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76df39e99d04eda196828fe657321738cfcf779e
create/src/Mod/Part/App/TopoShape.h
Zheng, Lei 76df39e99d Toponaming/Part: transfer in getSubTopoShape
2024-02-13 10:01:17 -05:00

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/***************************************************************************
* Copyright (c) 2002 Jürgen Riegel <juergen.riegel@web.de> *
* *
* This file is part of the FreeCAD CAx development system. *
* *
* This library is free software; you can redistribute it and/or *
* modify it under the terms of the GNU Library General Public *
* License as published by the Free Software Foundation; either *
* version 2 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 Library General Public License for more details. *
* *
* You should have received a copy of the GNU Library General Public *
* License along with this library; see the file COPYING.LIB. If not, *
* write to the Free Software Foundation, Inc., 59 Temple Place, *
* Suite 330, Boston, MA 02111-1307, USA *
* *
***************************************************************************/
#ifndef PART_TOPOSHAPE_H
#define PART_TOPOSHAPE_H
#include <iosfwd>
#include <list>
#include <App/ComplexGeoData.h>
#include <Base/Exception.h>
#include <Mod/Part/PartGlobal.h>
#include <TopoDS_Compound.hxx>
#include <TopoDS_Wire.hxx>
#include <TopTools_ListOfShape.hxx>
#include <BRepBuilderAPI_MakeShape.hxx>
#include <BRepBuilderAPI_Sewing.hxx>
#include <BRepOffsetAPI_ThruSections.hxx>
#include <BRepOffsetAPI_MakePipeShell.hxx>
#include <BRepFeat_MakePrism.hxx>
#include <BRepPrimAPI_MakeHalfSpace.hxx>
#include <BRepTools_History.hxx>
#include <BRepTools_ReShape.hxx>
#include <ShapeFix_Root.hxx>
class gp_Ax1;
class gp_Ax2;
class gp_Pln;
class gp_Vec;
namespace App
{
class Color;
}
namespace Part
{
struct ShapeHasher;
class TopoShape;
class TopoShapeCache;
typedef std::unordered_map<TopoShape, TopoShape, ShapeHasher, ShapeHasher> TopoShapeMap;
/* A special sub-class to indicate null shapes
*/
class PartExport NullShapeException: public Base::ValueError
{
public:
/// Construction
NullShapeException();
explicit NullShapeException(const char* sMessage);
explicit NullShapeException(const std::string& sMessage);
/// Destruction
~NullShapeException() noexcept override = default;
};
/* A special sub-class to indicate boolean failures
*/
class PartExport BooleanException: public Base::CADKernelError
{
public:
/// Construction
BooleanException();
explicit BooleanException(const char* sMessage);
explicit BooleanException(const std::string& sMessage);
/// Destruction
~BooleanException() noexcept override = default;
};
class PartExport ShapeSegment: public Data::Segment
{
TYPESYSTEM_HEADER_WITH_OVERRIDE();
public:
explicit ShapeSegment(const TopoDS_Shape& ShapeIn)
: Shape(ShapeIn)
{}
ShapeSegment() = default;
std::string getName() const override;
TopoDS_Shape Shape;
};
/// When tracing an element's history, one can either stop the trace when the element's type
/// changes, or continue tracing the history through the change. This enumeration replaces a boolean
/// parameter in the original Toponaming branch by realthunder.
enum class HistoryTraceType
{
stopOnTypeChange,
followTypeChange
};
/// Behavior of refines when a problem arises; either leave the shape untouched or throw an exception.
/// This replaces a boolean parameter in the original Toponaming branch by realthunder..
enum class RefineFail
{
shapeUntouched,
throwException
};
/** The representation for a CAD Shape
*/
class PartExport TopoShape: public Data::ComplexGeoData
{
TYPESYSTEM_HEADER_WITH_OVERRIDE();
public:
TopoShape(long Tag=0,
App::StringHasherRef hasher=App::StringHasherRef(),
const TopoDS_Shape &shape=TopoDS_Shape()); // Cannot be made explicit
TopoShape(const TopoDS_Shape&,
long Tag=0,
App::StringHasherRef hasher=App::StringHasherRef()); // Cannot be made explicit
TopoShape(const TopoShape&);
~TopoShape() override;
void setShape(const TopoDS_Shape& shape, bool resetElementMap = true);
inline void setShape(const TopoShape& shape)
{
*this = shape;
}
inline const TopoDS_Shape& getShape() const
{
return this->_Shape;
}
void operator=(const TopoShape&);
/** @name Placement control */
//@{
/// set the transformation of the CasCade Shape
void setTransform(const Base::Matrix4D& rclTrf) override;
/// set the transformation of the CasCade Shape
void setShapePlacement(const Base::Placement& rclTrf);
/// get the transformation of the CasCade Shape
Base::Placement getShapePlacement() const;
/// get the transformation of the CasCade Shape
Base::Matrix4D getTransform() const override;
/// Bound box from the CasCade shape
Base::BoundBox3d getBoundBox() const override;
bool getCenterOfGravity(Base::Vector3d& center) const override;
static void convertTogpTrsf(const Base::Matrix4D& mtrx, gp_Trsf& trsf);
static void convertToMatrix(const gp_Trsf& trsf, Base::Matrix4D& mtrx);
static Base::Matrix4D convert(const gp_Trsf& trsf);
static gp_Trsf convert(const Base::Matrix4D& mtrx);
//@}
/** @name Getting basic geometric entities */
//@{
private:
/** Get lines from sub-shape */
void getLinesFromSubShape(const TopoDS_Shape& shape,
std::vector<Base::Vector3d>& vertices,
std::vector<Line>& lines) const;
void getFacesFromDomains(const std::vector<Domain>& domains,
std::vector<Base::Vector3d>& vertices,
std::vector<Facet>& faces) const;
public:
/// Get the standard accuracy to be used with getPoints, getLines or getFaces
double getAccuracy() const override;
/** Get points from object with given accuracy */
void getPoints(std::vector<Base::Vector3d>& Points,
std::vector<Base::Vector3d>& Normals,
double Accuracy,
uint16_t flags = 0) const override;
/** Get lines from object with given accuracy */
void getLines(std::vector<Base::Vector3d>& Points,
std::vector<Line>& lines,
double Accuracy,
uint16_t flags = 0) const override;
void getFaces(std::vector<Base::Vector3d>& Points,
std::vector<Facet>& faces,
double Accuracy,
uint16_t flags = 0) const override;
void setFaces(const std::vector<Base::Vector3d>& Points,
const std::vector<Facet>& faces,
double tolerance = 1.0e-06);
void getDomains(std::vector<Domain>&) const;
//@}
/** @name Subelement management */
//@{
/// Unlike \ref getTypeAndIndex() this function only handles the supported
/// element types.
