void Revolution::updateAxis(void) { Part::Part2DObject* sketch = getVerifiedSketch(); Base::Placement SketchPlm = sketch->Placement.getValue(); // get reference axis App::DocumentObject *pcReferenceAxis = ReferenceAxis.getValue(); const std::vector<std::string> &subReferenceAxis = ReferenceAxis.getSubValues(); if (pcReferenceAxis && pcReferenceAxis == sketch) { bool hasValidAxis=false; Base::Axis axis; if (subReferenceAxis[0] == "V_Axis") { hasValidAxis = true; axis = sketch->getAxis(Part::Part2DObject::V_Axis); } else if (subReferenceAxis[0] == "H_Axis") { hasValidAxis = true; axis = sketch->getAxis(Part::Part2DObject::H_Axis); } else if (subReferenceAxis[0].size() > 4 && subReferenceAxis[0].substr(0,4) == "Axis") { int AxId = std::atoi(subReferenceAxis[0].substr(4,4000).c_str()); if (AxId >= 0 && AxId < sketch->getAxisCount()) { hasValidAxis = true; axis = sketch->getAxis(AxId); } } if (hasValidAxis) { axis *= SketchPlm; Base::Vector3d base=axis.getBase(); Base::Vector3d dir=axis.getDirection(); Base.setValue(base.x,base.y,base.z); Axis.setValue(dir.x,dir.y,dir.z); } } }
void ProfileBased::getAxis(const App::DocumentObject *pcReferenceAxis, const std::vector<std::string> &subReferenceAxis, Base::Vector3d& base, Base::Vector3d& dir) { dir = Base::Vector3d(0,0,0); // If unchanged signals that no valid axis was found if (pcReferenceAxis == NULL) return; App::DocumentObject* profile = Profile.getValue(); gp_Pln sketchplane; if (profile->getTypeId().isDerivedFrom(Part::Part2DObject::getClassTypeId())) { Part::Part2DObject* sketch = getVerifiedSketch(); Base::Placement SketchPlm = sketch->Placement.getValue(); Base::Vector3d SketchVector = Base::Vector3d(0, 0, 1); Base::Rotation SketchOrientation = SketchPlm.getRotation(); SketchOrientation.multVec(SketchVector, SketchVector); Base::Vector3d SketchPos = SketchPlm.getPosition(); sketchplane = gp_Pln(gp_Pnt(SketchPos.x, SketchPos.y, SketchPos.z), gp_Dir(SketchVector.x, SketchVector.y, SketchVector.z)); if (pcReferenceAxis == profile) { bool hasValidAxis = false; Base::Axis axis; if (subReferenceAxis[0] == "V_Axis") { hasValidAxis = true; axis = sketch->getAxis(Part::Part2DObject::V_Axis); } else if (subReferenceAxis[0] == "H_Axis") { hasValidAxis = true; axis = sketch->getAxis(Part::Part2DObject::H_Axis); } else if (subReferenceAxis[0].size() > 4 && subReferenceAxis[0].substr(0, 4) == "Axis") { int AxId = std::atoi(subReferenceAxis[0].substr(4, 4000).c_str()); if (AxId >= 0 && AxId < sketch->getAxisCount()) { hasValidAxis = true; axis = sketch->getAxis(AxId); } } if (hasValidAxis) { axis *= SketchPlm; base = axis.getBase(); dir = axis.getDirection(); return; } //else - an edge of the sketch was selected as an axis } } else if (profile->getTypeId().isDerivedFrom(Part::Feature::getClassTypeId())) { Base::Placement SketchPlm = getVerifiedObject()->Placement.getValue(); Base::Vector3d SketchVector = getProfileNormal(); Base::Vector3d SketchPos = SketchPlm.getPosition(); sketchplane = gp_Pln(gp_Pnt(SketchPos.x, SketchPos.y, SketchPos.z), gp_Dir(SketchVector.x, SketchVector.y, SketchVector.z)); } // get reference axis if (pcReferenceAxis->getTypeId().isDerivedFrom(PartDesign::Line::getClassTypeId())) { const PartDesign::Line* line = static_cast<const PartDesign::Line*>(pcReferenceAxis); base = line->getBasePoint(); dir = line->getDirection(); // Check