopAbs_FORWARD);
ShapeAnalysis::GetFaceUVBounds(aFace, aU1, aU2, aV1, aV2);
// Get the surface of original type
while (aType == STANDARD_TYPE(Geom_RectangularTrimmedSurface)) {
Handle(Geom_RectangularTrimmedSurface) aTrSurface =
Handle(Geom_RectangularTrimmedSurface)::DownCast(aSurface);
aSurface = aTrSurface->BasisSurface();
aType = aSurface->DynamicType();
}
const Standard_Real aTol = BRep_Tool::Tolerance(aFace);
BRepBuilderAPI_MakeFace aMF(aSurface, aU1, aU2, aV1, aV2, aTol);
if (aMF.IsDone()) {
aShape = aMF.Shape();
}
}
}
} else if (aType == EXTRACTION) {
allowCompound = true;
GEOMImpl_IExtract aCI(aFunction);
Handle(GEOM_Function) aRefShape = aCI.GetShape();
TopoDS_Shape aShapeBase = aRefShape->GetValue();
if (aShapeBase.IsNull()) {
Standard_NullObject::Raise("Argument Shape is null");
return 0;
}
Handle(TColStd_HArray1OfInteger) anIDs = aCI.GetSubShapeIDs();
TopTools_ListOfShape aListSubShapes;
TopTools_IndexedMapOfShape anIndices;
int i;
TopExp::MapShapes(aShapeBase, anIndices);
if (!anIDs.IsNull()) {
const int anUpperID = anIDs->Upper();
const int aNbShapes = anIndices.Extent();
for (i = anIDs->Lower(); i <= anUpperID; ++i) {
const Standard_Integer anIndex = anIDs->Value(i);
if (anIndex < 1 || anIndex > aNbShapes) {
TCollection_AsciiString aMsg(" Invalid index: ");
aMsg += TCollection_AsciiString(anIndex);
StdFail_NotDone::Raise(aMsg.ToCString());
return 0;
}
const TopoDS_Shape &aSubShape = anIndices.FindKey(anIndex);
aListSubShapes.Append(aSubShape);
}
}
// Compute extraction.
GEOMAlgo_Extractor anExtractor;
anExtractor.SetShape(aShapeBase);
anExtractor.SetShapesToRemove(aListSubShapes);
anExtractor.Perform();
// Interpret results
Standard_Integer iErr = anExtractor.ErrorStatus();
// The detailed description of error codes is in GEOMAlgo_Extractor.cxx
if (iErr) {
TCollection_AsciiString aMsg(" iErr : ");
aMsg += TCollection_AsciiString(iErr);
StdFail_NotDone::Raise(aMsg.ToCString());
return 0;
}
aShape = anExtractor.GetResult();
if (aShape.IsNull()) {
Standard_ConstructionError::Raise("Result of extraction is empty");
}
// Get statistics.
const TopTools_ListOfShape &aRemoved = anExtractor.GetRemoved();
const TopTools_ListOfShape &aModified = anExtractor.GetModified();
const TopTools_ListOfShape &aNew = anExtractor.GetNew();
Handle(TColStd_HArray1OfInteger) aRemovedIDs =
GetShapeIDs(aRemoved, anIndices);
Handle(TColStd_HArray1OfInteger) aModifiedIDs =
GetShapeIDs(aModified, anIndices);
Handle(TColStd_HArray1OfInteger) aNewIDs;
if (!aShape.IsNull()) {
// Get newly created sub-shapes
TopTools_IndexedMapOfShape aNewIndices;
TopExp::MapShapes(aShape, aNewIndices);
aNewIDs = GetShapeIDs(aNew, aNewIndices);
}
if (!aRemovedIDs.IsNull()) {
aCI.SetRemovedIDs(aRemovedIDs);
}
if (!aModifiedIDs.IsNull()) {
aCI.SetModifiedIDs(aModifiedIDs);
}
if (!aNewIDs.IsNull()) {
aCI.SetAddedIDs(aNewIDs);
}
}
else {
}
if (aShape.IsNull()) return 0;
// Check shape validity
BRepCheck_Analyzer ana (aShape, true);
if (!ana.IsValid()) {
//Standard_ConstructionError::Raise("Algorithm have produced an invalid shape result");
// For Mantis issue 0021772: EDF 2336 GEOM: Non valid face created from two circles
Handle(ShapeFix_Shape) aSfs = new ShapeFix_Shape (aShape);
aSfs->Perform();
aShape = aSfs->Shape();
}
// Check if the result shape is of expected type.