static std::pair<std::string, unsigned long> getElementTypeAndIndex(const char* Name);
/** Sub type list
* List of different subelement types
* it is NOT a list of the subelements itself
*/
std::vector<const char*> getElementTypes() const override;
unsigned long countSubElements(const char* Type) const override;
/// get the subelement by type and number
Data::Segment* getSubElement(const char* Type, unsigned long) const override;
/** Get lines from segment */
void getLinesFromSubElement(const Data::Segment*,
std::vector<Base::Vector3d>& Points,
std::vector<Line>& lines) const override;
/** Get faces from segment */
void getFacesFromSubElement(const Data::Segment*,
std::vector<Base::Vector3d>& Points,
std::vector<Base::Vector3d>& PointNormals,
std::vector<Facet>& faces) const override;
//@}
/// get the Topo"sub"Shape with the given name
TopoDS_Shape getSubShape(const char* Type, bool silent = false) const;
TopoDS_Shape getSubShape(TopAbs_ShapeEnum type, int idx, bool silent = false) const;
TopoShape getSubTopoShape(const char* Type, bool silent = false) const;
TopoShape getSubTopoShape(TopAbs_ShapeEnum type, int idx, bool silent = false) const;
std::vector<TopoShape> getSubTopoShapes(TopAbs_ShapeEnum type = TopAbs_SHAPE) const;
std::vector<TopoDS_Shape> getSubShapes(TopAbs_ShapeEnum type = TopAbs_SHAPE) const;
unsigned long countSubShapes(const char* Type) const;
unsigned long countSubShapes(TopAbs_ShapeEnum type) const;
bool hasSubShape(const char* Type) const;
bool hasSubShape(TopAbs_ShapeEnum type) const;
/// get the Topo"sub"Shape with the given name
PyObject* getPySubShape(const char* Type, bool silent = false) const;
PyObject* getPyObject() override;
void setPyObject(PyObject*) override;
/** @name Save/restore */
//@{
void Save(Base::Writer& writer) const override;
void Restore(Base::XMLReader& reader) override;
void SaveDocFile(Base::Writer& writer) const override;
void RestoreDocFile(Base::Reader& reader) override;
unsigned int getMemSize() const override;
//@}
/** @name Input/Output */
//@{
void read(const char* FileName);
void write(const char* FileName) const;
void dump(std::ostream& out) const;
void importIges(const char* FileName);
void importStep(const char* FileName);
void importBrep(const char* FileName);
void importBrep(std::istream&, int indicator = 1);
void importBinary(std::istream&);
void exportIges(const char* FileName) const;
void exportStep(const char* FileName) const;
void exportBrep(const char* FileName) const;
void exportBrep(std::ostream&) const;
void exportBinary(std::ostream&) const;
void exportStl(const char* FileName, double deflection) const;
void exportFaceSet(double, double, const std::vector<App::Color>&, std::ostream&) const;
void exportLineSet(std::ostream&) const;
//@}
/** @name Query*/
//@{
bool isNull() const;
bool isValid() const;
bool analyze(bool runBopCheck, std::ostream&) const;
bool isClosed() const;
bool isCoplanar(const TopoShape& other, double tol = -1) const;
bool findPlane(gp_Pln& plane, double tol = -1) const;
/// Returns true if the expansion of the shape is infinite, false otherwise
bool isInfinite() const;
/// Checks whether the shape is a planar face
bool isPlanar(double tol = 1.0e-7) const;
//@}
/** @name Boolean operation*/
//@{
TopoDS_Shape cut(TopoDS_Shape) const;
TopoDS_Shape cut(const std::vector<TopoDS_Shape>&, Standard_Real tolerance = 0.0) const;
TopoDS_Shape common(TopoDS_Shape) const;
TopoDS_Shape common(const std::vector<TopoDS_Shape>&, Standard_Real tolerance = 0.0) const;
TopoDS_Shape fuse(TopoDS_Shape) const;
TopoDS_Shape fuse(const std::vector<TopoDS_Shape>&, Standard_Real tolerance = 0.0) const;
TopoDS_Shape oldFuse(TopoDS_Shape) const;
TopoDS_Shape section(TopoDS_Shape, Standard_Boolean approximate = Standard_False) const;
TopoDS_Shape section(const std::vector<TopoDS_Shape>&,
Standard_Real tolerance = 0.0,
Standard_Boolean approximate = Standard_False) const;
std::list<TopoDS_Wire> slice(const Base::Vector3d&, double) const;
TopoDS_Compound slices(const Base::Vector3d&, const std::vector<double>&) const;
/**
* @brief generalFuse: run general fuse algorithm between this and shapes
* supplied as sOthers
*
* @param sOthers (input): list of shapes to run the algorithm between
* (this is automatically added to the list)
*
* @param tolerance (input): fuzzy value (pass zero to disable fuzzyness
* and use shape tolerances only)
*
* @param mapInOut (output): pointer to list of lists, to write the info
* which shapes in result came from which argument shape. The length of
* list is equal to length of sOthers+1. First element is a list of shapes
* that came from shape of this, and the rest are those that come from
* shapes in sOthers. If the info is not needed, nullptr can be passed.
*
* @return compound of slices that can be combined to reproduce results of
* cut, fuse, common. The shapes share edges and faces where they touch.
* For example, if input shapes are two intersecting spheres, GFA returns
* three solids: two cuts and common.
*/
TopoDS_Shape generalFuse(const std::vector<TopoDS_Shape>& sOthers,
Standard_Real tolerance,
std::vector<TopTools_ListOfShape>* mapInOut = nullptr) const;
//@}
/** Sweeping */
//@{
TopoDS_Shape makePipe(const TopoDS_Shape& profile) const;
TopoDS_Shape makePipeShell(const TopTools_ListOfShape& profiles,
const Standard_Boolean make_solid,
const Standard_Boolean isFrenet = Standard_False,
int transition = 0) const;
TopoDS_Shape makePrism(const gp_Vec&) const;
/// revolve shape. Note: isSolid is deprecated (instead, use some Part::FaceMaker to make a
/// face, first).
