// @(#)root/geom:$Name:  $:$Id: TGeoTube.cxx,v 1.22 2003/05/07 13:32:39 brun Exp $
// Author: Andrei Gheata   24/10/01
// TGeoTube::Contains() and DistToOut/In() implemented by Mihaela Gheata

/*************************************************************************
 * Copyright (C) 1995-2000, Rene Brun and Fons Rademakers.               *
 * All rights reserved.                                                  *
 *                                                                       *
 * For the licensing terms see $ROOTSYS/LICENSE.                         *
 * For the list of contributors see $ROOTSYS/README/CREDITS.             *
 *************************************************************************/

#include "TROOT.h"

#include "TGeoManager.h"
#include "TGeoVolume.h"
#include "TVirtualGeoPainter.h"
#include "TGeoTube.h"

/*************************************************************************
 * TGeoTube - cylindrical tube class. It takes 3 parameters : 
 * inner radius, outer radius and half-length dz. 
 *
 *************************************************************************/
//
/*

*/
//

/*************************************************************************
 * TGeoTubeSeg - a phi segment of a tube. Has 5 parameters :
 *            - the same 3 as a tube;
 *            - first phi limit (in degrees)
 *            - second phi limit 
 *
 *************************************************************************/
//
/*

*/
//

/*************************************************************************
 * TGeoCtub - a tube segment cut with 2 planes. Has 11 parameters :
 *            - the same 5 as a tube segment;
 *            - x, y, z components of the normal to the -dZ cut plane in
 *              point (0, 0, -dZ);
 *            - x, y, z components of the normal to the +dZ cut plane in
 *              point (0, 0, dZ);
 *
 *************************************************************************/
//
/*

*/
//


ClassImp(TGeoTube)
   
//-----------------------------------------------------------------------------
 TGeoTube::TGeoTube()
{
// Default constructor
   SetBit(TGeoShape::kGeoTube);
   fRmin = 0.0;
   fRmax = 0.0;
   fDz   = 0.0;
}   
//-----------------------------------------------------------------------------
 TGeoTube::TGeoTube(Double_t rmin, Double_t rmax, Double_t dz)
           :TGeoBBox(0, 0, 0)
{
// Default constructor specifying minimum and maximum radius
   SetBit(TGeoShape::kGeoTube);
   SetTubeDimensions(rmin, rmax, dz);
   if ((fDz<0) || (fRmin<0) || (fRmax<0)) {
      SetBit(kGeoRunTimeShape);
//      if (fRmax<=fRmin) SetBit(kGeoInvalidShape);
//      printf("tube : dz=%f rmin=%f rmax=%fn", dz, rmin, rmax);
   }
   ComputeBBox();
}
//-----------------------------------------------------------------------------
 TGeoTube::TGeoTube(const char *name, Double_t rmin, Double_t rmax, Double_t dz)
           :TGeoBBox(name, 0, 0, 0)
{
// Default constructor specifying minimum and maximum radius
   SetBit(TGeoShape::kGeoTube);
   SetTubeDimensions(rmin, rmax, dz);
   if ((fDz<0) || (fRmin<0) || (fRmax<0)) {
      SetBit(kGeoRunTimeShape);
//      if (fRmax<=fRmin) SetBit(kGeoInvalidShape);
//      printf("tube : dz=%f rmin=%f rmax=%fn", dz, rmin, rmax);
   }
   ComputeBBox();
}
//-----------------------------------------------------------------------------
 TGeoTube::TGeoTube(Double_t *param)
         :TGeoBBox(0, 0, 0)
{
// Default constructor specifying minimum and maximum radius
// param[0] = Rmin
// param[1] = Rmax
// param[2] = dz
   SetBit(TGeoShape::kGeoTube);
   SetDimensions(param);
   if ((fDz<0) || (fRmin<0) || (fRmax<0)) SetBit(kGeoRunTimeShape);
   ComputeBBox();
}
//-----------------------------------------------------------------------------
 TGeoTube::~TGeoTube()
{
// destructor
}
//-----------------------------------------------------------------------------   
 void TGeoTube::ComputeBBox()
{
// compute bounding box of the tube
   fDX = fDY = fRmax;
   fDZ = fDz;
}   
//-----------------------------------------------------------------------------
 Bool_t TGeoTube::Contains(Double_t *point) const
{
// test if point is inside this tube
   if (TMath::Abs(point[2]) > fDz) return kFALSE;
   Double_t r2 = point[0]*point[0]+point[1]*point[1];
   if ((r2<fRmin*fRmin) || (r2>fRmax*fRmax)) return kFALSE;
   return kTRUE;
}
//-----------------------------------------------------------------------------
 Int_t TGeoTube::DistancetoPrimitive(Int_t px, Int_t py)
{
// compute closest distance from point px,py to each corner
   Int_t n = gGeoManager->GetNsegments();
   const Int_t numPoints = 4*n;
   return ShapeDistancetoPrimitive(numPoints, px, py);
}
//-----------------------------------------------------------------------------
 Double_t TGeoTube::DistToOutS(Double_t *point, Double_t *dir, Double_t rmin, Double_t rmax, Double_t dz)
{
// compute distance from inside point to surface of the tube (static)
   Double_t rsq=point[0]*point[0]+point[1]*point[1];
   // compute distance to surface 
   // Do Z
   Double_t sz = kBig;
   if (dir[2]>1E-20) 
      sz = (dz-point[2])/dir[2];
   else
      if (dir[2]<-1E-20) sz = -(dz+point[2])/dir[2];
   // Do R
   Double_t nsq=dir[0]*dir[0]+dir[1]*dir[1];
   if (TMath::Abs(nsq)<1E-10) return sz;
   Double_t rdotn=point[0]*dir[0]+point[1]*dir[1];
   Double_t b,d;
   Double_t sr;
   // inner cylinder
   if (rmin>1E-10) {
      DistToTube(rsq,nsq,rdotn,rmin,b,d);
      if (d>0) {
         sr=-b-d;
         if (sr>0) return TMath::Min(sz,sr);
      }
   }
   // outer cylinder
   DistToTube(rsq,nsq,rdotn,rmax,b,d);
   if (d>0) {
      sr=-b+d;
      if (sr>0) return TMath::Min(sz,sr);
   }
   printf("Error : TGeoTube::DistToOutS() -> cannot exit tube !n");
   return kBig;      
}
//-----------------------------------------------------------------------------
 Double_t TGeoTube::DistToOut(Double_t *point, Double_t *dir, Int_t iact, Double_t step, Double_t *safe) const
{
// compute distance from inside point to surface of the tube
   if (iact<3 && safe) {
      *safe = Safety(point, kTRUE);
      if (iact==0) return kBig;
      if ((iact==1) && (*safe>step)) return kBig;
   }
   // compute distance to surface 
   Double_t rsq=point[0]*point[0]+point[1]*point[1];
   // Do Z
   Double_t sz = kBig;
   if (dir[2]>1E-20) 
      sz = (fDz-point[2])/dir[2];
   else
      if (dir[2]<-1E-20) sz = -(fDz+point[2])/dir[2];
   // Do R
   Double_t nsq=dir[0]*dir[0]+dir[1]*dir[1];
   if (TMath::Abs(nsq)<1E-10) return sz;
   Double_t rdotn=point[0]*dir[0]+point[1]*dir[1];
   Double_t b,d;
   Double_t sr;
   // inner cylinder
   if (fRmin>1E-10) {
      DistToTube(rsq,nsq,rdotn,fRmin,b,d);
      if (d>0) {
         sr=-b-d;
         if (sr>0) return TMath::Min(sz,sr);
      }
   }
   // outer cylinder
   DistToTube(rsq,nsq,rdotn,fRmax,b,d);
   if (d>0) {
      sr=-b+d;
      if (sr>0) return TMath::Min(sz,sr);
   }
   Error("DistToOutS","cannot exit tube !");
   return kBig;      
}
//-----------------------------------------------------------------------------
 Double_t TGeoTube::DistToInS(Double_t *point, Double_t *dir, Double_t rmin, Double_t rmax, Double_t dz)
{
// static method to compute distance from outside point to a tube with given parameters
   Double_t rsq = point[0]*point[0]+point[1]*point[1];