const TopAbs_ShapeEnum aShType = aShape.ShapeType();
bool ok = false;
if ( aShType == TopAbs_COMPOUND || aShType == TopAbs_COMPSOLID ) {
ok = allowCompound && checkCompound( aShape, anExpectedType );
}
else {
ok = ( anExpectedType == TopAbs_SHAPE ) || ( aShType == anExpectedType );
}
if (!ok)
Standard_ConstructionError::Raise("Result type check failed");
aFunction->SetValue(aShape);
log->SetTouched(Label());
if (!aWarning.IsEmpty())
Standard_Failure::Raise(aWarning.ToCString());
return 1;
}
TopoDS_Wire GEOMImpl_ShapeDriver::MakeWireFromEdges(const Handle(TColStd_HSequenceOfTransient)& theEdgesFuncs,
const Standard_Real theTolerance)
{
BRep_Builder B;
TopoDS_Wire aWire;
B.MakeWire(aWire);
// add edges
for (int ind = 1; ind <= theEdgesFuncs->Length(); ind++) {
Handle(GEOM_Function) aRefShape = Handle(GEOM_Function)::DownCast(theEdgesFuncs->Value(ind));
TopoDS_Shape aShape_i = aRefShape->GetValue();
if (aShape_i.IsNull()) {
Standard_NullObject::Raise("Shape for wire construction is null");
}
if (aShape_i.ShapeType() == TopAbs_EDGE || aShape_i.ShapeType() == TopAbs_WIRE) {
TopExp_Explorer exp (aShape_i, TopAbs_EDGE);
for (; exp.More(); exp.Next())
B.Add(aWire, TopoDS::Edge(exp.Current()));
} else {
Standard_TypeMismatch::Raise
("Shape for wire construction is neither an edge nor a wire");
}
}
// fix edges order
Handle(ShapeFix_Wire) aFW = new ShapeFix_Wire;
aFW->Load(aWire);
aFW->FixReorder();
if (aFW->StatusReorder(ShapeExtend_FAIL1)) {
Standard_ConstructionError::Raise("Wire construction failed: several loops detected");
}
else if (aFW->StatusReorder(ShapeExtend_FAIL)) {
Standard_ConstructionError::Raise("Wire construction failed");
}
else {
}
// IMP 0019766: Building a Wire from unconnected edges by introducing a tolerance
bool isClosed = false;
Handle(ShapeAnalysis_Wire) asaw = aFW->Analyzer();
if (asaw->CheckGap3d(1)) { // between last and first edges
Standard_Real dist = asaw->MinDistance3d();
if (dist < theTolerance)
isClosed = true;
}
aFW->ClosedWireMode() = isClosed;
aFW->FixConnected(theTolerance);
if (aFW->StatusConnected(ShapeExtend_FAIL)) {
Standard_ConstructionError::Raise("Wire construction failed: cannot build connected wire");
}
// IMP 0019766
if (aFW->StatusConnected(ShapeExtend_DONE3)) {
// Confused with <prec> but not Analyzer.Precision(), set the same
aFW->SetPrecision(theTolerance); // bos #33377, prevent conversion of initial curves to BSplines
aFW->FixGapsByRangesMode() = Standard_True;
if (aFW->FixGaps3d()) {
Handle(ShapeExtend_WireData) sbwd = aFW->WireData();
Handle(ShapeFix_Edge) aFe = new ShapeFix_Edge;
for (Standard_Integer iedge = 1; iedge <= sbwd->NbEdges(); iedge++) {
TopoDS_Edge aEdge = TopoDS::Edge(sbwd->Edge(iedge));
aFe->FixVertexTolerance(aEdge);
aFe->FixSameParameter(aEdge);
}
}
else if (aFW->StatusGaps3d(ShapeExtend_FAIL)) {
Standard_ConstructionError::Raise("Wire construction failed: cannot fix 3d gaps");
}
}
aWire = aFW->WireAPIMake();
return aWire;
}
TopoDS_Edge GEOMImpl_ShapeDriver::MakeEdgeFromWire(const TopoDS_Shape& aWire,
const Standard_Real LinTol,
const Standard_Real AngTol)
{
TopoDS_Edge ResEdge;
BRepLib::BuildCurves3d(aWire);
Handle(ShapeFix_Shape) Fixer = new ShapeFix_Shape(aWire);
Fixer->SetPrecision(LinTol);
Fixer->SetMaxTolerance(LinTol);
Fixer->Perform();
TopoDS_Wire theWire = TopoDS::Wire(Fixer->Shape());
TColGeom_SequenceOfCurve CurveSeq;
TopTools_SequenceOfShape LocSeq;
TColStd_SequenceOfReal FparSeq;
TColStd_SequenceOfReal LparSeq;
TColStd_SequenceOfReal TolSeq;
GeomAbs_CurveType CurType = GeomAbs_OtherCurve; // todo: refactor: CurType must be explicitly initialized to avoid warning (see below)
TopoDS_Vertex FirstVertex, LastVertex;
Standard_Real aPntShiftDist = 0.;
BRepTools_WireExplorer wexp(theWire) ;
for (; wexp.More(); wexp.Next())
{
TopoDS_Edge anEdge = wexp.Current();
Standard_Real fpar, lpar;
TopLoc_Location aLoc;
Handle(Geom_Curve) aCurve = BRep_Tool::Curve(anEdge, aLoc, fpar, lpar);
if (aCurve.IsNull())
continue;
BRepAdaptor_Curve BAcurve(anEdge);
GeomAbs_CurveType aType = BAcurve.GetType();
Handle(Geom_Curve) aBasisCurve = BAcurve.Curve().Curve();
if (aBasisCurve->IsPeriodic())
ElCLib::AdjustPeriodic(aBasisCurve->FirstParameter(), aBasisCurve->LastParameter(),