TopoDS_Shape revolve(const gp_Ax1&, double d, Standard_Boolean isSolid = Standard_False) const;
TopoDS_Shape makeSweep(const TopoDS_Shape& profile, double, int) const;
TopoDS_Shape makeTube(double radius, double tol, int cont, int maxdeg, int maxsegm) const;
TopoDS_Shape makeTorus(Standard_Real radius1,
Standard_Real radius2,
Standard_Real angle1,
Standard_Real angle2,
Standard_Real angle3,
Standard_Boolean isSolid = Standard_True) const;
TopoDS_Shape makeHelix(Standard_Real pitch,
Standard_Real height,
Standard_Real radius,
Standard_Real angle = 0,
Standard_Boolean left = Standard_False,
Standard_Boolean style = Standard_False) const;
TopoDS_Shape makeLongHelix(Standard_Real pitch,
Standard_Real height,
Standard_Real radius,
Standard_Real angle = 0,
Standard_Boolean left = Standard_False) const;
TopoDS_Shape makeSpiralHelix(Standard_Real radiusbottom,
Standard_Real radiustop,
Standard_Real height,
Standard_Real nbturns = 1,
Standard_Real breakperiod = 1,
Standard_Boolean left = Standard_False) const;
TopoDS_Shape makeThread(Standard_Real pitch,
Standard_Real depth,
Standard_Real height,
Standard_Real radius) const;
TopoDS_Shape makeLoft(const TopTools_ListOfShape& profiles,
Standard_Boolean isSolid,
Standard_Boolean isRuled,
Standard_Boolean isClosed = Standard_False,
Standard_Integer maxDegree = 5) const;
TopoDS_Shape makeOffsetShape(double offset,
double tol,
bool intersection = false,
bool selfInter = false,
short offsetMode = 0,
short join = 0,
bool fill = false) const;
TopoDS_Shape makeOffset2D(double offset,
short joinType = 0,
bool fill = false,
bool allowOpenResult = false,
bool intersection = false) const;
TopoDS_Shape makeThickSolid(const TopTools_ListOfShape& remFace,
double offset,
double tol,
bool intersection = false,
bool selfInter = false,
short offsetMode = 0,
short join = 0) const;
//@}
/** @name Manipulation*/
//@{
void transformGeometry(const Base::Matrix4D& rclMat) override;
TopoDS_Shape transformGShape(const Base::Matrix4D&, bool copy = false) const;
bool transformShape(const Base::Matrix4D&, bool copy, bool checkScale = false);
TopoDS_Shape mirror(const gp_Ax2&) const;
TopoDS_Shape toNurbs() const;
TopoDS_Shape replaceShape(const std::vector<std::pair<TopoDS_Shape, TopoDS_Shape>>& s) const;
TopoDS_Shape removeShape(const std::vector<TopoDS_Shape>& s) const;
void sewShape(double tolerance = 1.0e-06);
bool fix();
bool fix(double, double, double);
bool fixSolidOrientation();
bool removeInternalWires(double);
TopoDS_Shape removeSplitter() const;
TopoDS_Shape defeaturing(const std::vector<TopoDS_Shape>& s) const;
TopoDS_Shape makeShell(const TopoDS_Shape&) const;
//@}
/// Wire re-orientation when calling splitWires()
enum SplitWireReorient {
/// Keep original reorientation
NoReorient,
/// Make outer wire forward, and inner wires reversed
Reorient,
/// Make both outer and inner wires forward
ReorientForward,
/// Make both outer and inner wires reversed
ReorientReversed,
};
/** Return the outer and inner wires of a face
*
* @param inner: optional output of inner wires
* @param reorient: wire reorientation, see SplitWireReorient
*
* @return Return the outer wire
*/
TopoShape splitWires(std::vector<TopoShape> *inner = nullptr,
SplitWireReorient reorient = Reorient) const;
/** @name Element name mapping aware shape maker
*
* To be complete in next batch of patches
*/
//@{
TopoShape&
makeCompound(const std::vector<TopoShape>& shapes, const char* op = nullptr, bool force = true);
TopoShape&
makeWires(const TopoShape& shape, const char* op = nullptr, bool fix = false, double tol = 0.0);
TopoShape makeWires(const char* op = nullptr, bool fix = false, double tol = 0.0) const
{
return TopoShape().makeWires(*this, op, fix, tol);
}
TopoShape& makeFace(const std::vector<TopoShape>& shapes,
const char* op = nullptr,
const char* maker = nullptr);
TopoShape&
makeFace(const TopoShape& shape, const char* op = nullptr, const char* maker = nullptr);
TopoShape makeFace(const char* op = nullptr, const char* maker = nullptr) const
{
return TopoShape().makeFace(*this, op, maker);
}
bool _makeTransform(const TopoShape& shape,
const Base::Matrix4D& mat,
const char* op = nullptr,
bool checkScale = false,
bool copy = false);
TopoShape& makeTransform(const TopoShape& shape,
const Base::Matrix4D& mat,
const char* op = nullptr,
bool checkScale = false,
bool copy = false)
{
_makeTransform(shape, mat, op, checkScale, copy);
return *this;
}
TopoShape makeTransform(const Base::Matrix4D& mat,
const char* op = nullptr,
bool checkScale = false,
bool copy = false) const
{
return TopoShape().makeTransform(*this, mat, op, checkScale, copy);
}
TopoShape& makeTransform(const TopoShape& shape,
const gp_Trsf& trsf,
const char* op = nullptr,
bool copy = false);
TopoShape makeTransform(const gp_Trsf& trsf, const char* op = nullptr, bool copy = false) const
{
return TopoShape().makeTransform(*this, trsf, op, copy);
}
/** Move the shape to a new location
*
* @param loc: location
*
* The location is applied in addition to any current transformation of the shape
*/
void move(const TopLoc_Location& loc)
{
_Shape.Move(loc);
}
/** Return a new shape that is moved to a new location
*
* @param loc: location
*
* @return Return a shallow copy of the shape moved to the new location
* that is applied in addition to any current transformation of the
* shape
*/
TopoShape moved(const TopLoc_Location& loc) const
{
TopoShape ret(*this);
ret._Shape.Move(loc);
return ret;
}
/** Move and/or rotate the shape
*
* @param trsf: OCCT transformation (must not have scale)
*
* The transformation is applied in addition to any current transformation
* of the shape
*/
void move(const gp_Trsf& trsf)
{
move(_Shape, trsf);
}
/** Return a new transformed shape
*
* @param trsf: OCCT transformation (must not have scale)
*
* @return Return a shallow copy of the shape transformed to the new
* location that is applied in addition to any current
* transformation of the shape
*/
TopoShape moved(const gp_Trsf& trsf) const
{
return moved(_Shape, trsf);
}
/** Set a new location for the shape
*
* @param loc: shape location
*
* Any previous location of the shape is discarded before applying the
* input location
*/
void locate(const TopLoc_Location& loc)
{
_Shape.Location(loc);
}
/** ReturnSet a new location for the shape
*
* @param loc: shape location
*
* @return Return a shallow copy the shape in a new location. Any previous
* location of the shape is discarded before applying the input
* location
*/
TopoShape located(const TopLoc_Location& loc) const
{
TopoShape ret(*this);
ret._Shape.Location(loc);
return ret;
}
/** Set a new transformation for the shape
*
* @param trsf: OCCT transformation (must not have scale)
*
* Any previous transformation of the shape is discarded before applying
* the input transformation
*/
void locate(const gp_Trsf& trsf)
{
located(_Shape, trsf);
}
/** Set a new transformation for the shape
*
* @param trsf: OCCT transformation (must not have scale)
*
* Any previous transformation of the shape is discarded before applying
* the input transformation.