   // check Z planes
   Double_t xi,yi,zi;
   Double_t s = kBig;
   if (TMath::Abs(point[2])>dz) {
      if ((point[2]*dir[2])<0) {
         s = (TMath::Abs(point[2])-dz)/TMath::Abs(dir[2]);
         xi = point[0]+s*dir[0];
         yi = point[1]+s*dir[1];
         Double_t r2=xi*xi+yi*yi;
         if (((rmin*rmin)<=r2) && (r2<=(rmax*rmax))) return s;
      }
   }      
   
   // check outer cyl. surface
   Double_t nsq=dir[0]*dir[0]+dir[1]*dir[1];
   if (TMath::Abs(nsq)<1E-10) return kBig;
   Double_t rdotn=point[0]*dir[0]+point[1]*dir[1];
   Double_t b,d;
   // only r>rmax has to be considered
   if (rsq>rmax*rmax) {
      DistToTube(rsq, nsq, rdotn, rmax, b, d);
      if (d>0) {
         s=-b-d;
         if (s>0) {
            zi=point[2]+s*dir[2];
            if (TMath::Abs(zi)<=dz) return s;
         }
      }
   }         
   // check inner cylinder
   if (rmin>0) {
      DistToTube(rsq, nsq, rdotn, rmin, b, d);
      if (d>0) {
         s=-b+d;
         if (s>0) {
            zi=point[2]+s*dir[2];
            if (TMath::Abs(zi)<=dz) return s;
         }
      }
   }         
   return kBig;
}   
//-----------------------------------------------------------------------------
 Double_t TGeoTube::DistToIn(Double_t *point, Double_t *dir, Int_t iact, Double_t step, Double_t *safe) const
{
// compute distance from outside point to surface of the tube and safe distance
   // fist localize point w.r.t tube
   if (iact<3 && *safe) {
      *safe = Safety(point, kFALSE);
      if (iact==0) return kBig;
      if ((iact==1) && (step<=*safe)) return kBig;
   }
   // find distance to shape
   return DistToInS(point, dir, fRmin, fRmax, fDz);
}

//-----------------------------------------------------------------------------
 void TGeoTube::DistToTube(Double_t rsq, Double_t nsq, Double_t rdotn, Double_t radius, Double_t &b, Double_t &delta)
{
// Static method computing the distance to a tube with given radius, starting from
// POINT along DIR director cosines. The distance is computed as :
//    RSQ   = point[0]*point[0]+point[1]*point[1]
//    NSQ   = dir[0]*dir[0]+dir[1]*dir[1]  ---> should NOT be 0 !!!
//    RDOTN = point[0]*dir[0]+point[1]*dir[1]
// The distance can be computed as :
//    D = -B +/- DELTA 
// where DELTA.GT.0 and D.GT.0

   Double_t t1 = 1./nsq;
   Double_t t3=rsq-(radius*radius);
   b          = t1*rdotn;
   Double_t c =t1*t3;
   delta = b*b-c;
   if (delta>0) {
      delta=TMath::Sqrt(delta);
   } else {
      delta = -1;
   }      
}         