Precision::PConfusion(), fpar, lpar);
if (CurveSeq.IsEmpty())
{
CurveSeq.Append(aCurve);
TopoDS_Shape aLocShape;
aLocShape.Location(aLoc);
aLocShape.Orientation(wexp.Orientation());
LocSeq.Append(aLocShape);
FparSeq.Append(fpar);
LparSeq.Append(lpar);
CurType = aType; // todo: refactor: CurType must be explicitly initialized to avoid warning (see above)
FirstVertex = wexp.CurrentVertex();
}
else
{
Standard_Boolean Done = Standard_False;
Standard_Real NewFpar, NewLpar;
Handle(Geom_Geometry) aTrsfGeom = CurveSeq.Last()->Transformed
(LocSeq.Last().Location().Transformation());
GeomAdaptor_Curve GAprevcurve(Handle(Geom_Curve)::DownCast(aTrsfGeom));
TopoDS_Vertex CurVertex = wexp.CurrentVertex();
TopoDS_Vertex CurFirstVer = TopExp::FirstVertex(anEdge);
TopAbs_Orientation ConnectByOrigin = (CurVertex.IsSame(CurFirstVer))? TopAbs_FORWARD : TopAbs_REVERSED;
if (aCurve == CurveSeq.Last() && aLoc.IsEqual(LocSeq.Last().Location()))
{
NewFpar = fpar;
NewLpar = lpar;
if (aBasisCurve->IsPeriodic())
{
if (NewLpar < NewFpar)
NewLpar += aBasisCurve->Period();
if (ConnectByOrigin == TopAbs_FORWARD)
ElCLib::AdjustPeriodic(FparSeq.Last(),
FparSeq.Last() + aBasisCurve->Period(),
Precision::PConfusion(), NewFpar, NewLpar);
else
ElCLib::AdjustPeriodic(FparSeq.Last() - aBasisCurve->Period(),
FparSeq.Last(),
Precision::PConfusion(), NewFpar, NewLpar);
}
Done = Standard_True;
}
else if (aType == CurType &&
aType != GeomAbs_BezierCurve &&
aType != GeomAbs_BSplineCurve &&
aType != GeomAbs_OtherCurve)
{
switch (aType)
{
case GeomAbs_Line:
{
gp_Lin aLine = BAcurve.Line();
gp_Lin PrevLine = GAprevcurve.Line();
if (aLine.Contains(PrevLine.Location(), LinTol) &&
aLine.Direction().IsParallel(PrevLine.Direction(), AngTol))
{
gp_Pnt P1 = ElCLib::Value(fpar, aLine);
gp_Pnt P2 = ElCLib::Value(lpar, aLine);
NewFpar = ElCLib::Parameter(PrevLine, P1);
NewLpar = ElCLib::Parameter(PrevLine, P2);
// Compute shift
if (ConnectByOrigin == TopAbs_FORWARD) {
gp_Pnt aNewP2 = ElCLib::Value(NewLpar, PrevLine);
aPntShiftDist += P2.Distance(aNewP2);
} else {
gp_Pnt aNewP1 = ElCLib::Value(NewFpar, PrevLine);
aPntShiftDist += P1.Distance(aNewP1);
}
if (NewLpar < NewFpar)
{
Standard_Real MemNewFpar = NewFpar;
NewFpar = NewLpar;
NewLpar = MemNewFpar;
ConnectByOrigin = TopAbs::Reverse(ConnectByOrigin);
}
Done = Standard_True;
}
break;
}
case GeomAbs_Circle:
{
gp_Circ aCircle = BAcurve.Circle();
gp_Circ PrevCircle = GAprevcurve.Circle();
if (aCircle.Location().Distance(PrevCircle.Location()) <= LinTol &&
Abs(aCircle.Radius() - PrevCircle.Radius()) <= LinTol &&
aCircle.Axis().IsParallel(PrevCircle.Axis(), AngTol))
{
const Standard_Boolean isFwd = ConnectByOrigin == TopAbs_FORWARD;
if (aCircle.Axis().Direction() * PrevCircle.Axis().Direction() < 0.)
{
Standard_Real memfpar = fpar;
fpar = lpar;
lpar = memfpar;
ConnectByOrigin = TopAbs::Reverse(ConnectByOrigin);
}
gp_Pnt P1 = ElCLib::Value(fpar, aCircle);
gp_Pnt P2 = ElCLib::Value(lpar, aCircle);
NewFpar = ElCLib::Parameter(PrevCircle, P1);
NewLpar = ElCLib::Parameter(PrevCircle, P2);
// Compute shift
if (isFwd) {
gp_Pnt aNewP2 = ElCLib::Value(NewLpar, PrevCircle);
aPntShiftDist += P2.Distance(aNewP2);
} else {
gp_Pnt aNewP1 = ElCLib::Value(NewFpar, PrevCircle);
aPntShiftDist += P1.Distance(aNewP1);
}
if (NewLpar < NewFpar)
NewLpar += 2.*M_PI;
//Standard_Real MemNewFpar = NewFpar, MemNewLpar = NewLpar;
if (ConnectByOrigin == TopAbs_FORWARD)
ElCLib::AdjustPeriodic(FparSeq.Last(),
FparSeq.Last() + 2.*M_PI,
Precision::PConfusion(), NewFpar, NewLpar);
else
ElCLib::AdjustPeriodic(FparSeq.Last() - 2.*M_PI,
FparSeq.Last(),
Precision::PConfusion(), NewFpar, NewLpar);
Done = Standard_True;
}
break;
}
case GeomAbs_Ellipse:
{
gp_Elips anEllipse = BAcurve.Ellipse();
gp_Elips PrevEllipse = GAprevcurve.Ellipse();
if (anEllipse.Focus1().Distance(PrevEllipse.Focus1()) <= LinTol &&
anEllipse.Focus2().Distance(PrevEllipse.Focus2()) <= LinTol &&
Abs(anEllipse.MajorRadius() - PrevEllipse.MajorRadius()) <= LinTol &&
Abs(anEllipse.MinorRadius() - PrevEllipse.MinorRadius()) <= LinTol &&
anEllipse.Axis().IsParallel(PrevEllipse.Axis(), AngTol))
{
const Standard_Boolean isFwd = ConnectByOrigin == TopAbs_FORWARD;
if (anEllipse.Axis().Direction() * PrevEllipse.Axis().Direction() < 0.)