*/
TopoShape located(const gp_Trsf& trsf) const
{
return located(_Shape, trsf);
}
static TopoDS_Shape& move(TopoDS_Shape& tds, const TopLoc_Location& loc);
static TopoDS_Shape moved(const TopoDS_Shape& tds, const TopLoc_Location& loc);
static TopoDS_Shape& move(TopoDS_Shape& tds, const gp_Trsf& transfer);
static TopoDS_Shape moved(const TopoDS_Shape& tds, const gp_Trsf& transfer);
static TopoDS_Shape& locate(TopoDS_Shape& tds, const TopLoc_Location& loc);
static TopoDS_Shape located(const TopoDS_Shape& tds, const TopLoc_Location& loc);
static TopoDS_Shape& locate(TopoDS_Shape& tds, const gp_Trsf& transfer);
static TopoDS_Shape located(const TopoDS_Shape& tds, const gp_Trsf& transfer);
TopoShape& makeGTransform(const TopoShape& shape,
const Base::Matrix4D& mat,
const char* op = nullptr,
bool copy = false);
TopoShape
makeGTransform(const Base::Matrix4D& mat, const char* op = nullptr, bool copy = false) const
{
return TopoShape().makeGTransform(*this, mat, op, copy);
}
/** Refine the input shape by merging faces/edges that share the same geometry
*
* @param source: input shape
* @param op: optional string to be encoded into topo naming for indicating
* the operation
* @param no_fail: if throwException, throw exception if failed to refine. Or else,
* if shapeUntouched the shape remains untouched if failed.
*
* @return The original content of this TopoShape is discarded and replaced
* with the refined shape. The function returns the TopoShape
* itself as a self reference so that multiple operations can be
* carried out for the same shape in the same line of code.
*/
TopoShape& makeElementRefine(const TopoShape& source,
const char* op = nullptr,
RefineFail no_fail = RefineFail::throwException);
/** Refine the input shape by merging faces/edges that share the same geometry
*
* @param source: input shape
* @param op: optional string to be encoded into topo naming for indicating
* the operation
* @param no_fail: if throwException, throw exception if failed to refine. Or else,
* if shapeUntouched the shape remains untouched if failed.
*
* @return Return a refined shape. The shape itself is not modified
*/
TopoShape makeElementRefine(const char* op = nullptr,
RefineFail no_fail = RefineFail::throwException) const
{
return TopoShape(Tag, Hasher).makeElementRefine(*this, op, no_fail);
}
TopoShape& makeRefine(const TopoShape& shape,
const char* op = nullptr,
RefineFail no_fail = RefineFail::throwException);
TopoShape makeRefine(const char* op = nullptr,
RefineFail no_fail = RefineFail::throwException) const
{
return TopoShape().makeRefine(*this, op, no_fail);
}
//@}
static TopAbs_ShapeEnum shapeType(const char* type, bool silent = false);
static TopAbs_ShapeEnum shapeType(char type, bool silent = false);
TopAbs_ShapeEnum shapeType(bool silent = false) const;
static const std::string& shapeName(TopAbs_ShapeEnum type, bool silent = false);
const std::string& shapeName(bool silent = false) const;
static std::pair<TopAbs_ShapeEnum, int> shapeTypeAndIndex(const char* name);
Data::MappedName setElementComboName(const Data::IndexedName & element,
const std::vector<Data::MappedName> &names,
const char *marker=nullptr,
const char *op=nullptr,
const Data::ElementIDRefs *sids=nullptr);
/** @name sub shape cached functions
*
* Mapped element names introduces some overhead when getting sub shapes
* from a shape. These functions use internal caches for sub-shape maps to
* improve performance.
*/
//@{
void initCache(int reset = 0) const;
int findShape(const TopoDS_Shape& subshape) const;
TopoDS_Shape findShape(const char* name) const;
TopoDS_Shape findShape(TopAbs_ShapeEnum type, int idx) const;
int findAncestor(const TopoDS_Shape& subshape, TopAbs_ShapeEnum type) const;
TopoDS_Shape findAncestorShape(const TopoDS_Shape& subshape, TopAbs_ShapeEnum type) const;
std::vector<int> findAncestors(const TopoDS_Shape& subshape, TopAbs_ShapeEnum type) const;
std::vector<TopoDS_Shape> findAncestorsShapes(const TopoDS_Shape& subshape,
TopAbs_ShapeEnum type) const;
/** Search sub shape
*
* unlike findShape(), the input shape does not have to be an actual
* sub-shape of this shape. The sub-shape is searched by shape geometry
*
* @param subshape: a sub shape to search
* @param names: optional output of found sub shape indexed based name
* @param checkGeometry: whether to compare shape geometry
* @param tol: tolerance to check coincident vertices
* @param atol: tolerance to check for same angles
*/
// TODO: Implement this method and its tests later in Toponaming Phase 3.