//-----------------------------------------------------------------------------
 Double_t TGeoTube::DistToSurf(Double_t * /*point*/, Double_t * /*dir*/) const
{
// computes the distance to next surface of the sphere along a ray
// starting from given point to the given direction.
   return kBig;
}
//-----------------------------------------------------------------------------
 TGeoVolume *TGeoTube::Divide(TGeoVolume *voldiv, const char *divname, Int_t iaxis, Int_t ndiv, 
                             Double_t start, Double_t step) 
{
//--- Divide this tube shape belonging to volume "voldiv" into ndiv volumes
// called divname, from start position with the given step. Returns pointer
// to created division cell volume in case of Z divisions. For radial division 
// creates all volumes with different shapes and returns pointer to volume that
// was divided. In case a wrong division axis is supplied, returns pointer to 
// volume that was divided.
   TGeoShape *shape;           //--- shape to be created
   TGeoVolume *vol;            //--- division volume to be created
   TGeoVolumeMulti *vmulti;    //--- generic divided volume
   TGeoPatternFinder *finder;  //--- finder to be attached 
   TString opt = "";           //--- option to be attached
   Int_t id;
   Double_t end = start+ndiv*step;
   switch (iaxis) {
      case 1:  //---                R division
         finder = new TGeoPatternCylR(voldiv, ndiv, start, end);
         vmulti = gGeoManager->MakeVolumeMulti(divname, voldiv->GetMedium());
         voldiv->SetFinder(finder);
         finder->SetDivIndex(voldiv->GetNdaughters());
         for (id=0; id<ndiv; id++) {
            shape = new TGeoTube(start+id*step, start+(id+1)*step, fDz);
            vol = new TGeoVolume(divname, shape, voldiv->GetMedium());
            vmulti->AddVolume(vol);
            opt = "R";
            voldiv->AddNodeOffset(vol, id, 0, opt.Data());
            ((TGeoNodeOffset*)voldiv->GetNodes()->At(voldiv->GetNdaughters()-1))->SetFinder(finder);
         }
         return vmulti;
      case 2:  //---                Phi division
         finder = new TGeoPatternCylPhi(voldiv, ndiv, start, end);
         voldiv->SetFinder(finder);
         finder->SetDivIndex(voldiv->GetNdaughters());            
         shape = new TGeoTubeSeg(fRmin, fRmax, fDz, -step/2, step/2);
         vol = new TGeoVolume(divname, shape, voldiv->GetMedium());
         vmulti = gGeoManager->MakeVolumeMulti(divname, voldiv->GetMedium());
         vmulti->AddVolume(vol);
         opt = "Phi";
         for (id=0; id<ndiv; id++) {
            voldiv->AddNodeOffset(vol, id, start+id*step+step/2, opt.Data());
            ((TGeoNodeOffset*)voldiv->GetNodes()->At(voldiv->GetNdaughters()-1))->SetFinder(finder);
         }
         return vmulti;
      case 3: //---                  Z division
         finder = new TGeoPatternZ(voldiv, ndiv, start, start+ndiv*step);
         voldiv->SetFinder(finder);
         finder->SetDivIndex(voldiv->GetNdaughters());            
         shape = new TGeoTube(fRmin, fRmax, step/2);
         vol = new TGeoVolume(divname, shape, voldiv->GetMedium());
         vmulti = gGeoManager->MakeVolumeMulti(divname, voldiv->GetMedium());
         vmulti->AddVolume(vol);
         opt = "Z";
         for (id=0; id<ndiv; id++) {
            voldiv->AddNodeOffset(vol, id, start+step/2+id*step, opt.Data());
            ((TGeoNodeOffset*)voldiv->GetNodes()->At(voldiv->GetNdaughters()-1))->SetFinder(finder);
         }
         return vmulti;
      default:
         Error("Divide", "Wrong axis type for division");
         return 0;            
   }
}   
//-----------------------------------------------------------------------------
 const char *TGeoTube::GetAxisName(Int_t iaxis) const
{
// Returns name of axis IAXIS.
   switch (iaxis) {
      case 1:
         return "R";
      case 2:
         return "PHI";
      case 3:
         return "Z";
      default:
         return "UNDEFINED";
   }
}   

//-----------------------------------------------------------------------------
 Double_t TGeoTube::GetAxisRange(Int_t iaxis, Double_t &xlo, Double_t &xhi) const
{
// Get range of shape for a given axis.
   xlo = 0;
   xhi = 0;
   Double_t dx = 0;
   switch (iaxis) {
      case 1:
         xlo = fRmin;
         xhi = fRmax;
         dx = xhi-xlo;
         return dx;
      case 2:
         xlo = 0;
         xhi = 360;
         dx = 360;
         return dx;
      case 3:
         xlo = -fDz;
         xhi = fDz;
         dx = xhi-xlo;
         return dx;
   }
   return dx;
}         
            