{
Standard_Real memfpar = fpar;
fpar = lpar;
lpar = memfpar;
ConnectByOrigin = TopAbs::Reverse(ConnectByOrigin);
}
gp_Pnt P1 = ElCLib::Value(fpar, anEllipse);
gp_Pnt P2 = ElCLib::Value(lpar, anEllipse);
NewFpar = ElCLib::Parameter(PrevEllipse, P1);
NewLpar = ElCLib::Parameter(PrevEllipse, P2);
// Compute shift
if (isFwd) {
gp_Pnt aNewP2 = ElCLib::Value(NewLpar, PrevEllipse);
aPntShiftDist += P2.Distance(aNewP2);
} else {
gp_Pnt aNewP1 = ElCLib::Value(NewFpar, PrevEllipse);
aPntShiftDist += P1.Distance(aNewP1);
}
if (NewLpar < NewFpar)
NewLpar += 2.*M_PI;
if (ConnectByOrigin == TopAbs_FORWARD)
ElCLib::AdjustPeriodic(FparSeq.Last(),
FparSeq.Last() + 2.*M_PI,
Precision::PConfusion(), NewFpar, NewLpar);
else
ElCLib::AdjustPeriodic(FparSeq.Last() - 2.*M_PI,
FparSeq.Last(),
Precision::PConfusion(), NewFpar, NewLpar);
Done = Standard_True;
}
break;
}
case GeomAbs_Hyperbola:
{
gp_Hypr aHypr = BAcurve.Hyperbola();
gp_Hypr PrevHypr = GAprevcurve.Hyperbola();
if (aHypr.Focus1().Distance(PrevHypr.Focus1()) <= LinTol &&
aHypr.Focus2().Distance(PrevHypr.Focus2()) <= LinTol &&
Abs(aHypr.MajorRadius() - PrevHypr.MajorRadius()) <= LinTol &&
Abs(aHypr.MinorRadius() - PrevHypr.MinorRadius()) <= LinTol &&
aHypr.Axis().IsParallel(PrevHypr.Axis(), AngTol))
{
gp_Pnt P1 = ElCLib::Value(fpar, aHypr);
gp_Pnt P2 = ElCLib::Value(lpar, aHypr);
NewFpar = ElCLib::Parameter(PrevHypr, P1);
NewLpar = ElCLib::Parameter(PrevHypr, P2);
// Compute shift
if (ConnectByOrigin == TopAbs_FORWARD) {
gp_Pnt aNewP2 = ElCLib::Value(NewLpar, PrevHypr);
aPntShiftDist += P2.Distance(aNewP2);
} else {
gp_Pnt aNewP1 = ElCLib::Value(NewFpar, PrevHypr);
aPntShiftDist += P1.Distance(aNewP1);
}
if (NewLpar < NewFpar)
{
Standard_Real MemNewFpar = NewFpar;
NewFpar = NewLpar;
NewLpar = MemNewFpar;
ConnectByOrigin = TopAbs::Reverse(ConnectByOrigin);
}
Done = Standard_True;
}
break;
}
case GeomAbs_Parabola:
{
gp_Parab aParab = BAcurve.Parabola();
gp_Parab PrevParab = GAprevcurve.Parabola();
if (aParab.Location().Distance(PrevParab.Location()) <= LinTol &&
aParab.Focus().Distance(PrevParab.Focus()) <= LinTol &&
Abs(aParab.Focal() - PrevParab.Focal()) <= LinTol &&
aParab.Axis().IsParallel(PrevParab.Axis(), AngTol))
{
gp_Pnt P1 = ElCLib::Value(fpar, aParab);
gp_Pnt P2 = ElCLib::Value(lpar, aParab);
NewFpar = ElCLib::Parameter(PrevParab, P1);
NewLpar = ElCLib::Parameter(PrevParab, P2);
// Compute shift
if (ConnectByOrigin == TopAbs_FORWARD) {
gp_Pnt aNewP2 = ElCLib::Value(NewLpar, PrevParab);
aPntShiftDist += P2.Distance(aNewP2);
} else {
gp_Pnt aNewP1 = ElCLib::Value(NewFpar, PrevParab);
aPntShiftDist += P1.Distance(aNewP1);
}
if (NewLpar < NewFpar)
{
Standard_Real MemNewFpar = NewFpar;
NewFpar = NewLpar;
NewLpar = MemNewFpar;
ConnectByOrigin = TopAbs::Reverse(ConnectByOrigin);
}
Done = Standard_True;
}
break;
}
default:
break;
} //end of switch (aType)
} // end of else if (aType == CurType && ...