// std::vector<TopoShape> searchSubShape(const TopoShape &subshape,
// std::vector<std::string> *names=nullptr,
// bool checkGeometry=true,
// double tol=1e-7, double atol=1e-12) const;
//@}
void copyElementMap(const TopoShape & topoShape, const char *op=nullptr);
bool canMapElement(const TopoShape &other) const;
void mapSubElement(const TopoShape &other,const char *op=nullptr, bool forceHasher=false);
void mapSubElement(const std::vector<TopoShape> &shapes, const char *op=nullptr);
void mapSubElementsTo(std::vector<TopoShape>& shapes, const char* op = nullptr) const;
bool hasPendingElementMap() const;
/** Helper class to return the generated and modified shape given an input shape
*
* Shape history information is extracted using OCCT APIs
* BRepBuilderAPI_MakeShape::Generated/Modified(). However, there is often
* some glitches in various derived class. So we use this class as an
* abstraction, and create various derived classes to deal with the glitches.
*/
struct PartExport Mapper {
/// Helper vector for temporary storage of both generated and modified shapes
mutable std::vector<TopoDS_Shape> _res;
virtual ~Mapper() {}
/// Return a list of shape generated from the given input shape
virtual const std::vector<TopoDS_Shape> &generated(const TopoDS_Shape &) const {
return _res;
}
/// Return a list of shape modified from the given input shape
virtual const std::vector<TopoDS_Shape> &modified(const TopoDS_Shape &) const {
return _res;
}
};
/** Core function to generate mapped element names from shape history
*
* @param shape: the new shape
* @param mapper: for mapping input shapes to generated/modified shapes
* @param sources: list of source shapes.
* @param op: optional string to be encoded into topo naming for indicating
* the operation
*
* @return The original content of this TopoShape is discarded and replaced
* with the given new shape. The function returns the TopoShape
* itself as a self reference so that multiple operations can be
* carried out for the same shape in the same line of code.
*/
TopoShape &makeShapeWithElementMap(const TopoDS_Shape &shape,
const Mapper &mapper,
const std::vector<TopoShape> &sources,
const char *op=nullptr);
/**
* When given a single shape to create a compound, two results are possible: either to simply
* return the shape as given, or to force it to be placed in a Compound.
*/
enum class SingleShapeCompoundCreationPolicy {
returnShape,
forceCompound
};
/** Make a compound shape
*
* @param shapes: input shapes
* @param op: optional string to be encoded into topo naming for indicating
* the operation
* @param policy: set behavior when only a single shape is given
*
* @return The original content of this TopoShape is discarded and replaced
* with the new shape. The function returns the TopoShape itself as
* a reference so that multiple operations can be carried out for
* the same shape in the same line of code.
*/
TopoShape& makeElementCompound(const std::vector<TopoShape>& shapes,
const char* op = nullptr,
SingleShapeCompoundCreationPolicy policy =
SingleShapeCompoundCreationPolicy::forceCompound);
enum class ConnectionPolicy
{
requireSharedVertex,
mergeWithTolerance
};
/** Make a compound of wires by connecting input edges
*
* @param shapes: input shapes. Can be any type of shape. Edges will be
* extracted for building wires.
* @param op: optional string to be encoded into topo naming for indicating
* the operation
* @param keepOrder: whether to respect the order of the input edges
* @param tol: tolerance for checking the distance of two vertex to decide
* if two edges are connected
* @param shared: if true, then only connect edges if they shared the same
* vertex, or else use \c tol to check for connection.
* @param output: optional output mapping from wire edges to input edge.
* Note that edges may be modified after adding to the wire,
* so the output edges may not be the same as the input
* ones.
*
* @return The function produces either a wire or a compound of wires. The
* original content of this TopoShape is discarded and replaced
* with the new shape. The function returns the TopoShape itself as
* a reference so that multiple operations can be carried out for
* the same shape in the same line of code.
*/
TopoShape& makeElementWires(const std::vector<TopoShape>& shapes,
const char* op = nullptr,
double tol = 0.0,
ConnectionPolicy policy = ConnectionPolicy::mergeWithTolerance,
TopoShapeMap* output = nullptr);
/** Make a compound of wires by connecting input edges
*
* @param shape: input shape. Can be any type of shape. Edges will be
* extracted for building wires.
* @param op: optional string to be encoded into topo naming for indicating
* the operation
* @param keepOrder: whether to respect the order of the input edges
* @param tol: tolerance for checking the distance of two vertex to decide
* if two edges are connected
* @param policy: if requireSharedVertex, then only connect edges if they shared the same
* vertex. If mergeWithTolerance use \c tol to check for connection.
* @param output: optional output mapping from wire edges to input edge.
* Note that edges may be modified after adding to the wire,
* so the output edges may not be the same as the input
* ones.
*
* @return The function produces either a wire or a compound of wires. The
* original content of this TopoShape is discarded and replaced
* with the new shape. The function returns the TopoShape itself as
* a reference so that multiple operations can be carried out for
* the same shape in the same line of code.
*/
TopoShape& makeElementWires(const TopoShape& shape,
const char* op = nullptr,
double tol = 0.0,
ConnectionPolicy policy = ConnectionPolicy::mergeWithTolerance,
TopoShapeMap* output = nullptr);
/** Make a compound of wires by connecting input edges in the given order
*
* @param shapes: input shapes. Can be any type of shape. Edges will be
* extracted for building wires.
* @param op: optional string to be encoded into topo naming for indicating
* the operation
* @param tol: tolerance for checking the distance of two vertex to decide
* if two edges are connected
* @param output: optional output mapping from wire edges to input edge.
* Note that edges may be modified after adding to the wire,
* so the output edges may not be the same as the input
* ones.
*
* @return Same as makeElementWires() but respects the order of the input edges.
* The function produces either a wire or a compound of wires. The
* original content of this TopoShape is discarded and replaced
* with the new shape. The function returns the TopoShape itself as
* a reference so that multiple operations can be carried out for
* the same shape in the same line of code.
*/
TopoShape& makeElementOrderedWires(const std::vector<TopoShape>& shapes,
const char* op = nullptr,
double tol = 0.0,
TopoShapeMap* output = nullptr);
/** Make a wire or compound of wires with the edges inside the this shape
*
* @param op: optional string to be encoded into topo naming for indicating
* the operation
* @param keepOrder: whether to respect the order of the input edges
* @param tol: tolerance for checking the distance of two vertex to decide
* if two edges are connected
* @param shared: if true, then only connect edges if they shared the same
* vertex, or else use \c tol to check for connection.