//-----------------------------------------------------------------------------
 void TGeoTube::GetBoundingCylinder(Double_t *param) const
{
//--- Fill vector param[4] with the bounding cylinder parameters. The order
// is the following : Rmin, Rmax, Phi1, Phi2, dZ
   param[0] = fRmin; // Rmin
   param[0] *= param[0];
   param[1] = fRmax; // Rmax
   param[1] *= param[1];
   param[2] = 0.;    // Phi1
   param[3] = 360.;  // Phi1
}
//-----------------------------------------------------------------------------
 TGeoShape *TGeoTube::GetMakeRuntimeShape(TGeoShape *mother, TGeoMatrix * /*mat*/) const
{
// in case shape has some negative parameters, these has to be computed
// in order to fit the mother
   if (!TestBit(kGeoRunTimeShape)) return 0;
   Double_t rmin, rmax, dz;
   Double_t xmin,xmax;
   rmin = fRmin;
   rmax = fRmax;
   dz = fDz;
   if (fDz<0) {
      mother->GetAxisRange(3,xmin,xmax);
      if (xmax<0) return 0;
      dz=xmax;
   }   
   mother->GetAxisRange(1,xmin,xmax);
   if (fRmin<0) {
      if (xmin<0) return 0;
      rmin = xmin;
   }   
   if (fRmax<0) {
      if (xmax<=0) return 0;
      rmax = xmax;
   }   

   return (new TGeoTube(rmin, rmax, dz));
}
//-----------------------------------------------------------------------------
 void TGeoTube::InspectShape() const
{
// print shape parameters
   printf("*** TGeoTube parameters ***n");
   printf("    Rmin = %11.5fn", fRmin);
   printf("    Rmax = %11.5fn", fRmax);
   printf("    dz   = %11.5fn", fDz);
   TGeoBBox::InspectShape();
}
//-----------------------------------------------------------------------------
 void *TGeoTube::Make3DBuffer(const TGeoVolume *vol) const
{
   TVirtualGeoPainter *painter = gGeoManager->GetGeomPainter();
   if (!painter) return 0;
   return painter->MakeTube3DBuffer(vol);
}

//-----------------------------------------------------------------------------
 void TGeoTube::Paint(Option_t *option)
{
// paint this shape according to option
   TVirtualGeoPainter *painter = gGeoManager->GetGeomPainter();
   if (!painter) return;
   TGeoVolume *vol = gGeoManager->GetCurrentVolume();
   if (vol->GetShape() != (TGeoShape*)this) return;
   painter->PaintTube(this, option);
}
//-----------------------------------------------------------------------------
 void TGeoTube::PaintNext(TGeoHMatrix *glmat, Option_t *option)
{
// paint this shape according to option
   TVirtualGeoPainter *painter = gGeoManager->GetGeomPainter();
   if (!painter) return;
   painter->PaintTube(this, option, glmat);
}
//-----------------------------------------------------------------------------
 void TGeoTube::NextCrossing(TGeoParamCurve * /*c*/, Double_t * /*point*/) const
{
// computes next intersection point of curve c with this shape
}
//-----------------------------------------------------------------------------
 Double_t TGeoTube::Safety(Double_t *point, Bool_t in) const
{
// computes the closest distance from given point to this shape, according
// to option. The matching point on the shape is stored in spoint.
   Double_t saf[3];
   Double_t rsq = point[0]*point[0]+point[1]*point[1];
   Double_t r = TMath::Sqrt(rsq);
   saf[0] = fDz-TMath::Abs(point[2]); // positive if inside
   saf[1] = (fRmin>1E-10)?(r-fRmin):kBig;
   saf[2] = fRmax-r;
   if (in) return saf[TMath::LocMin(3,saf)];
   for (Int_t i=0; i<3; i++) saf[i]=-saf[i];
   return saf[TMath::LocMax(3,saf)];
}
//-----------------------------------------------------------------------------
 Double_t TGeoTube::SafetyS(Double_t *point, Bool_t in, Double_t rmin, Double_t rmax, Double_t dz, Int_t skipz)
{
// computes the closest distance from given point to this shape, according
// to option. The matching point on the shape is stored in spoint.
   Double_t saf[3];
   Double_t rsq = point[0]*point[0]+point[1]*point[1];
   Double_t r = TMath::Sqrt(rsq);
   switch (skipz) {
      case 1: // skip lower Z plane
         saf[0] = dz - point[2];
         break;
      case 2: // skip upper Z plane
         saf[0] = dz + point[2];
         break;
      case 3: // skip both
         saf[0] = kBig;
         break;
      default:
         saf[0] = dz-TMath::Abs(point[2]);         
   }
   saf[1] = (rmin>1E-10)?(r-rmin):kBig;
   saf[2] = rmax-r;
//   printf("saf0=%g saf1=%g saf2=%g in=%d skipz=%dn", saf[0],saf[1],saf[2],in,skipz);
   if (in) return saf[TMath::LocMin(3,saf)];
   for (Int_t i=0; i<3; i++) saf[i]=-saf[i];
   return saf[TMath::LocMax(3,saf)];
}
//-----------------------------------------------------------------------------
 void TGeoTube::SetTubeDimensions(Double_t rmin, Double_t rmax, Double_t dz)
{
/*
   if (rmin>=0) {
      if (rmax>0) {
         if (rmin<=rmax) {
         // normal rmin/rmax
            fRmin = rmin;
            fRmax = rmax;
         } else {
            fRmin = rmax;
            fRmax = rmin;
            Warning("SetTubeDimensions", "rmin>rmax Switch rmin<->rmax");
            SetBit(TGeoShape::kGeoBad);
         }
      } else {
         // run-time
         fRmin = rmin;
         fRmax = rmax;
      }
   } else {
      // run-time
      fRmin = rmin;
      fRmax = rmax;
   }               
*/
   fRmin = rmin;
   fRmax = rmax;
   fDz   = dz;
}   
//-----------------------------------------------------------------------------
 void TGeoTube::SetDimensions(Double_t *param)
{
   Double_t rmin = param[0];
   Double_t rmax = param[1];
   Double_t dz   = param[2];
   SetTubeDimensions(rmin, rmax, dz);
}   
//-----------------------------------------------------------------------------
 void TGeoTube::SetPoints(Double_t *buff) const
{
// create tube mesh points
    Double_t dz;
    Int_t j, n;

    n = gGeoManager->GetNsegments();
    Double_t dphi = 360./n;
    Double_t phi = 0;
    dz = fDz;

