#include "SketchSolver.h"
#include <SketchSolver_ConstraintMulti.h>
+#include "GeomDataAPI_Point2D.h"
+
/** \class SketchSolver_ConstraintMultiRotation
* \ingroup Plugins
* \brief Convert rotated features to the list of SolveSpace constraints
SketchSolver_ConstraintMulti(theConstraint)
{}
- virtual int getType() const
- { return SLVS_C_MULTI_ROTATION; }
-
protected:
/// \brief Converts SketchPlugin constraint to a list of SolveSpace constraints
virtual void process();
/// \brief Generate list of rotated entities
- /// \param[out] theCenter ID of central point of rotation
+ /// \param[out] theCenter central point of rotation
/// \param[out] theAngle rotation angle
- /// \param[out] thePoints list of IDs of initial points and their rotated copies
- /// \param[out] theEntities list of IDs of entities and their rotated copies
- void getAttributes(Slvs_hEntity& theCenter, double& theAngle,
- std::vector< std::vector<Slvs_hEntity> >& thePoints,
- std::vector< std::vector<Slvs_hEntity> >& theEntities);
+ /// \param[out] theFullValue applying translation using the disstance as a full or single value
+ /// \param[out] theEntities list of base entities
+ void getAttributes(EntityWrapperPtr& theCenter, double& theAngle, bool& theFullValue,
+ std::list<EntityWrapperPtr>& theEntities);
/// \brief This method is used in derived objects to check consistence of constraint.
virtual void adjustConstraint();
/// \brief Apply transformation for relative coordinates
virtual void transformRelative(double& theX, double& theY);
-private:
/// \brief Returns name of NUMBER_OF_COPIES parameter for corresponding feature
- virtual const std::string& nameNbCopies();
+ virtual const std::string& nameNbObjects();
private:
- Slvs_hEntity myRotationCenter; ///< ID of center of rotation
- double myAngle; ///< angle of rotation
+ AttributePoint2DPtr myCenterPointAttribute; ///< a center of rotation
+ double myAngle; ///< angle of rotation
+ bool myIsFullValue; ///< value whether the angle is a full or single for objects
double myCenterCoord[2]; ///< coordinates of rotation center
- double myRotationVal[2]; ///< sinus and cosinus of rotation angle
+ double myRotationVal[2]; ///< sinus and cosine of rotation angle
};
#endif