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#include <GeomConvert_ApproxSurface.ixx>
#include <GeomAdaptor_HSurface.hxx>
#include <Precision.hxx>
#include <AdvApp2Var_ApproxAFunc2Var.hxx>
#include <Standard_Real.hxx>
#include <TColStd_HArray2OfReal.hxx>
#include <TColStd_HArray1OfReal.hxx>
#include <AdvApprox_PrefAndRec.hxx>
static Handle(Adaptor3d_HSurface) fonct;
extern "C" void mySurfEval1(Standard_Integer * Dimension,
// Dimension
Standard_Real * UStartEnd,
// StartEnd[2] in U
Standard_Real * VStartEnd,
// StartEnd[2] in V
Standard_Integer * FavorIso,
// Choice of constante, 1 for U, 2 for V
Standard_Real * ConstParam,
// Value of constant parameter
Standard_Integer * NbParams,
// Number of parameters N
Standard_Real * Parameters,
// Values of parameters,
Standard_Integer * UOrder,
// Derivative Request in U
Standard_Integer * VOrder,
// Derivative Request in V
Standard_Real * Result,
// Result[Dimension,N]
Standard_Integer * ErrorCode)
// Error Code
{
*ErrorCode = 0;
// Standard_Integer idim;
Standard_Integer jpar;
Standard_Real Upar,Vpar;
// Dimension incorrecte
if (*Dimension!=3) {
*ErrorCode = 1;
}
// Parametres incorrects
/* if (*FavorIso==1) {
Upar = *ConstParam;
if (( Upar < UStartEnd[0] ) || ( Upar > UStartEnd[1] )) {
*ErrorCode = 2;
}
for (jpar=1;jpar<=*NbParams;jpar++) {
Vpar = Parameters[jpar-1];
if (( Vpar < VStartEnd[0] ) || ( Vpar > VStartEnd[1] )) {
*ErrorCode = 2;
}
}
}
else {
Vpar = *ConstParam;
if (( Vpar < VStartEnd[0] ) || ( Vpar > VStartEnd[1] )) {
*ErrorCode = 2;
}
for (jpar=1;jpar<=*NbParams;jpar++) {
Upar = Parameters[jpar-1];
if (( Upar < UStartEnd[0] ) || ( Upar > UStartEnd[1] )) {
*ErrorCode = 2;
}
}
}*/
// Initialisation
fonct = fonct->UTrim(UStartEnd[0], UStartEnd[1], Precision::PConfusion());
fonct = fonct->VTrim(VStartEnd[0], VStartEnd[1], Precision::PConfusion());
/*
for (idim=1;idim<=*Dimension;idim++) {
for (jpar=1;jpar<=*NbParams;jpar++) {
Result[idim-1+(jpar-1)*(*Dimension)] = 0.;
}
}*/
Standard_Integer Order = *UOrder + *VOrder;
gp_Pnt pnt;
gp_Vec vect, v1, v2, v3, v4, v5, v6, v7, v8, v9;
if (*FavorIso==1) {
Upar = *ConstParam;
switch (Order) {
case 0 :
for (jpar=1;jpar<=*NbParams;jpar++) {
Vpar = Parameters[jpar-1];
pnt = fonct->Value(Upar,Vpar);
Result[(jpar-1)*(*Dimension)] = pnt.X();
Result[1+(jpar-1)*(*Dimension)] = pnt.Y();
Result[2+(jpar-1)*(*Dimension)] = pnt.Z();
}
break;
case 1 :
for (jpar=1;jpar<=*NbParams;jpar++) {
Vpar = Parameters[jpar-1];
fonct->D1(Upar, Vpar, pnt, v1, v2);
if (*UOrder==1) {
Result[(jpar-1)*(*Dimension)] = v1.X();
Result[1+(jpar-1)*(*Dimension)] = v1.Y();
Result[2+(jpar-1)*(*Dimension)] = v1.Z();
}
else {
Result[(jpar-1)*(*Dimension)] = v2.X();
Result[1+(jpar-1)*(*Dimension)] = v2.Y();
Result[2+(jpar-1)*(*Dimension)] = v2.Z();
}
}
break;
case 2 :
for (jpar=1;jpar<=*NbParams;jpar++) {
Vpar = Parameters[jpar-1];
fonct->D2(Upar, Vpar, pnt, v1, v2, v3, v4, v5);
if (*UOrder==2) {
Result[(jpar-1)*(*Dimension)] = v3.X();
Result[1+(jpar-1)*(*Dimension)] = v3.Y();
Result[2+(jpar-1)*(*Dimension)] = v3.Z();
}
else if (*UOrder==1) {
Result[(jpar-1)*(*Dimension)] = v5.X();
Result[1+(jpar-1)*(*Dimension)] = v5.Y();
Result[2+(jpar-1)*(*Dimension)] = v5.Z();
}
else if (*UOrder==0) {
Result[(jpar-1)*(*Dimension)] = v4.X();
Result[1+(jpar-1)*(*Dimension)] = v4.Y();
Result[2+(jpar-1)*(*Dimension)] = v4.Z();