    Int_t indx = 0;


    if (buff) {

        for (j = 0; j < n; j++) {
            phi = j*dphi*kDegRad;
            buff[indx+6*n] = buff[indx] = fRmin * TMath::Cos(phi);
            indx++;
            buff[indx+6*n] = buff[indx] = fRmin * TMath::Sin(phi);
            indx++;
            buff[indx+6*n] = dz;
            buff[indx]     =-dz;
            indx++;
        }
        for (j = 0; j < n; j++) {
            phi = j*dphi*kDegRad;
            buff[indx+6*n] = buff[indx] = fRmax * TMath::Cos(phi);
            indx++;
            buff[indx+6*n] = buff[indx] = fRmax * TMath::Sin(phi);
            indx++;
            buff[indx+6*n]= dz;
            buff[indx]    =-dz;
            indx++;
        }
    }
}
//-----------------------------------------------------------------------------
 void TGeoTube::SetPoints(Float_t *buff) const
{
// create tube mesh points
    Double_t dz;
    Int_t j, n;

    n = gGeoManager->GetNsegments();
    Double_t dphi = 360./n;
    Double_t phi = 0;
    dz = fDz;

    Int_t indx = 0;


    if (buff) {

        for (j = 0; j < n; j++) {
            phi = j*dphi*kDegRad;
            buff[indx+6*n] = buff[indx] = fRmin * TMath::Cos(phi);
            indx++;
            buff[indx+6*n] = buff[indx] = fRmin * TMath::Sin(phi);
            indx++;
            buff[indx+6*n] = dz;
            buff[indx]     =-dz;
            indx++;
        }
        for (j = 0; j < n; j++) {
            phi = j*dphi*kDegRad;
            buff[indx+6*n] = buff[indx] = fRmax * TMath::Cos(phi);
            indx++;
            buff[indx+6*n] = buff[indx] = fRmax * TMath::Sin(phi);
            indx++;
            buff[indx+6*n]= dz;
            buff[indx]    =-dz;
            indx++;
        }
    }
}
//-----------------------------------------------------------------------------
 void TGeoTube::Sizeof3D() const
{
// fill size of this 3-D object
    TVirtualGeoPainter *painter = gGeoManager->GetGeomPainter();
    if (!painter) return;
    Int_t n = gGeoManager->GetNsegments();
    Int_t numPoints = n*4;
    Int_t numSegs   = n*8;
    Int_t numPolys  = n*4;
    painter->AddSize3D(numPoints, numSegs, numPolys);
}

ClassImp(TGeoTubeSeg)
   
//-----------------------------------------------------------------------------
TGeoTubeSeg::TGeoTubeSeg()
{
// Default constructor
   SetBit(TGeoShape::kGeoTubeSeg);
   fPhi1 = fPhi2 = 0.0;
}   
//-----------------------------------------------------------------------------
TGeoTubeSeg::TGeoTubeSeg(Double_t rmin, Double_t rmax, Double_t dz,
                          Double_t phi1, Double_t phi2)
            :TGeoTube(rmin, rmax, dz)
{
// Default constructor specifying minimum and maximum radius
   SetBit(TGeoShape::kGeoTubeSeg);
   SetTubsDimensions(rmin, rmax, dz, phi1, phi2);
   ComputeBBox();
}
//-----------------------------------------------------------------------------
TGeoTubeSeg::TGeoTubeSeg(const char *name, Double_t rmin, Double_t rmax, Double_t dz,
                          Double_t phi1, Double_t phi2)
            :TGeoTube(name, rmin, rmax, dz)
{
// Default constructor specifying minimum and maximum radius
   SetBit(TGeoShape::kGeoTubeSeg);
   SetTubsDimensions(rmin, rmax, dz, phi1, phi2);
   ComputeBBox();
}
//-----------------------------------------------------------------------------
TGeoTubeSeg::TGeoTubeSeg(Double_t *param)
            :TGeoTube(0, 0, 0)
{
// Default constructor specifying minimum and maximum radius
// param[0] = Rmin
// param[1] = Rmax
// param[2] = dz
// param[3] = phi1
// param[4] = phi2
   SetBit(TGeoShape::kGeoTubeSeg);
   SetDimensions(param);
   ComputeBBox();
}
//-----------------------------------------------------------------------------
TGeoTubeSeg::~TGeoTubeSeg()
{
// destructor
}
//-----------------------------------------------------------------------------   
void TGeoTubeSeg::ComputeBBox()
{
// compute bounding box of the tube segment
   Double_t xc[4];
   Double_t yc[4];
   xc[0] = fRmax*TMath::Cos(fPhi1*kDegRad);
   yc[0] = fRmax*TMath::Sin(fPhi1*kDegRad);
   xc[1] = fRmax*TMath::Cos(fPhi2*kDegRad);
   yc[1] = fRmax*TMath::Sin(fPhi2*kDegRad);
   xc[2] = fRmin*TMath::Cos(fPhi1*kDegRad);
   yc[2] = fRmin*TMath::Sin(fPhi1*kDegRad);
   xc[3] = fRmin*TMath::Cos(fPhi2*kDegRad);
   yc[3] = fRmin*TMath::Sin(fPhi2*kDegRad);

