// File GccAna_Circ2d3Tan_2.cxx, REG 08/07/91 #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include //========================================================================= // Creation d un cercle tangent a un cercle et a deux droites. + //========================================================================= GccAna_Circ2d3Tan::GccAna_Circ2d3Tan (const GccEnt_QualifiedCirc& Qualified1 , const GccEnt_QualifiedLin& Qualified2 , const GccEnt_QualifiedLin& Qualified3 , const Standard_Real Tolerance ) //========================================================================= // Initialisation des champs. + //========================================================================= :cirsol(1,8) , qualifier1(1,8) , qualifier2(1,8) , qualifier3(1,8) , TheSame1(1,8) , TheSame2(1,8) , TheSame3(1,8) , pnttg1sol(1,8) , pnttg2sol(1,8) , pnttg3sol(1,8) , par1sol(1,8) , par2sol(1,8) , par3sol(1,8) , pararg1(1,8) , pararg2(1,8) , pararg3(1,8) { TheSame1.Init(0); gp_Dir2d dirx(1.0,0.0); Standard_Real Tol = Abs(Tolerance); WellDone = Standard_False; NbrSol = 0; if (!(Qualified1.IsEnclosed() || Qualified1.IsEnclosing() || Qualified1.IsOutside() || Qualified1.IsUnqualified()) || !(Qualified2.IsEnclosed() || Qualified2.IsOutside() || Qualified2.IsUnqualified()) || !(Qualified3.IsEnclosed() || Qualified3.IsOutside() || Qualified3.IsUnqualified())) { GccEnt_BadQualifier::Raise(); return; } //========================================================================= // Traitement. + //========================================================================= gp_Circ2d C1 = Qualified1.Qualified(); gp_Lin2d L2 = Qualified2.Qualified(); gp_Lin2d L3 = Qualified3.Qualified(); Standard_Real R1 = C1.Radius(); gp_Pnt2d center1(C1.Location()); gp_Pnt2d origin2(L2.Location()); gp_Dir2d dir2(L2.Direction()); gp_Dir2d normL2(-dir2.Y(),dir2.X()); gp_Pnt2d origin3(L3.Location()); gp_Dir2d dir3(L3.Direction()); gp_Dir2d normL3(-dir3.Y(),dir3.X()); TColStd_Array1OfReal Radius(1,2); GccAna_CircLin2dBisec Bis1(C1,L2); GccAna_Lin2dBisec Bis2(L2,L3); if (Bis1.IsDone() && Bis2.IsDone()) { Standard_Integer nbsolution1 = Bis1.NbSolutions(); Standard_Integer nbsolution2 = Bis2.NbSolutions(); for (Standard_Integer i = 1 ; i <= nbsolution1; i++) { Handle(GccInt_Bisec) Sol1 = Bis1.ThisSolution(i); GccInt_IType typ1 = Sol1->ArcType(); IntAna2d_AnaIntersection Intp; for (Standard_Integer k = 1 ; k <= nbsolution2; k++) { if (typ1 == GccInt_Lin) { Intp.Perform(Sol1->Line(),Bis2.ThisSolution(k)); } else if (typ1 == GccInt_Par) { Intp.Perform(Bis2.ThisSolution(k),IntAna2d_Conic(Sol1->Parabola())); } if (Intp.IsDone()) { if ((!Intp.IsEmpty())&&(!Intp.ParallelElements())&& (!Intp.IdenticalElements())) { for (Standard_Integer j = 1 ; j <= Intp.NbPoints() ; j++) { gp_Pnt2d Center(Intp.Point(j).Value()); Standard_Real dist1 = Center.Distance(center1); Standard_Real dist2 = L2.Distance(Center); Standard_Real dist3 = L3.Distance(Center); Standard_Integer nbsol1 = 0; Standard_Integer nbsol3 = 0; Standard_Boolean ok = Standard_False; if (Qualified1.IsEnclosed()) { if (dist1-R1 < Tolerance) { Radius(1) = Abs(R1-dist1); nbsol1 = 1; ok = Standard_True; } } else if (Qualified1.IsOutside()) { if (R1-dist1 < Tolerance) { Radius(1) = Abs(R1-dist1); nbsol1 = 1; ok = Standard_True; } } else if (Qualified1.IsEnclosing()) { ok = Standard_True; nbsol1 = 1; Radius(1) = Abs(R1-dist1); } else if (Qualified1.IsUnqualified()) { ok = Standard_True; nbsol1 = 2; Radius(1) = Abs(R1-dist1); Radius(2) = R1+dist1; } if (Qualified2.IsEnclosed() && ok) { if ((((origin2.X()-Center.X())*(-dir2.Y()))+ ((origin2.Y()-Center.Y())*(dir2.X())))<=0){ for (Standard_Integer ii = 1 ; ii <= nbsol1 ; ii++) { if (Abs(dist2-Radius(ii)) < Tol) { ok = Standard_True; Radius(1) = Radius(ii); } } } } else if (Qualified2.IsOutside() && ok) { if ((((origin2.X()-Center.X())*(-dir2.Y()))+ ((origin2.Y()-Center.Y())*(dir2.X())))>=0){ for (Standard_Integer ii = 1 ; ii <= nbsol1 ; ii++) { if (Abs(dist2-Radius(ii)) < Tol) { ok = Standard_True; Radius(1) = Radius(ii); } } } } else if (Qualified2.IsUnqualified() && ok) { for (Standard_Integer ii = 1 ; ii <= nbsol1 ; ii++) { if (Abs(dist2-Radius(ii)) < Tol) { ok = Standard_True; Radius(1) = Radius(ii); } } } if (Qualified3.IsEnclosed() && ok) { if ((((origin3.X()-Center.X())*(-dir3.Y()))+ ((origin3.Y()-Center.Y())*(dir3.X())))<=0){ if (Abs(dist3-Radius(1)) < Tol) { ok = Standard_True; nbsol3 = 1; } } } else if (Qualified3.IsOutside() && ok) { if ((((origin3.X()-Center.X())*(-dir3.Y()))+ ((origin3.Y()-Center.Y())*(dir3.X())))>=0){ if (Abs(dist3-Radius(1)) < Tol) { ok = Standard_True; nbsol3 = 1; } } } else if (Qualified3.IsUnqualified() && ok) { if (Abs(dist3-Radius(1)) < Tol) { ok = Standard_True; nbsol3 = 1; } } if (ok) { for (k = 1 ; k <= nbsol3 ; k++) { NbrSol++; cirsol(NbrSol) = gp_Circ2d(gp_Ax2d(Center,dirx),Radius(k)); // ========================================================== Standard_Real distcc1 = Center.Distance(center1); if (!Qualified1.IsUnqualified()) { qualifier1(NbrSol) = Qualified1.Qualifier(); } else if (Abs(distcc1+Radius(k)-R1) < Tol) { qualifier1(NbrSol) = GccEnt_enclosed; } else if (Abs(distcc1-R1-Radius(k)) < Tol) { qualifier1(NbrSol) = GccEnt_outside; } else { qualifier1(NbrSol) = GccEnt_enclosing; } gp_Dir2d dc2(origin2.XY()-Center.XY()); if (!Qualified2.IsUnqualified()) { qualifier2(NbrSol) = Qualified2.Qualifier(); } else if (dc2.Dot(normL2) > 0.0) { qualifier2(NbrSol) = GccEnt_outside; } else { qualifier2(NbrSol) = GccEnt_enclosed; } gp_Dir2d dc3(origin3.XY()-Center.XY()); if (!Qualified3.IsUnqualified()) { qualifier3(NbrSol) = Qualified3.Qualifier(); } else if (dc3.Dot(normL3) > 0.0) { qualifier3(NbrSol) = GccEnt_outside; } else { qualifier3(NbrSol) = GccEnt_enclosed; } if (Center.Distance(center1) <= Tolerance && Abs(Radius(k)-R1) <= Tolerance) { TheSame1(NbrSol) = 1; } else { TheSame1(NbrSol) = 0; gp_Dir2d dc(center1.XY()-Center.XY()); pnttg1sol(NbrSol)=gp_Pnt2d(Center.XY()+Radius(k)*dc.XY()); par1sol(NbrSol)=ElCLib::Parameter(cirsol(NbrSol), pnttg1sol(NbrSol)); pararg1(NbrSol)=ElCLib::Parameter(C1,pnttg1sol(NbrSol)); } TheSame2(NbrSol) = 0; TheSame3(NbrSol) = 0; gp_Dir2d dc(origin2.XY()-Center.XY()); Standard_Real sign = dc.Dot(gp_Dir2d(-dir2.Y(),dir2.X())); dc = gp_Dir2d(sign*gp_XY(-dir2.Y(),dir2.X())); pnttg2sol(NbrSol) = gp_Pnt2d(Center.XY()+Radius(k)*dc.XY()); par2sol(NbrSol)=ElCLib::Parameter(cirsol(NbrSol), pnttg2sol(NbrSol)); pararg2(NbrSol)=ElCLib::Parameter(L2,pnttg2sol(NbrSol)); dc = gp_Dir2d(origin3.XY()-Center.XY()); sign = dc.Dot(gp_Dir2d(-dir3.Y(),dir3.X())); dc = gp_Dir2d(sign*gp_XY(-dir3.Y(),dir3.X())); pnttg3sol(NbrSol) = gp_Pnt2d(Center.XY()+Radius(k)*dc.XY()); par3sol(NbrSol)=ElCLib::Parameter(cirsol(NbrSol), pnttg3sol(NbrSol)); pararg3(NbrSol)=ElCLib::Parameter(L3,pnttg3sol(NbrSol)); } } } } WellDone = Standard_True; } } } } }