* @param output: optional output mapping from wire edges to input edge.
* Note that edges may be modified after adding to the wire,
* so the output edges may not be the same as the input
* ones.
*
*
* @return The function returns a new shape of either a single wire or a
* compound of wires. The shape itself is not modified.
*/
TopoShape makeElementWires(const char* op = nullptr,
double tol = 0.0,
ConnectionPolicy policy = ConnectionPolicy::mergeWithTolerance,
TopoShapeMap* output = nullptr) const
{
return TopoShape(0, Hasher).makeElementWires(*this, op, tol, policy, output);
}
/** Make a deep copy of the shape
*
* @param source: input shape
* @param op: optional string to be encoded into topo naming for indicating
* the operation
* @param copyGeom: whether to copy internal geometry of the shape
* @param copyMesh: whether to copy internal meshes of the shape
*
* @return The original content of this TopoShape is discarded and replaced
* with a deep copy of the input shape. The function returns the
* TopoShape itself as a self reference so that multiple operations
* can be carried out for the same shape in the same line of code.
*/
TopoShape& makeElementCopy(const TopoShape& source,
const char* op = nullptr,
bool copyGeom = true,
bool copyMesh = false);
/** Make a deep copy of the shape
*
* @param op: optional string to be encoded into topo naming for indicating
* the operation
* @param copyGeom: whether to copy internal geometry of the shape
* @param copyMesh: whether to copy internal meshes of the shape
*
* @return Return a deep copy of the shape. The shape itself is not
* modified
*/
TopoShape
makeElementCopy(const char* op = nullptr, bool copyGeom = true, bool copyMesh = false) const
{
return TopoShape(Tag, Hasher).makeElementCopy(*this, op, copyGeom, copyMesh);
}
/* Make a shell using this shape
* @param silent: whether to throw exception on failure
* @param op: optional string to be encoded into topo naming for indicating
* the operation
*
* @return The original content of this TopoShape is discarded and replaced
* with the new shape. The function returns the TopoShape itself as
* a self reference so that multiple operations can be carried out
* for the same shape in the same line of code.
*/
TopoShape& makeElementShell(bool silent = true, const char* op = nullptr);
/* Make a shell with input wires
*
* @param wires: input wires
* @param silent: whether to throw exception on failure
* @param op: optional string to be encoded into topo naming for indicating
* the operation
*
* @return The original content of this TopoShape is discarded and replaced
* with the new shape. The function returns the TopoShape itself as
* a self reference so that multiple operations can be carried out
* for the same shape in the same line of code.
*/
TopoShape& makeElementShellFromWires(const std::vector<TopoShape>& wires,
bool silent = true,
const char* op = nullptr);
/* Make a shell with input wires
*
* @param wires: input wires
* @param silent: whether to throw exception on failure
* @param op: optional string to be encoded into topo naming for indicating
* the operation
*
* @return Return the new shape. The TopoShape itself is not modified.
*/
TopoShape& makeElementShellFromWires(bool silent = true, const char* op = nullptr)
{
return makeElementShellFromWires(getSubTopoShapes(TopAbs_WIRE), silent, op);
}
TopoShape& makeElementFace(const std::vector<TopoShape>& shapes,
const char* op = nullptr,
const char* maker = nullptr,
const gp_Pln* plane = nullptr);
/** Make a planar face with the input wire or edge
*
* @param shape: input shape. Can be either edge, wire, or compound of
* those two types
* @param op: optional string to be encoded into topo naming for indicating
* the operation
* @param maker: optional type name of the face maker. If not given,
* default to "Part::FaceMakerBullseye"
* @param plane: optional plane of the face.
*
* @return The function creates a planar face. The original content of this
* TopoShape is discarded and replaced with the new shape. The
* function returns the TopoShape itself as a reference so that
* multiple operations can be carried out for the same shape in the
* same line of code.
*/
TopoShape& makeElementFace(const TopoShape& shape,
const char* op = nullptr,
const char* maker = nullptr,
const gp_Pln* plane = nullptr);
/** Make a planar face using this shape
*
* @param op: optional string to be encoded into topo naming for indicating
* the operation
* @param maker: optional type name of the face maker. If not given,
* default to "Part::FaceMakerBullseye"
* @param plane: optional plane of the face.
*
* @return The function returns a new planar face made using the wire or edge
* inside this shape. The shape itself is not modified.
*/
TopoShape makeElementFace(const char* op = nullptr,
const char* maker = nullptr,
const gp_Pln* plane = nullptr) const
{
return TopoShape(0, Hasher).makeElementFace(*this, op, maker, plane);
}
/// Filling style when making a BSpline face
enum class FillingStyle
{
/// The style with the flattest patches
Stretch,
/// A rounded style of patch with less depth than those of Curved
Coons,
/// The style with the most rounded patches
Curved,
};
struct BRepFillingParams;
/** Provides information about the continuity of a curve.
* Corresponds to OCCT type GeomAbs_Shape
*/
enum class Continuity {
/// Only geometric continuity
C0,
/** for each point on the curve, the tangent vectors 'on the right' and 'on
* the left' are collinear with the same orientation.
*/
G1,
/** Continuity of the first derivative. The 'C1' curve is also 'G1' but, in
* addition, the tangent vectors 'on the right' and 'on the left' are equal.
*/
C1,
/** For each point on the curve, the normalized normal vectors 'on the
* right' and 'on the left' are equal.
*/
G2,
/// Continuity of the second derivative.
C2,
/// Continuity of the third derivative.
C3,
/** Continuity of the N-th derivative, whatever is the value given for N
* (infinite order of continuity). Also provides information about the
* continuity of a surface.
*/
CN,
};
/** Generic shape making with mapped element name from shape history
*
* @param mkShape: OCCT shape maker.
* @param sources: list of source shapes.
* @param op: optional string to be encoded into topo naming for indicating
* the operation
*
* @return The original content of this TopoShape is discarded and replaced
* with the new shape built by the shape maker. The function
* returns the TopoShape itself as a self reference so that
* multiple operations can be carried out for the same shape in the
* same line of code.