   Double_t xmin = xc[TMath::LocMin(4, &xc[0])];
   Double_t xmax = xc[TMath::LocMax(4, &xc[0])]; 
   Double_t ymin = yc[TMath::LocMin(4, &yc[0])]; 
   Double_t ymax = yc[TMath::LocMax(4, &yc[0])];

   Double_t dp = fPhi2-fPhi1;
   if (dp<0) dp+=360;
   Double_t ddp = -fPhi1;
   if (ddp<0) ddp+= 360;
   if (ddp>360) ddp-=360;
   if (ddp<=dp) xmax = fRmax;
   ddp = 90-fPhi1;
   if (ddp<0) ddp+= 360;
   if (ddp>360) ddp-=360;
   if (ddp<=dp) ymax = fRmax;
   ddp = 180-fPhi1;
   if (ddp<0) ddp+= 360;
   if (ddp>360) ddp-=360;
   if (ddp<=dp) xmin = -fRmax;
   ddp = 270-fPhi1;
   if (ddp<0) ddp+= 360;
   if (ddp>360) ddp-=360;
   if (ddp<=dp) ymin = -fRmax;
   fOrigin[0] = (xmax+xmin)/2;
   fOrigin[1] = (ymax+ymin)/2;
   fOrigin[2] = 0;
   fDX = (xmax-xmin)/2;
   fDY = (ymax-ymin)/2;
   fDZ = fDz;
}   
//-----------------------------------------------------------------------------
Bool_t TGeoTubeSeg::Contains(Double_t *point) const
{
// test if point is inside this tube segment
   // first check if point is inside the tube
   if (!TGeoTube::Contains(point)) return kFALSE;
   Double_t phi = TMath::ATan2(point[1], point[0]) * kRadDeg;
   if (phi < 0 ) phi+=360.;
   Double_t dphi = fPhi2 -fPhi1;
   Double_t ddp = phi-fPhi1;
   if (ddp<0) ddp += 360.;
//   if (ddp>360) ddp-=360;
   if (ddp > dphi) return kFALSE;
   return kTRUE;    
}
//-----------------------------------------------------------------------------
Int_t TGeoTubeSeg::DistancetoPrimitive(Int_t px, Int_t py)
{
// compute closest distance from point px,py to each corner
   Int_t n = gGeoManager->GetNsegments()+1;
   const Int_t numPoints = 4*n;
   return ShapeDistancetoPrimitive(numPoints, px, py);
}
//-----------------------------------------------------------------------------
Double_t TGeoTubeSeg::DistToPhiMin(Double_t *point, Double_t *dir, Double_t s1, Double_t c1,
                                   Double_t s2, Double_t c2, Double_t sm, Double_t cm)
{
// compute distance from poin to both phi planes. Return minimum.
   Double_t sfi1=kBig;
   Double_t sfi2=kBig;
   Double_t s=0;
   Double_t un = dir[0]*s1-dir[1]*c1;
   if (un!=0) {
      s=(point[1]*c1-point[0]*s1)/un;
      if (s>=0) {
         if (((point[1]+s*dir[1])*cm-(point[0]+s*dir[0])*sm)<=0) sfi1=s;
      }   
   }
   un = dir[0]*s2-dir[1]*c2;    
   if (un!=0) {
      s=(point[1]*c2-point[0]*s2)/un;
      if (s>=0) {
         if (((point[1]+s*dir[1])*cm-(point[0]+s*dir[0])*sm)>=0) sfi2=s;
      }   
   }
   return TMath::Min(sfi1, sfi2);
}
//-----------------------------------------------------------------------------
Double_t TGeoTubeSeg::DistToOutS(Double_t *point, Double_t *dir, Double_t rmin, Double_t rmax, Double_t dz, 
                                 Double_t c1, Double_t s1, Double_t c2, Double_t s2, Double_t cm, Double_t sm)
{
// compute distance from inside point to surface of the tube segment (static)
   Double_t rsq=point[0]*point[0]+point[1]*point[1];   
   // compute distance to surface 
   // Do Z
   Double_t sz = kBig;
   if (dir[2]>1E-20) 
      sz = (dz-point[2])/dir[2];
   else
      if (dir[2]<-1E-20) sz = -(dz+point[2])/dir[2];
   // Do R
   Double_t nsq=dir[0]*dir[0]+dir[1]*dir[1];  
   // track parralel to Z
   if (TMath::Abs(nsq)<1E-10) return sz;
   
   Double_t rdotn=point[0]*dir[0]+point[1]*dir[1];  
   Double_t b, d;
   Double_t sr=kBig;
   Bool_t skip_outer = kFALSE;
   // inner cylinder
   if (rmin>1E-10) {
      TGeoTube::DistToTube(rsq,nsq,rdotn,rmin,b,d);
      if (d>0) {
         sr=-b-d;
         if (sr>0)
            skip_outer = kTRUE;
      }
   }
   // outer cylinder
   if (!skip_outer) {
      TGeoTube::DistToTube(rsq,nsq,rdotn,rmax,b,d);
      sr=-b+d;
      if (sr<0) sr=kBig;
   }
   // phi planes
   Double_t sfmin=TGeoTubeSeg::DistToPhiMin(point, dir, s1, c1, s2, c2, sm, cm);
   return TMath::Min(TMath::Min(sz,sr), sfmin);      
}
//-----------------------------------------------------------------------------
Double_t TGeoTubeSeg::DistToOut(Double_t *point, Double_t *dir, Int_t iact, Double_t step, Double_t *safe) const
{
// compute distance from inside point to surface of the tube segment
   Double_t phi1 = fPhi1*kDegRad;
   Double_t phi2 = fPhi2*kDegRad;
   Double_t c1 = TMath::Cos(phi1);
   Double_t c2 = TMath::Cos(phi2);
   Double_t s1 = TMath::Sin(phi1);
   Double_t s2 = TMath::Sin(phi2);
   if (iact<3 && safe) {
      *safe = SafetyS(point, kTRUE, fRmin, fRmax, fDz,c1,s1,c2,s2);
      if (iact==0) return kBig;
      if ((iact==1) && (*safe>step)) return kBig;
   }
   Double_t phim = 0.5*(phi1+phi2);
   Double_t cm = TMath::Cos(phim);
   Double_t sm = TMath::Sin(phim);
   