}
}
break;
case 3 :
for (jpar=1;jpar<=*NbParams;jpar++) {
Vpar = Parameters[jpar-1];
fonct->D3(Upar, Vpar, pnt, v1, v2, v3, v4, v5, v6, v7, v8, v9);
if (*UOrder==2) {
Result[(jpar-1)*(*Dimension)] = v8.X();
Result[1+(jpar-1)*(*Dimension)] = v8.Y();
Result[2+(jpar-1)*(*Dimension)] = v8.Z();
}
else if (*UOrder==1) {
Result[(jpar-1)*(*Dimension)] = v9.X();
Result[1+(jpar-1)*(*Dimension)] = v9.Y();
Result[2+(jpar-1)*(*Dimension)] = v9.Z();
}
}
break;
case 4 :
for (jpar=1;jpar<=*NbParams;jpar++) {
Vpar = Parameters[jpar-1];
vect = fonct->DN(Upar, Vpar, *UOrder, *VOrder);
Result[(jpar-1)*(*Dimension)] = vect.X();
Result[1+(jpar-1)*(*Dimension)] = vect.Y();
Result[2+(jpar-1)*(*Dimension)] = vect.Z();
}
break;
}
}
else {
Vpar = *ConstParam;
switch (Order) {
case 0 :
for (jpar=1;jpar<=*NbParams;jpar++) {
Upar = Parameters[jpar-1];
pnt = fonct->Value(Upar,Vpar);
Result[(jpar-1)*(*Dimension)] = pnt.X();
Result[1+(jpar-1)*(*Dimension)] = pnt.Y();
Result[2+(jpar-1)*(*Dimension)] = pnt.Z();
}
break;
case 1 :
for (jpar=1;jpar<=*NbParams;jpar++) {
Upar = Parameters[jpar-1];
fonct->D1(Upar, Vpar, pnt, v1, v2);
if (*UOrder==1) {
Result[(jpar-1)*(*Dimension)] = v1.X();
Result[1+(jpar-1)*(*Dimension)] = v1.Y();
Result[2+(jpar-1)*(*Dimension)] = v1.Z();
}
else {
Result[(jpar-1)*(*Dimension)] = v2.X();
Result[1+(jpar-1)*(*Dimension)] = v2.Y();
Result[2+(jpar-1)*(*Dimension)] = v2.Z();
}
}
break;
case 2 :
for (jpar=1;jpar<=*NbParams;jpar++) {
Upar = Parameters[jpar-1];
fonct->D2(Upar, Vpar, pnt, v1, v2, v3, v4, v5);
if (*UOrder==2) {
Result[(jpar-1)*(*Dimension)] = v3.X();
Result[1+(jpar-1)*(*Dimension)] = v3.Y();
Result[2+(jpar-1)*(*Dimension)] = v3.Z();
}
else if (*UOrder==1) {
Result[(jpar-1)*(*Dimension)] = v5.X();
Result[1+(jpar-1)*(*Dimension)] = v5.Y();
Result[2+(jpar-1)*(*Dimension)] = v5.Z();
}
else if (*UOrder==0) {
Result[(jpar-1)*(*Dimension)] = v4.X();
Result[1+(jpar-1)*(*Dimension)] = v4.Y();
Result[2+(jpar-1)*(*Dimension)] = v4.Z();
}
}
break;
case 3 :
for (jpar=1;jpar<=*NbParams;jpar++) {
Upar = Parameters[jpar-1];
fonct->D3(Upar, Vpar, pnt, v1, v2, v3, v4, v5, v6, v7, v8, v9);
if (*UOrder==2) {
Result[(jpar-1)*(*Dimension)] = v8.X();
Result[1+(jpar-1)*(*Dimension)] = v8.Y();
Result[2+(jpar-1)*(*Dimension)] = v8.Z();
}
else if (*UOrder==1) {
Result[(jpar-1)*(*Dimension)] = v9.X();
Result[1+(jpar-1)*(*Dimension)] = v9.Y();
Result[2+(jpar-1)*(*Dimension)] = v9.Z();
}
}
break;
case 4 :
for (jpar=1;jpar<=*NbParams;jpar++) {
Upar = Parameters[jpar-1];
vect = fonct->DN(Upar, Vpar, *UOrder, *VOrder);
Result[(jpar-1)*(*Dimension)] = vect.X();
Result[1+(jpar-1)*(*Dimension)] = vect.Y();
Result[2+(jpar-1)*(*Dimension)] = vect.Z();
}
break;
}
}
}
//=======================================================================
//function : GeomConvert_ApproxSurface
//purpose :
//=======================================================================
GeomConvert_ApproxSurface::GeomConvert_ApproxSurface(const Handle(Geom_Surface)& Surf,
const Standard_Real Tol3d,
const GeomAbs_Shape UContinuity,
const GeomAbs_Shape VContinuity,
const Standard_Integer MaxDegU,
const Standard_Integer MaxDegV,
const Standard_Integer MaxSegments,
const Standard_Integer PrecisCode)
{
Standard_Real U0, U1, V0, V1;
fonct = new (GeomAdaptor_HSurface)(Surf); // Initialisation de la surface algorithmique