if (Done)
{
if (NewFpar < FparSeq.Last())
FparSeq(FparSeq.Length()) = NewFpar;
else
LparSeq(LparSeq.Length()) = NewLpar;
}
else
{
CurveSeq.Append(aCurve);
TopoDS_Shape aLocShape;
aLocShape.Location(aLoc);
aLocShape.Orientation(wexp.Orientation());
LocSeq.Append(aLocShape);
FparSeq.Append(fpar);
LparSeq.Append(lpar);
TolSeq.Append(aPntShiftDist + BRep_Tool::Tolerance(CurVertex));
aPntShiftDist = 0.;
CurType = aType;
}
} // end of else (CurveSeq.IsEmpty()) -> not first time
} // end for (; wexp.More(); wexp.Next())
LastVertex = wexp.CurrentVertex();
TolSeq.Append(aPntShiftDist + BRep_Tool::Tolerance(LastVertex));
FirstVertex.Orientation(TopAbs_FORWARD);
LastVertex.Orientation(TopAbs_REVERSED);
if (!CurveSeq.IsEmpty())
{
Standard_Integer nb_curve = CurveSeq.Length(); //number of curves
TColGeom_Array1OfBSplineCurve tab(0,nb_curve-1); //array of the curves
TColStd_Array1OfReal tabtolvertex(0,nb_curve-1); //(0,nb_curve-2); //array of the tolerances
Standard_Integer i;
if (nb_curve > 1)
{
for (i = 1; i <= nb_curve; i++)
{
if (CurveSeq(i)->IsInstance(STANDARD_TYPE(Geom_TrimmedCurve)))
CurveSeq(i) = (*((Handle(Geom_TrimmedCurve)*)&(CurveSeq(i))))->BasisCurve();
Handle(Geom_TrimmedCurve) aTrCurve = new Geom_TrimmedCurve(CurveSeq(i), FparSeq(i), LparSeq(i));
tab(i-1) = GeomConvert::CurveToBSplineCurve(aTrCurve);
tab(i-1)->Transform(LocSeq(i).Location().Transformation());
GeomConvert::C0BSplineToC1BSplineCurve(tab(i-1), Precision::Confusion());
if (LocSeq(i).Orientation() == TopAbs_REVERSED)
tab(i-1)->Reverse();
//Temporary
//char* name = new char[100];
//sprintf(name, "c%d", i);
//DrawTrSurf::Set(name, tab(i-1));
if (i > 1)
tabtolvertex(i-2) = TolSeq(i-1);
} // end for (i = 1; i <= nb_curve; i++)
tabtolvertex(nb_curve-1) = TolSeq(TolSeq.Length());
Standard_Boolean closed_flag = Standard_False;
Standard_Real closed_tolerance = 0.;
if (FirstVertex.IsSame(LastVertex) &&
GeomLProp::Continuity(tab(0), tab(nb_curve-1),
tab(0)->FirstParameter(),
tab(nb_curve-1)->LastParameter(),
Standard_False, Standard_False, LinTol, AngTol) >= GeomAbs_G1)
{
closed_flag = Standard_True ;
closed_tolerance = BRep_Tool::Tolerance(FirstVertex);
}
Handle(TColGeom_HArray1OfBSplineCurve) concatcurve; //array of the concatenated curves
Handle(TColStd_HArray1OfInteger) ArrayOfIndices; //array of the remining Vertex
GeomConvert::ConcatC1(tab,
tabtolvertex,
ArrayOfIndices,
concatcurve,
closed_flag,
closed_tolerance); //C1 concatenation
if (concatcurve->Length() > 1)
{
GeomConvert_CompCurveToBSplineCurve Concat(concatcurve->Value(concatcurve->Lower()));
for (i = concatcurve->Lower()+1; i <= concatcurve->Upper(); i++)
Concat.Add( concatcurve->Value(i), LinTol, Standard_True );
concatcurve->SetValue(concatcurve->Lower(), Concat.BSplineCurve());
}
// rnc : prevents the driver from building an edge without C1 continuity
if (concatcurve->Value(concatcurve->Lower())->Continuity()==GeomAbs_C0){
Standard_ConstructionError::Raise("Construction aborted : The given Wire has sharp bends between some Edges, no valid Edge can be built");
}
Standard_Boolean isValidEndVtx = Standard_True;
if (closed_flag) {
// Check if closed curve is reordered.
Handle(Geom_BSplineCurve) aCurve = concatcurve->Value(concatcurve->Lower());
Standard_Real aFPar = aCurve->FirstParameter();
gp_Pnt aPFirst;
gp_Pnt aPntVtx = BRep_Tool::Pnt(FirstVertex);
Standard_Real aTolVtx = BRep_Tool::Tolerance(FirstVertex);
aCurve->D0(aFPar, aPFirst);
if (!aPFirst.IsEqual(aPntVtx, aTolVtx)) {
// The curve is reordered. Find the new first and last vertices.
TopTools_IndexedMapOfShape aMapVtx;
TopExp::MapShapes(theWire, TopAbs_VERTEX, aMapVtx);
const Standard_Integer aNbVtx = aMapVtx.Extent();
Standard_Integer iVtx;
for (iVtx = 1; iVtx <= aNbVtx; iVtx++) {
const TopoDS_Vertex aVtx = TopoDS::Vertex(aMapVtx.FindKey(iVtx));
const gp_Pnt aPnt = BRep_Tool::Pnt(aVtx);
const Standard_Real aTol = BRep_Tool::Tolerance(aVtx);
if (aPFirst.IsEqual(aPnt, aTol)) {
// The coincident vertex is found.
FirstVertex = aVtx;
LastVertex = aVtx;
FirstVertex.Orientation(TopAbs_FORWARD);
LastVertex.Orientation(TopAbs_REVERSED);
break;
}
}
if (iVtx > aNbVtx) {
// It is necessary to create new vertices.
isValidEndVtx = Standard_False;
}
}
}
if (isValidEndVtx) {
ResEdge = BRepLib_MakeEdge(concatcurve->Value(concatcurve->Lower()),
FirstVertex, LastVertex,
concatcurve->Value(concatcurve->Lower())->FirstParameter(),
concatcurve->Value(concatcurve->Lower())->LastParameter());
} else {
ResEdge = BRepLib_MakeEdge(concatcurve->Value(concatcurve->Lower()),
concatcurve->Value(concatcurve->Lower())->FirstParameter(),
concatcurve->Value(concatcurve->Lower())->LastParameter());
}
}
else
{
if (CurveSeq(1)->IsInstance(STANDARD_TYPE(Geom_TrimmedCurve)))
CurveSeq(1) = (*((Handle(Geom_TrimmedCurve)*)&(CurveSeq(1))))->BasisCurve();
Handle(Geom_Curve) aNewCurve =
Handle(Geom_Curve)::DownCast(CurveSeq(1)->Copy());
aNewCurve->Transform(LocSeq(1).Location().Transformation());
if (LocSeq(1).Orientation() == TopAbs_REVERSED) {
const TopoDS_Vertex aVtxTmp = FirstVertex;
FirstVertex = LastVertex;
LastVertex = aVtxTmp;
FirstVertex.Orientation(TopAbs_FORWARD);
LastVertex.Orientation(TopAbs_REVERSED);
}
ResEdge = BRepLib_MakeEdge(aNewCurve,
FirstVertex, LastVertex,
FparSeq(1), LparSeq(1));
if (LocSeq(1).Orientation() == TopAbs_REVERSED) {
ResEdge.Reverse();
}
}
}
return ResEdge;
}
//=============================================================================
/*!