   // compute distance to surface 
   return TGeoTubeSeg::DistToOutS(point,dir,fRmin,fRmax,fDz,c1,s1,c2,s2,cm,sm);
}
//-----------------------------------------------------------------------------
Double_t TGeoTubeSeg::DistToInS(Double_t *point, Double_t *dir, Double_t rmin, Double_t rmax, 
                                Double_t dz, Double_t c1, Double_t s1, Double_t c2, Double_t s2,
                                Double_t cm, Double_t sm, Double_t cdfi)
{
// static method to compute distance to arbitrary tube segment from outside point
   Double_t r2, cpsi;
   Double_t rsq = point[0]*point[0]+point[1]*point[1];
   // check Z planes
   Double_t xi, yi, zi;
   Double_t s = kBig;
   if (TMath::Abs(point[2])>dz) {
      if ((point[2]*dir[2])<0) {
         s = (TMath::Abs(point[2])-dz)/TMath::Abs(dir[2]);
         xi = point[0]+s*dir[0];
         yi = point[1]+s*dir[1];
         r2=xi*xi+yi*yi;
         if (((rmin*rmin)<=r2) && (r2<=(rmax*rmax))) {
            cpsi=(xi*cm+yi*sm)/TMath::Sqrt(r2);
            if (cpsi>=cdfi) return s;
         }
      }
   }      
   
   // check outer cyl. surface
   Double_t nsq=dir[0]*dir[0]+dir[1]*dir[1];
   if (TMath::Abs(nsq)<1E-10) return kBig;
   Double_t rdotn=point[0]*dir[0]+point[1]*dir[1];
   Double_t b,d;
   // only r>rmax has to be considered
   if (rsq>rmax*rmax) {
      TGeoTube::DistToTube(rsq, nsq, rdotn, rmax, b, d);
      if (d>0) {
         s=-b-d;
         if (s>0) {
            zi=point[2]+s*dir[2];
            if (TMath::Abs(zi)<=dz) {
               xi=point[0]+s*dir[0];
               yi=point[1]+s*dir[1];
               cpsi=(xi*cm+yi*sm)/rmax;
               if (cpsi>=cdfi) return s;
            }
         }
      }
   }         
   // check inner cylinder
   Double_t snxt=kBig;
   if (rmin>0) {
      TGeoTube::DistToTube(rsq, nsq, rdotn, rmin, b, d);
      if (d>0) {
         s=-b+d;
         if (s>0) {
            zi=point[2]+s*dir[2];
            if (TMath::Abs(zi)<=dz) {
               xi=point[0]+s*dir[0];
               yi=point[1]+s*dir[1];
               cpsi=(xi*cm+yi*sm)/rmin;
               if (cpsi>=cdfi) snxt=s;
            }
         }
      }
   }         
   // check phi planes
   Double_t un=dir[0]*s1-dir[1]*c1;
   if (un != 0) {
      s=(point[1]*c1-point[0]*s1)/un;
      if (s>=0) {
         zi=point[2]+s*dir[2];
         if (TMath::Abs(zi)<=dz) {
            xi=point[0]+s*dir[0];
            yi=point[1]+s*dir[1];
            r2=xi*xi+yi*yi;
            if ((rmin*rmin<=r2) && (r2<=rmax*rmax)) {
               if ((yi*cm-xi*sm)<=0) {
                  if (s<snxt) snxt=s;
               }
            }
         }            
      }
   }
   un=dir[0]*s2-dir[1]*c2;
   if (un != 0) {
      s=(point[1]*c2-point[0]*s2)/un;
      if (s>=0) {
         zi=point[2]+s*dir[2];
         if (TMath::Abs(zi)<=dz) {
            xi=point[0]+s*dir[0];
            yi=point[1]+s*dir[1];
            r2=xi*xi+yi*yi;
            if ((rmin*rmin<=r2) && (r2<=rmax*rmax)) {
               if ((yi*cm-xi*sm)>=0) {
                  if (s<snxt) snxt=s;
               }
            }
         }            
      }
   }
   return snxt;
}   
//-----------------------------------------------------------------------------
Double_t TGeoTubeSeg::DistToIn(Double_t *point, Double_t *dir, Int_t iact, Double_t step, Double_t *safe) const
{
// compute distance from outside point to surface of the tube segment
   // fist localize point w.r.t tube
   Double_t phi1 = fPhi1*kDegRad;
   Double_t phi2 = fPhi2*kDegRad;
   Double_t c1 = TMath::Cos(phi1);
   Double_t s1 = TMath::Sin(phi1);
   Double_t c2 = TMath::Cos(phi2);
   Double_t s2 = TMath::Sin(phi2);
   if (iact<3 && *safe) {
      *safe = SafetyS(point, kFALSE, fRmin, fRmax, fDz, c1,s1,c2,s2);
      if (iact==0) return kBig;
      if ((iact==1) && (step<=*safe)) return kBig;
   }
   Double_t fio = 0.5*(phi1+phi2);
   Double_t cm = TMath::Cos(fio);
   Double_t sm = TMath::Sin(fio);
   Double_t dfi = 0.5*(phi2-phi1);
   Double_t cdfi = TMath::Cos(dfi);
   