*/
TopoShape& makeElementShape(BRepBuilderAPI_MakeShape& mkShape,
const std::vector<TopoShape>& sources,
const char* op = nullptr);
/** Generic shape making with mapped element name from shape history
*
* @param mkShape: OCCT shape maker.
* @param source: source shape.
* @param op: optional string to be encoded into topo naming for indicating
* the operation
*
* @return The original content of this TopoShape is discarded and replaced
* with the new shape built by the shape maker. The function
* returns the TopoShape itself as a self reference so that
* multiple operations can be carried out for the same shape in the
* same line of code.
*/
TopoShape& makeElementShape(BRepBuilderAPI_MakeShape& mkShape,
const TopoShape& source,
const char* op = nullptr);
/** Generic shape making with mapped element name from shape history
*
* @param mkShape: OCCT shape maker.
* @param op: optional string to be encoded into topo naming for indicating
* the operation
*
* @return Returns the new shape built by the shape maker with mappend element
* name generated using this shape as the source. The shape itself
* is not modified.
*/
TopoShape makeElementShape(BRepBuilderAPI_MakeShape& mkShape, const char* op = nullptr) const
{
return TopoShape(0, Hasher).makeElementShape(mkShape, *this, op);
}
/** Specialized shape making for BRepBuilderAPI_Sewing with mapped element name
*
* @param mkShape: OCCT shape maker.
* @param sources: list of source shapes.
* @param op: optional string to be encoded into topo naming for indicating
* the operation
*
* @return The original content of this TopoShape is discarded and replaced
* with the new shape built by the shape maker. The function
* returns the TopoShape itself as a self reference so that
* multiple operations can be carried out for the same shape in the
* same line of code.
*/
TopoShape& makeElementShape(BRepBuilderAPI_Sewing& mkShape,
const std::vector<TopoShape>& sources,
const char* op = nullptr);
/** Specialized shape making for BRepBuilderAPI_Sewing with mapped element name
*
* @param mkShape: OCCT shape maker.
* @param source: source shape.
* @param op: optional string to be encoded into topo naming for indicating
* the operation
*
* @return The original content of this TopoShape is discarded and replaced
* with the new shape built by the shape maker. The function
* returns the TopoShape itself as a self reference so that
* multiple operations can be carried out for the same shape in the
* same line of code.
*/
TopoShape& makeElementShape(BRepBuilderAPI_Sewing& mkShape,
const TopoShape& source,
const char* op = nullptr);
/** Specialized shape making for BRepBuilderAPI_Sewing with mapped element name
*
* @param mkShape: OCCT shape maker.
* @param op: optional string to be encoded into topo naming for indicating
* the operation
*
* @return Returns the new shape built by the shape maker with mappend element
* name generated using this shape as the source. The shape itself
* is not modified.
*/
TopoShape makeElementShape(BRepBuilderAPI_Sewing& mkShape, const char* op = nullptr) const
{
return TopoShape(0, Hasher).makeElementShape(mkShape, *this, op);
}
/** Specialized shape making for BRepBuilderAPI_ThruSections with mapped element name
*
* @param mkShape: OCCT shape maker.
* @param sources: list of source shapes.
* @param op: optional string to be encoded into topo naming for indicating
* the operation
*
* @return The original content of this TopoShape is discarded and replaced
* with the new shape built by the shape maker. The function
* returns the TopoShape itself as a self reference so that
* multiple operations can be carried out for the same shape in the
* same line of code.
*/
TopoShape& makeElementShape(BRepOffsetAPI_ThruSections& mkShape,
const std::vector<TopoShape>& sources,
const char* op = nullptr);
/** Specialized shape making for BRepBuilderAPI_Sewing with mapped element name
*
* @param mkShape: OCCT shape maker.
* @param source: source shape.
* @param op: optional string to be encoded into topo naming for indicating
* the operation
*
* @return The original content of this TopoShape is discarded and replaced
* with the new shape built by the shape maker. The function
* returns the TopoShape itself as a self reference so that
* multiple operations can be carried out for the same shape in the
* same line of code.
*/
TopoShape& makeElementShape(BRepOffsetAPI_ThruSections& mkShape,
const TopoShape& source,
const char* op = nullptr);
/** Specialized shape making for BRepBuilderAPI_Sewing with mapped element name
*
* @param mkShape: OCCT shape maker.
* @param op: optional string to be encoded into topo naming for indicating
* the operation
*
* @return Returns the new shape built by the shape maker with mappend element
* name generated using this shape as the source. The shape itself
* is not modified.
*/
TopoShape makeElementShape(BRepOffsetAPI_ThruSections& mkShape, const char* op = nullptr) const
{
return TopoShape(0, Hasher).makeElementShape(mkShape, *this, op);
}
/** Specialized shape making for BRepBuilderAPI_MakePipeShell with mapped element name
*
* @param mkShape: OCCT shape maker.
* @param sources: list of source shapes.
* @param op: optional string to be encoded into topo naming for indicating
* the operation
*
* @return The original content of this TopoShape is discarded and replaced
* with the new shape built by the shape maker. The function
* returns the TopoShape itself as a self reference so that
* multiple operations can be carried out for the same shape in the
* same line of code.
*/
TopoShape& makeElementShape(BRepOffsetAPI_MakePipeShell& mkShape,
const std::vector<TopoShape>& sources,
const char* op = nullptr);
/** Specialized shape making for BRepBuilderAPI_MakeHalfSpace with mapped element name
*
* @param mkShape: OCCT shape maker.
* @param source: source shape.
* @param op: optional string to be encoded into topo naming for indicating
* the operation
*
* @return The original content of this TopoShape is discarded and replaced
* with the new shape built by the shape maker. The function
* returns the TopoShape itself as a self reference so that
* multiple operations can be carried out for the same shape in the
* same line of code.
*/
TopoShape& makeElementShape(BRepPrimAPI_MakeHalfSpace& mkShape,
const TopoShape& source,
const char* op = nullptr);
/** Specialized shape making for BRepBuilderAPI_MakeHalfSpace with mapped element name
*
* @param mkShape: OCCT shape maker.
* @param op: optional string to be encoded into topo naming for indicating
* the operation
*
* @return Returns the new shape built by the shape maker with mappend element
* name generated using this shape as the source. The shape itself
* is not modified.
