// Created on: 1997-11-06
// Created by: Roman BORISOV
// Copyright (c) 1997-1999 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.
#include <Adaptor3d_Curve.hxx>
#include <Adaptor3d_Surface.hxx>
#include <gp_Pnt2d.hxx>
#include <math_FunctionSetRoot.hxx>
#include <math_NewtonFunctionSetRoot.hxx>
#include <ProjLib_PrjFunc.hxx>
#include <ProjLib_PrjResolve.hxx>
#include <Standard_ConstructionError.hxx>
#include <Standard_DomainError.hxx>
#include <StdFail_NotDone.hxx>
ProjLib_PrjResolve::ProjLib_PrjResolve(const Adaptor3d_Curve& C,const Adaptor3d_Surface& S,const Standard_Integer Fix)
: myDone(Standard_False),
myFix(Fix)
{
if (myFix > 3 || myFix < 1) throw Standard_ConstructionError();
mySolution = gp_Pnt2d(0.,0.);
myCurve = &C;
mySurface = &S;
}
// void ProjLib_PrjResolve::Perform(const Standard_Real t, const Standard_Real U, const Standard_Real V, const gp_Pnt2d& Tol2d, const gp_Pnt2d& Inf, const gp_Pnt2d& Sup, const Standard_Real FuncTol, const Standard_Boolean StrictInside)
void ProjLib_PrjResolve::Perform(const Standard_Real t, const Standard_Real U, const Standard_Real V, const gp_Pnt2d& Tol2d, const gp_Pnt2d& Inf, const gp_Pnt2d& Sup, const Standard_Real FuncTol, const Standard_Boolean )
{
myDone = Standard_False;
Standard_Real FixVal = 0.;
gp_Pnt2d ExtInf(0.,0.), ExtSup(0.,0.);
Standard_Real ExtU = 10*Tol2d.X(), ExtV = 10*Tol2d.Y();
math_Vector Tol(1, 2), Start(1, 2), BInf(1, 2), BSup(1, 2);
ExtInf.SetCoord(Inf.X() - ExtU, Inf.Y() - ExtV);
ExtSup.SetCoord(Sup.X() + ExtU, Sup.Y() + ExtV);
BInf(1) = ExtInf.X();
BInf(2) = ExtInf.Y();
BSup(1) = ExtSup.X();
BSup(2) = ExtSup.Y();
Tol(1) = Tol2d.X();
Tol(2) = Tol2d.Y();
switch(myFix) {
case 1:
Start(1) = U;
Start(2) = V;
FixVal = t;
break;
case 2:
Start(1) = t;
Start(2) = V;
FixVal = U;
break;
case 3:
Start(1) = t;
Start(2) = U;
FixVal = V;
}
ProjLib_PrjFunc F(myCurve, FixVal, mySurface, myFix);
// Standard_Integer option = 1;//2;
// if (option == 1) {
// math_FunctionSetRoot S1 (F, Start,Tol, BInf, BSup);
// if (!S1.IsDone()) { return; }
// }
// else {
math_NewtonFunctionSetRoot SR (F, Tol, 1.e-10);
SR.Perform(F, Start, BInf, BSup);
// if (!SR.IsDone()) { return; }
if (!SR.IsDone())
{
math_FunctionSetRoot S1 (F, Tol);
S1.Perform(F, Start, BInf, BSup);
if (!S1.IsDone())
return;
}
mySolution.SetXY(F.Solution().XY());
// computation of myDone
myDone = Standard_True;
Standard_Real ExtraU , ExtraV;
// if(!StrictInside) {
ExtraU = Tol2d.X();
ExtraV = Tol2d.Y();
// }
if (mySolution.X() > Inf.X() - Tol2d.X() && mySolution.X() < Inf.X()) mySolution.SetX(Inf.X());
if (mySolution.X() > Sup.X() && mySolution.X() < Sup.X() + Tol2d.X()) mySolution.SetX(Sup.X());
if (mySolution.Y() > Inf.Y() - Tol2d.Y() && mySolution.Y() < Inf.Y()) mySolution.SetY(Inf.Y());
if (mySolution.Y() > Sup.Y() && mySolution.Y() < Sup.Y() + Tol2d.Y()) mySolution.SetY(Sup.Y());
if (mySolution.X() < Inf.X() - ExtraU ||
mySolution.X() > Sup.X() + ExtraU ||
mySolution.Y() < Inf.Y() - ExtraV ||
mySolution.Y() > Sup.Y() + ExtraV) myDone = Standard_False;
else if (FuncTol > 0) {
math_Vector X(1,2,0.), FVal(1,2,0.);
X(1) = mySolution.X();
X(2) = mySolution.Y();
F.Value(X, FVal);
if ((FVal(1)*FVal(1) + FVal(2)*FVal(2)) > FuncTol) myDone = Standard_False;
}
}
Standard_Boolean ProjLib_PrjResolve::IsDone() const
{
return myDone;
}
gp_Pnt2d ProjLib_PrjResolve::Solution() const
{
if (!IsDone()) throw StdFail_NotDone();
return mySolution;
}