// Created on: 1993-03-10 // Created by: JCV // Copyright (c) 1993-1999 Matra Datavision // Copyright (c) 1999-2014 OPEN CASCADE SAS // // This file is part of Open CASCADE Technology software library. // // This library is free software; you can redistribute it and/or modify it under // the terms of the GNU Lesser General Public License version 2.1 as published // by the Free Software Foundation, with special exception defined in the file // OCCT_LGPL_EXCEPTION.txt. Consult the file LICENSE_LGPL_21.txt included in OCCT // distribution for complete text of the license and disclaimer of any warranty. // // Alternatively, this file may be used under the terms of Open CASCADE // commercial license or contractual agreement. #ifndef _Geom_Transformation_HeaderFile #define _Geom_Transformation_HeaderFile #include #include #include #include #include #include #include DEFINE_STANDARD_HANDLE(Geom_Transformation, Standard_Transient) //! Describes how to construct the following elementary transformations //! - translations, //! - rotations, //! - symmetries, //! - scales. //! The Transformation class can also be used to //! construct complex transformations by combining these //! elementary transformations. //! However, these transformations can never change //! the type of an object. For example, the projection //! transformation can change a circle into an ellipse, and //! therefore change the real type of the object. Such a //! transformation is forbidden in this environment and //! cannot be a Geom_Transformation. //! The transformation can be represented as follow : //! //! V1 V2 V3 T //! | a11 a12 a13 a14 | | x | | x'| //! | a21 a22 a23 a24 | | y | | y'| //! | a31 a32 a33 a34 | | z | = | z'| //! | 0 0 0 1 | | 1 | | 1 | //! //! where {V1, V2, V3} defines the vectorial part of the //! transformation and T defines the translation part of //! the transformation. //! Note: Geom_Transformation transformations //! provide the same kind of "geometric" services as //! gp_Trsf ones but have more complex data structures. //! The geometric objects provided by the Geom //! package use gp_Trsf transformations in the syntaxes //! Transform and Transformed. //! Geom_Transformation transformations are used in //! a context where they can be shared by several //! objects contained inside a common data structure. class Geom_Transformation : public Standard_Transient { DEFINE_STANDARD_RTTIEXT(Geom_Transformation, Standard_Transient) public: //! Creates an identity transformation. Standard_EXPORT Geom_Transformation(); //! Creates a transient copy of T. Standard_EXPORT Geom_Transformation(const gp_Trsf& T); //! Makes the transformation into a symmetrical transformation //! with respect to a point P. //! P is the center of the symmetry. void SetMirror (const gp_Pnt& thePnt) { gpTrsf.SetMirror (thePnt); } //! Makes the transformation into a symmetrical transformation //! with respect to an axis A1. //! A1 is the center of the axial symmetry. void SetMirror (const gp_Ax1& theA1) { gpTrsf.SetMirror (theA1); } //! Makes the transformation into a symmetrical transformation //! with respect to a plane. The plane of the symmetry is //! defined with the axis placement A2. It is the plane //! (Location, XDirection, YDirection). void SetMirror (const gp_Ax2& theA2) { gpTrsf.SetMirror (theA2); } //! Makes the transformation into a rotation. //! A1 is the axis rotation and Ang is the angular value //! of the rotation in radians. void SetRotation (const gp_Ax1& theA1, const Standard_Real theAng) { gpTrsf.SetRotation (theA1, theAng); } //! Makes the transformation into a scale. P is the center of //! the scale and S is the scaling value. void SetScale (const gp_Pnt& thePnt, const Standard_Real theScale) { gpTrsf.SetScale (thePnt, theScale); } //! Makes a transformation allowing passage from the coordinate //! system "FromSystem1" to the coordinate system "ToSystem2". //! Example : //! In a C++ implementation : //! Real x1, y1, z1; // are the coordinates of a point in the //! // local system FromSystem1 //! Real x2, y2, z2; // are the