// Created on: 1992-11-06 // Created by: Remi LEQUETTE // Copyright (c) 1992-1999 Matra Datavision // Copyright (c) 1999-2012 OPEN CASCADE SAS // // The content of this file is subject to the Open CASCADE Technology Public // License Version 6.5 (the "License"). You may not use the content of this file // except in compliance with the License. Please obtain a copy of the License // at http://www.opencascade.org and read it completely before using this file. // // The Initial Developer of the Original Code is Open CASCADE S.A.S., having its // main offices at: 1, place des Freres Montgolfier, 78280 Guyancourt, France. // // The Original Code and all software distributed under the License is // distributed on an "AS IS" basis, without warranty of any kind, and the // Initial Developer hereby disclaims all such warranties, including without // limitation, any warranties of merchantability, fitness for a particular // purpose or non-infringement. Please see the License for the specific terms // and conditions governing the rights and limitations under the License. #include #include #include #include #include #include #include #include //======================================================================= //function : BRepPrim_Cone //purpose : //======================================================================= BRepPrim_Cone::BRepPrim_Cone(const Standard_Real Angle, const gp_Ax2& Position, const Standard_Real Height, const Standard_Real Radius) : BRepPrim_Revolution(Position,0,0), myHalfAngle(Angle), myRadius(Radius) { if (Height < Precision::Confusion()) Standard_DomainError::Raise("cone with null height"); if (myHalfAngle*Height < Precision::Confusion()) Standard_DomainError::Raise("cone with null angle"); if ((M_PI/2 - myHalfAngle)*Height < Precision::Confusion()) Standard_DomainError::Raise("cone with angle > PI/2"); // cut at top VMax(Height / Cos(myHalfAngle)); VMin(0.); SetMeridian(); } //======================================================================= //function : BRepPrim_Cone //purpose : //======================================================================= BRepPrim_Cone::BRepPrim_Cone(const Standard_Real Angle) : BRepPrim_Revolution(gp::XOY(),0,RealLast()), myHalfAngle(Angle), myRadius(0.) { if ((Angle < 0) || (Angle > M_PI/2)) Standard_DomainError::Raise("cone with angle <0 or > PI/2"); VMin(0.); SetMeridian(); } //======================================================================= //function : BRepPrim_Cone //purpose : //======================================================================= BRepPrim_Cone::BRepPrim_Cone(const Standard_Real Angle, const gp_Pnt& Apex) : BRepPrim_Revolution(gp_Ax2(Apex,gp_Dir(0,0,1),gp_Dir(1,0,0)), 0,RealLast()), myHalfAngle(Angle), myRadius(0.) { if ((Angle < 0) || (Angle > M_PI/2)) Standard_DomainError::Raise("cone with angle <0 or > PI/2"); VMin(0.); SetMeridian(); } //======================================================================= //function : BRepPrim_Cone //purpose : //======================================================================= BRepPrim_Cone::BRepPrim_Cone(const Standard_Real Angle, const gp_Ax2& Axes) : BRepPrim_Revolution( Axes, 0,RealLast()), myHalfAngle(Angle) { if ((Angle < 0) || (Angle > M_PI/2)) Standard_DomainError::Raise("cone with angle <0 or > PI/2"); VMin(0.); SetMeridian(); } //======================================================================= //function : BRepPrim_Cone //purpose : //======================================================================= BRepPrim_Cone::BRepPrim_Cone(const Standard_Real R1, const Standard_Real R2, const Standard_Real H) : BRepPrim_Revolution(gp::XOY(),0,0) { SetParameters(R1,R2,H); SetMeridian(); } //======================================================================= //function : BRepPrim_Cone //purpose : //======================================================================= BRepPrim_Cone::BRepPrim_Cone(const gp_Pnt& Center, const Standard_Real R1, const Standard_Real R2, const Standard_Real H) : BRepPrim_Revolution(gp_Ax2(Center,gp_Dir(0,0,1),gp_Dir(1,0,0)), 0,0) { SetParameters(R1,R2,H); SetMeridian(); } //======================================================================= //function : BRepPrim_Cone //purpose : //======================================================================= BRepPrim_Cone::BRepPrim_Cone(const gp_Ax2& Axes, const Standard_Real R1, const Standard_Real R2, const Standard_Real H) : BRepPrim_Revolution(Axes,0,0) { SetParameters(R1,R2,H); SetMeridian(); } //======================================================================= //function : MakeEmptyLateralFace //purpose : //======================================================================= TopoDS_Face BRepPrim_Cone::MakeEmptyLateralFace()const { Handle(Geom_ConicalSurface) C = new Geom_ConicalSurface(Axes(),myHalfAngle,myRadius); TopoDS_Face F; myBuilder.Builder().MakeFace(F,C,Precision::Confusion()); return F; } //======================================================================= //function : SetMeridian //purpose : //======================================================================= void BRepPrim_Cone::SetMeridian () { gp_Ax1 A = Axes().Axis(); A.Rotate(gp_Ax1(Axes().Location(),Axes().YDirection()),myHalfAngle); gp_Vec V(Axes().XDirection()); V *= myRadius; A.Translate(V); Handle(Geom_Line) L = new Geom_Line(A); Handle(Geom2d_Line) L2d = new Geom2d_Line(gp_Pnt2d(myRadius,0),gp_Dir2d(Sin(myHalfAngle),Cos(myHalfAngle))); Meridian(L,L2d); } //======================================================================= //function : SetParameters //purpose : //======================================================================= void BRepPrim_Cone::SetParameters(const Standard_Real R1, const Standard_Real R2, const Standard_Real H) { if (((R1 != 0) && (R1 < Precision::Confusion())) || ((R2 != 0) && (R2 < Precision::Confusion()))) Standard_DomainError::Raise("cone with negative or too small radius"); if (Abs(R1-R2) < Precision::Confusion()) Standard_DomainError::Raise("cone with two identic radii"); if (H < Precision::Confusion()) Standard_DomainError::Raise("cone with negative or null height"); myRadius = R1; myHalfAngle = ATan((R2 - R1) / H); // cut top and bottom VMin(0.); VMax(Sqrt(H*H + (R2-R1)*(R2-R1))); }