* \brief Returns an isoline for a face.
*/
//=============================================================================
TopoDS_Shape GEOMImpl_ShapeDriver::MakeIsoline
(const TopoDS_Face &theFace,
const bool IsUIso,
const double theParameter) const
{
TopoDS_Shape aResult;
GEOMUtils::Hatcher aHatcher(theFace);
const GeomAbs_IsoType aType = (IsUIso ? GeomAbs_IsoU : GeomAbs_IsoV);
aHatcher.Init(aType, theParameter);
aHatcher.Perform();
if (!aHatcher.IsDone()) {
Standard_ConstructionError::Raise("MakeIsoline : Hatcher failure");
}
const Handle(TColStd_HArray1OfInteger) &anIndices =
(IsUIso ? aHatcher.GetUIndices() : aHatcher.GetVIndices());
if (anIndices.IsNull()) {
Standard_ConstructionError::Raise("MakeIsoline : Null hatching indices");
}
const Standard_Integer anIsoInd = anIndices->Lower();
const Standard_Integer aHatchingIndex = anIndices->Value(anIsoInd);
if (aHatchingIndex == 0) {
Standard_ConstructionError::Raise("MakeIsoline : Invalid hatching index");
}
const Standard_Integer aNbDomains =
aHatcher.GetNbDomains(aHatchingIndex);
if (aNbDomains < 0) {
Standard_ConstructionError::Raise("MakeIsoline : Invalid number of domains");
}
// The hatching is performed successfully. Create the 3d Curve.
Handle(Geom_Surface) aSurface = BRep_Tool::Surface(theFace);
Handle(Geom_Curve) anIsoCurve = (IsUIso ?
aSurface->UIso(theParameter) : aSurface->VIso(theParameter));
Handle(Geom2d_Curve) aPIsoCurve = aHatcher.GetHatching(aHatchingIndex);
Standard_Real aTol = BRep_Tool::MaxTolerance(theFace, TopAbs_EDGE);
Standard_Integer anIDom = 1;
Standard_Real aV1;
Standard_Real aV2;
BRep_Builder aBuilder;
Standard_Integer aNbEdges = 0;
for (; anIDom <= aNbDomains; anIDom++) {
if (aHatcher.GetDomain(aHatchingIndex, anIDom, aV1, aV2)) {
// Check first and last parameters.
if (!aHatcher.IsDomainInfinite(aHatchingIndex, anIDom)) {
// Create an edge.
TopoDS_Edge anEdge = BRepBuilderAPI_MakeEdge(anIsoCurve, aV1, aV2);
// Update it with a parametric curve on face.
aBuilder.UpdateEdge(anEdge, aPIsoCurve, theFace, aTol);
for (TopExp_Explorer ExV (anEdge, TopAbs_VERTEX); ExV.More(); ExV.Next()) {
TopoDS_Vertex V = TopoDS::Vertex(ExV.Current());
aBuilder.UpdateVertex(V, aTol);
}
aNbEdges++;
if (aNbEdges > 1) {
// Result is a compond.
if (aNbEdges == 2) {
// Create a new compound.
TopoDS_Compound aCompound;
aBuilder.MakeCompound(aCompound);
aBuilder.Add(aCompound, aResult);
aResult = aCompound;
}
// Add an edge to the compound.
aBuilder.Add(aResult, anEdge);
} else {
// Result is the edge.
aResult = anEdge;
}
}
}
}
if (aNbEdges == 0) {
Standard_ConstructionError::Raise("MakeIsoline : Empty result");
}
return aResult;
}
//=============================================================================
/*!
* \brief Returns an extended edge.
*/
//=============================================================================
TopoDS_Shape GEOMImpl_ShapeDriver::ExtendEdge
(const TopoDS_Edge &theEdge,
const Standard_Real theMin,
const Standard_Real theMax) const
{
TopoDS_Shape aResult;
Standard_Real aF;
Standard_Real aL;
Handle(Geom_Curve) aCurve = BRep_Tool::Curve(theEdge, aF, aL);
const Standard_Real aTol = BRep_Tool::Tolerance(theEdge);
Standard_Real aRange2d = aL - aF;
if (aCurve.IsNull() == Standard_False && aRange2d > aTol) {
Standard_Real aMin = aF + aRange2d*theMin;
Standard_Real aMax = aF + aRange2d*theMax;
Handle(Standard_Type) aType = aCurve->DynamicType();
// Get the curve of original type
while (aType == STANDARD_TYPE(Geom_TrimmedCurve)) {
Handle(Geom_TrimmedCurve) aTrCurve =
Handle(Geom_TrimmedCurve)::DownCast(aCurve);
aCurve = aTrCurve->BasisCurve();
aType = aCurve->DynamicType();
}
if (aCurve->IsPeriodic()) {
// The curve is periodic. Check if a new range is less then a period.
if (aMax - aMin > aCurve->Period()) {
aMax = aMin + aCurve->Period();
}
} else {
// The curve is not periodic. Check if aMin and aMax within bounds.
aMin = Max(aMin, aCurve->FirstParameter());
aMax = Min(aMax, aCurve->LastParameter());
}
if (aMax - aMin > aTol) {
// Create a new edge.