coordinates of a point in the //! // local system ToSystem2 //! gp_Pnt P1 (x1, y1, z1) //! Geom_Transformation T; //! T.SetTransformation (FromSystem1, ToSystem2); //! gp_Pnt P2 = P1.Transformed (T); //! P2.Coord (x2, y2, z2); void SetTransformation (const gp_Ax3& theFromSystem1, const gp_Ax3& theToSystem2) { gpTrsf.SetTransformation (theFromSystem1, theToSystem2); } //! Makes the transformation allowing passage from the basic //! coordinate system //! {P(0.,0.,0.), VX (1.,0.,0.), VY (0.,1.,0.), VZ (0., 0. ,1.) } //! to the local coordinate system defined with the Ax2 ToSystem. //! Same utilisation as the previous method. FromSystem1 is //! defaulted to the absolute coordinate system. void SetTransformation (const gp_Ax3& theToSystem) { gpTrsf.SetTransformation (theToSystem); } //! Makes the transformation into a translation. //! V is the vector of the translation. void SetTranslation (const gp_Vec& theVec) { gpTrsf.SetTranslation (theVec); } //! Makes the transformation into a translation from the point //! P1 to the point P2. void SetTranslation (const gp_Pnt& P1, const gp_Pnt& P2) { gpTrsf.SetTranslation (P1, P2); } //! Converts the gp_Trsf transformation T into this transformation. void SetTrsf (const gp_Trsf& theTrsf) { gpTrsf = theTrsf; } //! Checks whether this transformation is an indirect //! transformation: returns true if the determinant of the //! matrix of the vectorial part of the transformation is less than 0. Standard_Boolean IsNegative() const { return gpTrsf.IsNegative(); } //! Returns the nature of this transformation as a value //! of the gp_TrsfForm enumeration. gp_TrsfForm Form() const { return gpTrsf.Form(); } //! Returns the scale value of the transformation. Standard_Real ScaleFactor() const { return gpTrsf.ScaleFactor(); } //! Returns a non transient copy of . const gp_Trsf& Trsf() const { return gpTrsf; } //! Returns the coefficients of the global matrix of transformation. //! It is a 3 rows X 4 columns matrix. //! //! Raised if Row < 1 or Row > 3 or Col < 1 or Col > 4 Standard_Real Value (const Standard_Integer theRow, const Standard_Integer theCol) const { return gpTrsf.Value (theRow, theCol); } //! Raised if the the transformation is singular. This means that //! the ScaleFactor is lower or equal to Resolution from //! package gp. void Invert() { gpTrsf.Invert(); } //! Raised if the the transformation is singular. This means that //! the ScaleFactor is lower or equal to Resolution from //! package gp. Standard_NODISCARD Standard_EXPORT Handle(Geom_Transformation) Inverted() const; //! Computes the transformation composed with Other and . //! * Other. //! Returns a new transformation Standard_NODISCARD Standard_EXPORT Handle(Geom_Transformation) Multiplied (const Handle(Geom_Transformation)& Other) const; //! Computes the transformation composed with Other and . //! = * Other. void Multiply (const Handle(Geom_Transformation)& theOther) { gpTrsf.Multiply (theOther->Trsf()); } //! Computes the following composition of transformations //! if N > 0 * * .......* . //! if N = 0 Identity //! if N < 0 .Invert() * .........* .Invert() //! //! Raised if N < 0 and if the transformation is not inversible void Power (const Standard_Integer N) { gpTrsf.Power (N); } //! Raised if N < 0 and if the transformation is not inversible Standard_EXPORT Handle(Geom_Transformation) Powered (const Standard_Integer N) const; //! Computes the matrix of the transformation composed with //! and Other. = Other * Standard_EXPORT void PreMultiply (const Handle(Geom_Transformation)& Other); //! Applies the transformation to the triplet {X, Y, Z}. void Transforms (Standard_Real& theX, Standard_Real& theY, Standard_Real& theZ) const { gpTrsf.Transforms (theX, theY, theZ); } //! Creates a new object which is a copy of this transformation. Standard_EXPORT Handle(Geom_Transformation) Copy() const; //! Dumps the content of me into the stream Standard_EXPORT virtual void DumpJson (Standard_OStream& theOStream, Standard_Integer theDepth = -1) const; private: gp_Trsf gpTrsf; }; #endif // _Geom_Transformation_HeaderFile