*/
TopoShape makeElementShape(BRepPrimAPI_MakeHalfSpace& mkShape, const char* op = nullptr) const
{
return TopoShape(0, Hasher).makeElementShape(mkShape, *this, op);
}
/** Specialized shape making for BRepBuilderAPI_MakePrism with mapped element name
*
* @param mkShape: OCCT shape maker.
* @param sources: list of source shapes.
* @param op: optional string to be encoded into topo naming for indicating
* the operation
*
* @return The original content of this TopoShape is discarded and replaced
* with the new shape built by the shape maker. The function
* returns the TopoShape itself as a self reference so that
* multiple operations can be carried out for the same shape in the
* same line of code.
*/
TopoShape& makeElementShape(BRepFeat_MakePrism& mkShape,
const std::vector<TopoShape>& sources,
const TopoShape& uptoface,
const char* op);
/** Helper class to return the generated and modified shape given an input shape
*
* Shape history information is extracted using OCCT APIs
* BRepBuilderAPI_MakeShape::Generated/Modified(). However, there is often
* some glitches in various derived class. So we use this class as an
* abstraction, and create various derived classes to deal with the glitches.
*/
friend class TopoShapeCache;
private:
// Cache storage
mutable std::shared_ptr<TopoShapeCache> _parentCache;
mutable std::shared_ptr<TopoShapeCache> _cache;
mutable TopLoc_Location _subLocation;
/** Helper class to ensure synchronization of element map and cache
*
* It exposes constant methods of OCCT TopoDS_Shape unchanged, and wraps all
* non-constant method to auto-clear the element names in the owner TopoShape
*/
class ShapeProtector: public TopoDS_Shape
{
public:
using TopoDS_Shape::TopoDS_Shape;
using TopoDS_Shape::operator=;
explicit ShapeProtector(TopoShape & owner)
: _owner(&owner)
{}
ShapeProtector(TopoShape & owner, const TopoDS_Shape & shape)
: TopoDS_Shape(shape), _owner(&owner)
{}
void Nullify()
{
if (!this->IsNull()) {
_owner->resetElementMap();
_owner->_cache.reset();
_owner->_parentCache.reset();
}
}
const TopLoc_Location& Location() const
{
// Some platforms do not support "using TopoDS_Shape::Location" here because of an
// ambiguous lookup, so implement it manually.
return TopoDS_Shape::Location();
}
void Location(const TopLoc_Location& Loc)
{
// Location does not affect element map or cache
TopoShape::locate(*dynamic_cast<TopoDS_Shape*>(this), Loc);
}
void Move(const TopLoc_Location& position)
{
// Move does not affect element map or cache
TopoShape::move(*dynamic_cast<TopoDS_Shape*>(this), position);
}
using TopoDS_Shape::Orientation;
void Orientation(const TopAbs_Orientation Orient)
{
_owner->flushElementMap();
TopoDS_Shape::Orientation(Orient);
if (_owner->_cache) {
_owner->initCache();
}
}
void Reverse()
{
_owner->flushElementMap();
TopoDS_Shape::Reverse();
if (_owner->_cache) {
_owner->initCache();
}
}
void Complement()
{
_owner->flushElementMap();
TopoDS_Shape::Complement();
if (_owner->_cache) {
_owner->initCache();
}
}
void Compose(const TopAbs_Orientation Orient)
{
_owner->flushElementMap();
TopoDS_Shape::Compose(Orient);
if (_owner->_cache) {
_owner->initCache();
}
}
void EmptyCopy()
{
_owner->flushElementMap();
TopoDS_Shape::EmptyCopy();
if (_owner->_cache) {
_owner->initCache();
}
}
void TShape(const Handle(TopoDS_TShape) & T)
{
_owner->flushElementMap();
TopoDS_Shape::TShape(T);
if (_owner->_cache) {
_owner->initCache();
}
}
TopoShape* _owner;
};
ShapeProtector _Shape;
private:
// Helper methods
static std::vector<Data::ElementMap::MappedChildElements>
createChildMap(size_t count, const std::vector<TopoShape>& shapes, const char* op);
void setupChild(Data::ElementMap::MappedChildElements& child,
TopAbs_ShapeEnum elementType,
const TopoShape& topoShape,
size_t shapeCount,
const char* op);
void mapSubElementForShape(const TopoShape& other, const char* op);
void mapSubElementTypeForShape(const TopoShape& other,
TopAbs_ShapeEnum type,
const char* op,
int count,
bool forward,
bool& warned);
void mapCompoundSubElements(const std::vector<TopoShape>& shapes, const char* op);
/** Given a set of edges, return a sorted list of connected edges
*
* @param edges: (input/output) input list of shapes. Must be of type edge.
* On return, the returned connected edges will be removed
* from this list. You can repeated call this function to find
* all wires.
* @param keepOrder: whether to respect the order of the input edges
* @param tol: tolerance for checking the distance of two vertex to decide
* if two edges are connected
* @return Return a list of ordered connected edges.
*/
static std::deque<TopoShape>
sortEdges(std::list<TopoShape>& edges, bool keepOrder = false, double tol = 0.0);
static TopoShape reverseEdge(const TopoShape& edge);
};
/** Shape mapper for generic BRepBuilderAPI_MakeShape derived class
*
* Uses BRepBuilderAPI_MakeShape::Modified/Generated() function to extract
* shape history for generating mapped element names
*/
struct PartExport MapperMaker: TopoShape::Mapper
{
BRepBuilderAPI_MakeShape& maker;
explicit MapperMaker(BRepBuilderAPI_MakeShape& maker)
: maker(maker)
{}
const std::vector<TopoDS_Shape>& modified(const TopoDS_Shape& s) const override;
const std::vector<TopoDS_Shape>& generated(const TopoDS_Shape& s) const override;
};
/** Shape mapper for BRepTools_History
*
* Uses BRepTools_History::Modified/Generated() function to extract
* shape history for generating mapped element names
*/
struct PartExport MapperHistory: TopoShape::Mapper
{
Handle(BRepTools_History) history;
explicit MapperHistory(const Handle(BRepTools_History) & history);
explicit MapperHistory(const Handle(BRepTools_ReShape) & reshape);
explicit MapperHistory(ShapeFix_Root& fix);
const std::vector<TopoDS_Shape>& modified(const TopoDS_Shape& s) const override;
const std::vector<TopoDS_Shape>& generated(const TopoDS_Shape& s) const override;
};
} // namespace Part
#endif // PART_TOPOSHAPE_H
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