BRepBuilderAPI_MakeEdge aME (aCurve, aMin, aMax);
if (aME.IsDone()) {
aResult = aME.Shape();
}
}
}
return aResult;
}
//=============================================================================
/*!
* \brief Returns an extended face.
*/
//=============================================================================
TopoDS_Shape GEOMImpl_ShapeDriver::ExtendFace
(const TopoDS_Face &theFace,
const Standard_Real theUMin,
const Standard_Real theUMax,
const Standard_Real theVMin,
const Standard_Real theVMax) const
{
TopoDS_Shape aResult;
Handle(Geom_Surface) aSurface = BRep_Tool::Surface(theFace);
const Standard_Real aTol = BRep_Tool::Tolerance(theFace);
Standard_Real aU1;
Standard_Real aU2;
Standard_Real aV1;
Standard_Real aV2;
// Get U, V bounds of the face.
ShapeAnalysis::GetFaceUVBounds(theFace, aU1, aU2, aV1, aV2);
const Standard_Real aURange = aU2 - aU1;
const Standard_Real aVRange = aV2 - aV1;
if (aSurface.IsNull() == Standard_False &&
aURange > aTol && aURange > aTol) {
Handle(Standard_Type) aType = aSurface->DynamicType();
// Get the surface of original type
while (aType == STANDARD_TYPE(Geom_RectangularTrimmedSurface)) {
Handle(Geom_RectangularTrimmedSurface) aTrSurface =
Handle(Geom_RectangularTrimmedSurface)::DownCast(aSurface);
aSurface = aTrSurface->BasisSurface();
aType = aSurface->DynamicType();
}
Standard_Real aUMin = aU1 + aURange*theUMin;
Standard_Real aUMax = aU1 + aURange*theUMax;
Standard_Real aVMin = aV1 + aVRange*theVMin;
Standard_Real aVMax = aV1 + aVRange*theVMax;
aSurface->Bounds(aU1, aU2, aV1, aV2);
if (aSurface->IsUPeriodic()) {
// The surface is U-periodic. Check if a new U range is less
// then a period.
if (aUMax - aUMin > aSurface->UPeriod()) {
aUMax = aUMin + aSurface->UPeriod();
}
} else {
// The surface is not V-periodic. Check if aUMin and aUMax
// within bounds.
aUMin = Max(aUMin, aU1);
aUMax = Min(aUMax, aU2);
}
if (aSurface->IsVPeriodic()) {
// The surface is V-periodic. Check if a new V range is less
// then a period.
if (aVMax - aVMin > aSurface->VPeriod()) {
aVMax = aVMin + aSurface->VPeriod();
}
} else {
// The surface is not V-periodic. Check if aVMin and aVMax
// within bounds.
aVMin = Max(aVMin, aV1);
aVMax = Min(aVMax, aV2);
}
if (aUMax - aUMin > aTol && aVMax - aVMin > aTol) {
// Create a new edge.
BRepBuilderAPI_MakeFace aMF
(aSurface, aUMin, aUMax, aVMin, aVMax, aTol);
if (aMF.IsDone()) {
aResult = aMF.Shape();
}
}
}
return aResult;
}
//================================================================================
/*!
* \brief Returns a name of creation operation and names and values of creation parameters
*/
//================================================================================
bool GEOMImpl_ShapeDriver::
GetCreationInformation(std::string& theOperationName,
std::vector<GEOM_Param>& theParams)
{
if (Label().IsNull()) return 0;
Handle(GEOM_Function) function = GEOM_Function::GetFunction(Label());
GEOMImpl_IShapes aCI( function );
Standard_Integer aType = function->GetType();
switch ( aType ) {
case WIRE_EDGES:
theOperationName = "WIRE";
AddParam( theParams, "Wires/edges", aCI.GetShapes() );
AddParam( theParams, "Tolerance", aCI.GetTolerance() );
break;
case FACE_WIRE:
theOperationName = "FACE";
AddParam( theParams, "Wire/edge", aCI.GetBase() );
AddParam( theParams, "Is planar wanted", aCI.GetIsPlanar() );
break;
case FACE_WIRES:
theOperationName = "FACE";
AddParam( theParams, "Wires/edges", aCI.GetShapes() );
AddParam( theParams, "Is planar wanted", aCI.GetIsPlanar() );
break;
case FACE_FROM_SURFACE:
{
theOperationName = "FACE";
Handle(TColStd_HSequenceOfTransient) shapes = aCI.GetShapes();
if (shapes.IsNull() == Standard_False) {
Standard_Integer aNbShapes = shapes->Length();
if (aNbShapes > 0) {
AddParam(theParams, "Face", shapes->Value(1));
if (aNbShapes > 1) {
AddParam(theParams, "Wire", shapes->Value(2));
}
}
}
break;
}
case SHELL_FACES:
theOperationName = "SHELL";
AddParam( theParams, "Objects", aCI.GetShapes() );
break;
case SOLID_SHELLS:
theOperationName = "SOLID";
AddParam( theParams, "Objects", aCI.GetShapes() );
break;
case SOLID_FACES:
theOperationName = "SOLID_FROM_FACES";
AddParam( theParams, "Objects", aCI.GetShapes() );