that axis is perpendicular with sketch plane! if (sketchplane.Axis().Direction().IsParallel(gp_Dir(dir.x, dir.y, dir.z), Precision::Angular())) throw Base::ValueError("Rotation axis must not be perpendicular with the sketch plane"); return; } if (pcReferenceAxis->getTypeId().isDerivedFrom(App::Line::getClassTypeId())) { const App::Line* line = static_cast<const App::Line*>(pcReferenceAxis); base = Base::Vector3d(0,0,0); line->Placement.getValue().multVec(Base::Vector3d (1,0,0), dir); // Check that axis is perpendicular with sketch plane! if (sketchplane.Axis().Direction().IsParallel(gp_Dir(dir.x, dir.y, dir.z), Precision::Angular())) throw Base::ValueError("Rotation axis must not be perpendicular with the sketch plane"); return; } if (pcReferenceAxis->getTypeId().isDerivedFrom(Part::Feature::getClassTypeId())) { if (subReferenceAxis.empty()) throw Base::ValueError("No rotation axis reference specified"); const Part::Feature* refFeature = static_cast<const Part::Feature*>(pcReferenceAxis); Part::TopoShape refShape = refFeature->Shape.getShape(); TopoDS_Shape ref = refShape.getSubShape(subReferenceAxis[0].c_str()); if (ref.ShapeType() == TopAbs_EDGE) { TopoDS_Edge refEdge = TopoDS::Edge(ref); if (refEdge.IsNull()) throw Base::ValueError("Failed to extract rotation edge"); BRepAdaptor_Curve adapt(refEdge); if (adapt.GetType() != GeomAbs_Line) throw Base::TypeError("Rotation edge must be a straight line"); gp_Pnt b = adapt.Line().Location(); base = Base::Vector3d(b.X(), b.Y(), b.Z()); gp_Dir d = adapt.Line().Direction(); dir = Base::Vector3d(d.X(), d.Y(), d.Z()); // Check that axis is co-planar with sketch plane! // Check that axis is perpendicular with sketch plane! if (sketchplane.Axis().Direction().IsParallel(d, Precision::Angular())) throw Base::ValueError("Rotation axis must not be perpendicular with the sketch plane"); return; } else { throw Base::TypeError("Rotation reference must be an edge"); } } throw Base::TypeError("Rotation axis reference is invalid"); }
const std::list<gp_Trsf> PolarPattern::getTransformations(const std::vector<App::DocumentObject*>) { float angle = Angle.getValue(); if (angle < Precision::Confusion()) throw Base::Exception("Pattern angle too small"); int occurrences = Occurrences.getValue(); if (occurrences < 2) throw Base::Exception("At least two occurrences required"); bool reversed = Reversed.getValue(); double offset; if (std::abs(angle - 360.0) < Precision::Confusion()) offset = Base::toRadians<double>(angle) / occurrences; // Because e.g. two occurrences in 360 degrees need to be 180 degrees apart else offset = Base::toRadians<double>(angle) / (occurrences - 1); App::DocumentObject* refObject = Axis.getValue(); if (refObject == NULL) throw Base::Exception("No axis reference specified"); if (!refObject->getTypeId().isDerivedFrom(Part::Feature::getClassTypeId())) throw Base::Exception("Axis reference must be edge of a feature"); std::vector<std::string> subStrings = Axis.getSubValues(); if (subStrings.empty() || subStrings[0].empty()) throw Base::Exception("No axis reference specified"); gp_Pnt axbase; gp_Dir axdir; if (refObject->getTypeId().isDerivedFrom(Part::Part2DObject::getClassTypeId())) { Part::Part2DObject* refSketch = static_cast<Part::Part2DObject*>(refObject); Base::Axis axis; if (subStrings[0] == "H_Axis") axis = refSketch->getAxis(Part::Part2DObject::H_Axis); else if (subStrings[0] == "V_Axis") axis = refSketch->getAxis(Part::Part2DObject::V_Axis); else if (subStrings[0] == "N_Axis") axis = refSketch->getAxis(Part::Part2DObject::N_Axis); else if (subStrings[0].size() > 4 && subStrings[0].substr(0,4) == "Axis") { int AxId = std::atoi(subStrings[0].substr(4,4000).c_str()); if (AxId >= 0 && AxId < refSketch->getAxisCount()) axis = refSketch->getAxis(AxId); } axis *= refSketch->Placement.getValue(); axbase = gp_Pnt(axis.getBase().x, axis.getBase().y, axis.getBase().z); axdir = gp_Dir(axis.getDirection().x, axis.getDirection().y, axis.getDirection().z); } else { Part::Feature* refFeature = static_cast<Part::Feature*>(refObject); Part::TopoShape refShape = refFeature->Shape.getShape(); TopoDS_Shape ref = refShape.getSubShape(subStrings[0].c_str()); if (ref.ShapeType() == TopAbs_EDGE) { TopoDS_Edge refEdge = TopoDS::Edge(ref); if (refEdge.IsNull()) throw Base::Exception("Failed to extract axis edge"); BRepAdaptor_Curve adapt(refEdge); if (adapt.GetType() != GeomAbs_Line) throw Base::Exception("Axis edge must be a straight line"); axbase = adapt.Value(adapt.FirstParameter()); axdir = adapt.Line().Direction(); } else { throw Base::Exception("Axis reference must be an edge"); } } TopLoc_Location invObjLoc = this->getLocation().Inverted(); axbase.Transform(invObjLoc.Transformation()); axdir.Transform(invObjLoc.Transformation()); gp_Ax2 axis(axbase, axdir); if (reversed) axis.SetDirection(axis.Direction().Reversed()); // Note: The original feature is NOT included in the list of transformations! Therefore // we start with occurrence number 1, not number 0 std::list<gp_Trsf> transformations; gp_Trsf trans; transformations.push_back(trans); // identity transformation for (int i = 1; i < occurrences; i++) { trans.SetRotation(axis.Axis(), i * offset); transformations.push_back(trans); } return transformations; }
App::DocumentObjectExecReturn *Groove::execute(void) { // Validate parameters double angle = Angle.getValue(); if (angle < Precision::Confusion()) return new App::DocumentObjectExecReturn("Angle of groove too small"); if (angle > 360.0) return new App::DocumentObjectExecReturn("Angle of groove too large"); angle = Base::toRadians<double>(angle); // Reverse angle if selected if (Reversed.getValue() && !Midplane.getValue()) angle *= (-1.0); Part::Part2DObject* sketch = 0; std::vector<TopoDS_Wire> wires; TopoDS_Shape support; try { sketch = getVerifiedSketch(); wires = getSketchWires(); support = getSupportShape(); } catch (const Base::Exception& e) { return new App::DocumentObjectExecReturn(e.what()); } // get the Sketch plane Base::Placement SketchPlm = sketch->Placement.getValue(); // get reference axis App::DocumentObject *pcReferenceAxis = ReferenceAxis.getValue(); const std::vector<std::string> &subReferenceAxis = ReferenceAxis.getSubValues(); if (pcReferenceAxis && pcReferenceAxis == sketch) { bool hasValidAxis=false; Base::Axis axis; if (subReferenceAxis[0] == "V_Axis") { hasValidAxis = true; axis = sketch->getAxis(Part::Part2DObject::V_Axis); } else if (subReferenceAxis[0] == "H_Axis") { hasValidAxis = true; axis = sketch->getAxis(Part::Part2DObject::H_Axis); } else if (subReferenceAxis[0].size() > 4 && subReferenceAxis[0].substr(0,4) == "Axis") { int AxId = std::atoi(subReferenceAxis[0].substr(4,4000).c_str()); if (AxId >= 0 && AxId < sketch->getAxisCount()) { hasValidAxis = true; axis = sketch->getAxis(AxId); } } if (hasValidAxis) { axis *= SketchPlm; Base::Vector3d base=axis.getBase(); Base::Vector3d dir=axis.getDirection(); Base.setValue(base.x,base.y,base.z); Axis.setValue(dir.x,dir.y,dir.z); } } // get revolve axis Base::Vector3f b = Base.getValue(); gp_Pnt pnt(b.x,b.y,b.z); Base::Vector3f v = Axis.getValue(); gp_Dir dir(v.x,v.y,v.z); try { TopoDS_Shape sketchshape = makeFace(wires); if (sketchshape.IsNull()) return new App::DocumentObjectExecReturn("Creating a face from sketch failed"); // Rotate the face by half the angle to get Groove symmetric to sketch plane if (Midplane.getValue()) { gp_Trsf mov; mov.SetRotation(gp_Ax1(pnt, dir), Base::toRadians<double>(Angle.getValue()) * (-1.0) / 2.0); TopLoc_Location loc(mov); sketchshape.Move(loc); } this->positionBySketch(); TopLoc_Location invObjLoc = this->getLocation().Inverted(); pnt.Transform(invObjLoc.Transformation()); dir.Transform(invObjLoc.Transformation()); support.Move(invObjLoc); sketchshape.Move(invObjLoc); // Check distance between sketchshape and axis - to avoid failures and crashes if (checkLineCrossesFace(gp_Lin(pnt, dir), TopoDS::Face(sketchshape))) return new App::DocumentObjectExecReturn("Revolve axis intersects the sketch"); // revolve the face to a solid BRepPrimAPI_MakeRevol RevolMaker(sketchshape, gp_Ax1(pnt, dir), angle); if (RevolMaker.IsDone()) { TopoDS_Shape result = RevolMaker.Shape(); // set the subtractive shape property for later usage in e.g. pattern this->SubShape.setValue(result); // cut out groove to get one result object BRepAlgoAPI_Cut mkCut(support, result); // Let's check if the fusion has been successful if (!mkCut.IsDone()) throw Base::Exception("Cut out of support failed"); // we have to get the solids (fuse sometimes creates compounds) TopoDS_Shape solRes = this->getSolid(mkCut.Shape()); if (solRes.IsNull()) return new App::DocumentObjectExecReturn("Resulting shape is not a solid"); this->Shape.setValue(solRes); } else return new App::DocumentObjectExecReturn("Could not revolve the sketch!"); return App::DocumentObject::StdReturn; } catch (Standard_Failure) { Handle_Standard_Failure e = Standard_Failure::Caught(); if (std::string(e->GetMessageString()) == "TopoDS::Face") return new App::DocumentObjectExecReturn("Could not create face from sketch.\n" "Intersecting sketch entities or multiple faces in a sketch are not allowed."); else return new App::DocumentObjectExecReturn(e->GetMessageString()); } catch (Base::Exception& e) { return new App::DocumentObjectExecReturn(e.what()); } }
const std::list<gp_Trsf> LinearPattern::getTransformations(const std::vector<App::DocumentObject*>) { double distance = Length.getValue(); if (distance < Precision::Confusion()) throw Base::Exception("Pattern length too small"); int occurrences = Occurrences.getValue(); if (occurrences < 2) throw Base::Exception("At least two occurrences required"); bool reversed = Reversed.getValue(); double offset = distance / (occurrences - 1); App::DocumentObject* refObject = Direction.getValue(); if (refObject == NULL) throw Base::Exception("No direction reference specified"); std::vector<std::string> subStrings = Direction.getSubValues(); if (subStrings.empty()) throw Base::Exception("No direction