Surf->Bounds(U0, U1, V0, V1);
// " Init des nombres de sous-espaces et des tolerances"
Standard_Integer nb1 = 0, nb2 = 0, nb3 = 1;
Handle(TColStd_HArray1OfReal) nul1 =
new TColStd_HArray1OfReal(1,1);
nul1->SetValue(1,0.);
Handle(TColStd_HArray2OfReal) nul2 =
new TColStd_HArray2OfReal(1,1,1,4);
nul2->SetValue(1,1,0.);
nul2->SetValue(1,2,0.);
nul2->SetValue(1,3,0.);
nul2->SetValue(1,4,0.);
Handle(TColStd_HArray1OfReal) eps3D =
new TColStd_HArray1OfReal(1,1);
eps3D->SetValue(1,Tol3d);
Handle(TColStd_HArray2OfReal) epsfr =
new TColStd_HArray2OfReal(1,1,1,4);
epsfr->SetValue(1,1,Tol3d);
epsfr->SetValue(1,2,Tol3d);
epsfr->SetValue(1,3,Tol3d);
epsfr->SetValue(1,4,Tol3d);
// " Init du type d'iso"
GeomAbs_IsoType IsoType = GeomAbs_IsoV;
Standard_Integer NbDec;
NbDec = fonct->NbUIntervals(GeomAbs_C2);
TColStd_Array1OfReal UDec_C2(1, NbDec+1);
fonct->UIntervals(UDec_C2, GeomAbs_C2);
NbDec = fonct->NbVIntervals(GeomAbs_C2);
TColStd_Array1OfReal VDec_C2(1, NbDec+1);
fonct->VIntervals(VDec_C2, GeomAbs_C2);
NbDec = fonct->NbUIntervals(GeomAbs_C3);
TColStd_Array1OfReal UDec_C3(1, NbDec+1);
fonct->UIntervals(UDec_C3, GeomAbs_C3);
NbDec = fonct->NbVIntervals(GeomAbs_C3);
TColStd_Array1OfReal VDec_C3(1, NbDec+1);
fonct->VIntervals(VDec_C3, GeomAbs_C3);
// Approximation avec decoupe preferentiel
// aux lieux de discontinuitees C2
AdvApprox_PrefAndRec pUDec(UDec_C2,UDec_C3);
AdvApprox_PrefAndRec pVDec(VDec_C2,VDec_C3);
//POP pour WNT
AdvApp2Var_EvaluatorFunc2Var ev = mySurfEval1;
AdvApp2Var_ApproxAFunc2Var approx(nb1, nb2, nb3,
nul1,nul1,eps3D,
nul2,nul2,epsfr,
U0,U1,V0,V1,
IsoType,UContinuity,VContinuity,PrecisCode,
// MaxDegU,MaxDegV,MaxSegments,mySurfEval1,
MaxDegU,MaxDegV,MaxSegments,ev,
pUDec,pVDec);
myMaxError = approx.MaxError(3,1);
myBSplSurf = approx.Surface(1);
myIsDone = approx.IsDone();
myHasResult = approx.HasResult();
}
//=======================================================================
//function : Surface
//purpose :
//=======================================================================
Handle(Geom_BSplineSurface) GeomConvert_ApproxSurface::Surface() const
{
return myBSplSurf;
}
//=======================================================================
//function : IsDone
//purpose :
//=======================================================================
Standard_Boolean GeomConvert_ApproxSurface::IsDone() const
{
return myIsDone;
}
//=======================================================================
//function : HasResult
//purpose :
//=======================================================================
Standard_Boolean GeomConvert_ApproxSurface::HasResult() const
{
return myHasResult;
}
//=======================================================================
//function : MaxError
//purpose :
//=======================================================================
Standard_Real GeomConvert_ApproxSurface::MaxError() const
{
return myMaxError;
}
//=======================================================================
//function : Dump
//purpose :
//=======================================================================
void GeomConvert_ApproxSurface::Dump(Standard_OStream& o) const
{
o<<endl;
if (!myHasResult) { o<<"No result"<<endl; }
else {
o<<"Result max error :"<< myMaxError <<endl;
}
o<<endl;
}
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