AddParam( theParams, "Is intersect", aCI.GetIsIntersect() );
break;
case COMPOUND_SHAPES:
theOperationName = "COMPOUND";
AddParam( theParams, "Objects", aCI.GetShapes() );
break;
case EDGE_WIRE:
theOperationName = "EDGE";
AddParam( theParams, "Wire", aCI.GetBase() );
AddParam( theParams, "Linear Tolerance", aCI.GetTolerance() );
AddParam( theParams, "Angular Tolerance", aCI.GetAngularTolerance() );
break;
case EDGE_CURVE_LENGTH:
theOperationName = "EDGE";
{
GEOMImpl_IVector aCI( function );
AddParam( theParams, "Edge", aCI.GetPoint1() );
AddParam( theParams, "Start point", aCI.GetPoint2() );
AddParam( theParams, "Length", aCI.GetParameter() );
}
break;
case SHAPES_ON_SHAPE:
{
theOperationName = "GetShapesOnShapeAsCompound";
Handle(TColStd_HSequenceOfTransient) shapes = aCI.GetShapes();
if ( !shapes.IsNull() && shapes->Length() > 0 )
AddParam( theParams, "Check shape", shapes->Value(1) );
if ( !shapes.IsNull() && shapes->Length() > 1 )
AddParam( theParams, "Shape", shapes->Value(2) );
AddParam( theParams, "Shape type", TopAbs_ShapeEnum( aCI.GetSubShapeType() ));
AddParam( theParams, "State" );
GEOMAlgo_State st = GEOMAlgo_State( (int) ( aCI.GetTolerance()+0.1 ) );
const char* stName[] = { "UNKNOWN","IN","OUT","ON","ONIN","ONOUT","INOUT" };
if ( 0 <= st && st <= GEOMAlgo_ST_INOUT )
theParams.back() << stName[ st ];
else
theParams.back() << (int) st;
break;
}
case SHAPE_ISOLINE:
{
GEOMImpl_IIsoline aII (function);
theOperationName = "ISOLINE";
AddParam(theParams, "Face", aII.GetFace());
AddParam(theParams, "Isoline type", (aII.GetIsUIso() ? "U" : "V"));
AddParam(theParams, "Parameter", aII.GetParameter());
break;
}
case EDGE_UV:
{
GEOMImpl_IShapeExtend aSE (function);
theOperationName = "EDGE_EXTEND";
AddParam(theParams, "Edge", aSE.GetShape());
AddParam(theParams, "Min", aSE.GetUMin());
AddParam(theParams, "Max", aSE.GetUMax());
break;
}
case FACE_UV:
{
GEOMImpl_IShapeExtend aSE (function);
theOperationName = "FACE_EXTEND";
AddParam(theParams, "Face", aSE.GetShape());
AddParam(theParams, "UMin", aSE.GetUMin());
AddParam(theParams, "UMax", aSE.GetUMax());
AddParam(theParams, "VMin", aSE.GetVMin());
AddParam(theParams, "VMax", aSE.GetVMax());
break;
}
case SURFACE_FROM_FACE:
{
GEOMImpl_IShapeExtend aSE (function);
theOperationName = "SURFACE_FROM_FACE";
AddParam(theParams, "Face", aSE.GetShape());
break;
}
case EXTRACTION:
{
GEOMImpl_IExtract aCI (function);
theOperationName = "EXTRACTION";
AddParam(theParams, "Main Shape", aCI.GetShape());
AddParam(theParams, "Sub-shape IDs", aCI.GetSubShapeIDs());
break;
}
default:
return false;
}
return true;
}
IMPLEMENT_STANDARD_RTTIEXT (GEOMImpl_ShapeDriver,GEOM_BaseDriver)
//modified by NIZNHY-PKV Wed Dec 28 13:48:31 2011f
#include <TopoDS_Iterator.hxx>
#include <TopTools_HSequenceOfShape.hxx>
#include <ShapeAnalysis_FreeBounds.hxx>
#include <TopTools_MapOfShape.hxx>
#include <TopTools_MapOfOrientedShape.hxx>
#include <BRep_Builder.hxx>
#include <TopoDS_Wire.hxx>
//=======================================================================
//function : KeepEdgesOrder
//purpose :
//=======================================================================
/*
void KeepEdgesOrder(const Handle(TopTools_HSequenceOfShape)& aEdges,
const Handle(TopTools_HSequenceOfShape)& aWires)
{
Standard_Integer aNbWires, aNbEdges;
//
if (aEdges.IsNull()) {
return;
}
//
if (aWires.IsNull()) {
return;
}
//
aNbEdges=aEdges->Length();
aNbWires=aWires->Length();
if (!aNbEdges || !aNbWires) {
return;
}
//-----
Standard_Boolean bClosed;
Standard_Integer i, j;
TopoDS_Wire aWy;
TopoDS_Iterator aIt;
BRep_Builder aBB;
TopTools_MapOfOrientedShape aMEx;
//
for (i=1; i<=aNbWires; ++i) {
const TopoDS_Shape& aWx=aWires->Value(i);
//
aMEx.Clear();
aIt.Initialize (aWx);
for (; aIt.More(); aIt.Next()) {
const TopoDS_Shape& aEx=aIt.Value();
aMEx.Add(aEx);
}
// aWy
aBB.MakeWire (aWy);
for (j=1; j<=aNbEdges; ++j) {
const TopoDS_Shape& aE=aEdges->Value(j);
if (aMEx.Contains(aE)) {
aBB.Add(aWy, aE);
}
}
//
bClosed=aWx.Closed();
aWy.Closed(bClosed);
//
aWires->Append(aWy);
}// for (i=1; i<=aNbWires; ++i) {
//
aWires->Remove(1, aNbWires);
}
*/
//modified by NIZNHY-PKV Wed Dec 28 13:48:34 2011t