reference specified"); gp_Dir dir; if (refObject->getTypeId().isDerivedFrom(Part::Part2DObject::getClassTypeId())) { Part::Part2DObject* refSketch = static_cast<Part::Part2DObject*>(refObject); Base::Axis axis; if (subStrings[0] == "H_Axis") axis = refSketch->getAxis(Part::Part2DObject::H_Axis); else if (subStrings[0] == "V_Axis") axis = refSketch->getAxis(Part::Part2DObject::V_Axis); else if (subStrings[0] == "N_Axis") axis = refSketch->getAxis(Part::Part2DObject::N_Axis); else if (subStrings[0].size() > 4 && subStrings[0].substr(0,4) == "Axis") { int AxId = std::atoi(subStrings[0].substr(4,4000).c_str()); if (AxId >= 0 && AxId < refSketch->getAxisCount()) axis = refSketch->getAxis(AxId); } axis *= refSketch->Placement.getValue(); dir = gp_Dir(axis.getDirection().x, axis.getDirection().y, axis.getDirection().z); } else if (refObject->getTypeId().isDerivedFrom(PartDesign::Plane::getClassTypeId())) { PartDesign::Plane* plane = static_cast<PartDesign::Plane*>(refObject); Base::Vector3d d = plane->getNormal(); dir = gp_Dir(d.x, d.y, d.z); } else if (refObject->getTypeId().isDerivedFrom(PartDesign::Line::getClassTypeId())) { PartDesign::Line* line = static_cast<PartDesign::Line*>(refObject); Base::Vector3d d = line->getDirection(); dir = gp_Dir(d.x, d.y, d.z); } else if (refObject->getTypeId().isDerivedFrom(App::Line::getClassTypeId())) { App::Line* line = static_cast<App::Line*>(refObject); Base::Rotation rot = line->Placement.getValue().getRotation(); Base::Vector3d d(1,0,0); rot.multVec(d, d); dir = gp_Dir(d.x, d.y, d.z); } else if (refObject->getTypeId().isDerivedFrom(Part::Feature::getClassTypeId())) { if (subStrings[0].empty()) throw Base::Exception("No direction reference specified"); Part::Feature* refFeature = static_cast<Part::Feature*>(refObject); Part::TopoShape refShape = refFeature->Shape.getShape(); TopoDS_Shape ref = refShape.getSubShape(subStrings[0].c_str()); if (ref.ShapeType() == TopAbs_FACE) { TopoDS_Face refFace = TopoDS::Face(ref); if (refFace.IsNull()) throw Base::Exception("Failed to extract direction plane"); BRepAdaptor_Surface adapt(refFace); if (adapt.GetType() != GeomAbs_Plane) throw Base::Exception("Direction face must be planar"); dir = adapt.Plane().Axis().Direction(); } else if (ref.ShapeType() == TopAbs_EDGE) { TopoDS_Edge refEdge = TopoDS::Edge(ref); if (refEdge.IsNull()) throw Base::Exception("Failed to extract direction edge"); BRepAdaptor_Curve adapt(refEdge); if (adapt.GetType() != GeomAbs_Line) throw Base::Exception("Direction edge must be a straight line"); dir = adapt.Line().Direction(); } else { throw Base::Exception("Direction reference must be edge or face"); } } else { throw Base::Exception("Direction reference must be edge/face of a feature or a datum line/plane"); } TopLoc_Location invObjLoc = this->getLocation().Inverted(); dir.Transform(invObjLoc.Transformation()); gp_Vec direction(dir.X(), dir.Y(), dir.Z()); if (reversed) direction.Reverse(); // Note: The original feature is NOT included in the list of transformations! Therefore // we start with occurrence number 1, not number 0 std::list<gp_Trsf> transformations; gp_Trsf trans; transformations.push_back(trans); // identity transformation for (int i = 1; i < occurrences; i++) { trans.SetTranslation(direction * i * offset); transformations.push_back(trans); } return transformations; }