   // find distance to shape
   return TGeoTubeSeg::DistToInS(point, dir, fRmin, fRmax, fDz, c1, s1, c2, s2, cm, sm, cdfi);
}
//-----------------------------------------------------------------------------
Double_t TGeoTubeSeg::DistToSurf(Double_t * /*point*/, Double_t * /*dir*/) const
{
// computes the distance to next surface of the sphere along a ray
// starting from given point to the given direction.
   return kBig;
}
//-----------------------------------------------------------------------------
TGeoVolume *TGeoTubeSeg::Divide(TGeoVolume *voldiv, const char *divname, Int_t iaxis, Int_t ndiv, 
                             Double_t start, Double_t step) 
{
//--- Divide this tube segment shape belonging to volume "voldiv" into ndiv volumes
// called divname, from start position with the given step. Returns pointer
// to created division cell volume in case of Z divisions. For radialdivision 
// creates all volumes with different shapes and returns pointer to volume that
// was divided. In case a wrong division axis is supplied, returns pointer to 
// volume that was divided.
   TGeoShape *shape;           //--- shape to be created
   TGeoVolume *vol;            //--- division volume to be created
   TGeoVolumeMulti *vmulti;    //--- generic divided volume
   TGeoPatternFinder *finder;  //--- finder to be attached 
   TString opt = "";           //--- option to be attached
   Double_t dphi;
   Int_t id;
   Double_t end = start+ndiv*step;
   switch (iaxis) {
      case 1:  //---                 R division
         finder = new TGeoPatternCylR(voldiv, ndiv, start, end);
         vmulti = gGeoManager->MakeVolumeMulti(divname, voldiv->GetMedium());
         voldiv->SetFinder(finder);
         finder->SetDivIndex(voldiv->GetNdaughters());
         for (id=0; id<ndiv; id++) {
            shape = new TGeoTubeSeg(start+id*step, start+(id+1)*step, fDz, fPhi1, fPhi2);
            vol = new TGeoVolume(divname, shape, voldiv->GetMedium());
            vmulti->AddVolume(vol);
            opt = "R";
            voldiv->AddNodeOffset(vol, id, 0, opt.Data());
            ((TGeoNodeOffset*)voldiv->GetNodes()->At(voldiv->GetNdaughters()-1))->SetFinder(finder);
         }
         return vmulti;
      case 2:  //---                 Phi division
         dphi = fPhi2-fPhi1;
         if (dphi<0) dphi+=360.;
         if (step<=0) {step=dphi/ndiv; start=fPhi1; end=fPhi2;}
         finder = new TGeoPatternCylPhi(voldiv, ndiv, start, end);
         voldiv->SetFinder(finder);
         finder->SetDivIndex(voldiv->GetNdaughters());            
         shape = new TGeoTubeSeg(fRmin, fRmax, fDz, -step/2, step/2);
         vol = new TGeoVolume(divname, shape, voldiv->GetMedium());
         vmulti = gGeoManager->MakeVolumeMulti(divname, voldiv->GetMedium());
         vmulti->AddVolume(vol);
         opt = "Phi";
         for (id=0; id<ndiv; id++) {
            voldiv->AddNodeOffset(vol, id, start+id*step+step/2, opt.Data());
            ((TGeoNodeOffset*)voldiv->GetNodes()->At(voldiv->GetNdaughters()-1))->SetFinder(finder);
         }
         return vmulti;
      case 3: //---                  Z division
         finder = new TGeoPatternZ(voldiv, ndiv, start, end);
         voldiv->SetFinder(finder);
         finder->SetDivIndex(voldiv->GetNdaughters());            
         shape = new TGeoTubeSeg(fRmin, fRmax, step/2, fPhi1, fPhi2);
         vol = new TGeoVolume(divname, shape, voldiv->GetMedium());
         vmulti = gGeoManager->MakeVolumeMulti(divname, voldiv->GetMedium());
         vmulti->AddVolume(vol);
         opt = "Z";
         for (id=0; id<ndiv; id++) {
            voldiv->AddNodeOffset(vol, id, start+step/2+id*step, opt.Data());
            ((TGeoNodeOffset*)voldiv->GetNodes()->At(voldiv->GetNdaughters()-1))->SetFinder(finder);
         }
         return vmulti;
      default:
         Error("Divide", "Wrong axis type for division");
         return 0;            
   }
}

//-----------------------------------------------------------------------------
Double_t TGeoTubeSeg::GetAxisRange(Int_t iaxis, Double_t &xlo, Double_t &xhi) const
{
// Get range of shape for a given axis.
   xlo = 0;
   xhi = 0;
   Double_t dx = 0;
   switch (iaxis) {
      case 1:
         xlo = fRmin;
         xhi = fRmax;
         dx = xhi-xlo;
         return dx;
      case 2:
         xlo = fPhi1;
         xhi = fPhi2;
         dx = xhi-xlo;
         return dx;
      case 3:
         xlo = -fDz;
         xhi = fDz;
         dx = xhi-xlo;
         return dx;
   }
   return dx;
}         
            
//-----------------------------------------------------------------------------
void TGeoTubeSeg::GetBoundingCylinder(Double_t *param) const
{
//--- Fill vector param[4] with the bounding cylinder parameters. The order
// is the following : Rmin, Rmax, Phi1, Phi2
   param[0] = fRmin;
   param[0] *= param[0];
   param[1] = fRmax;
   param[1] *= param[1];
   param[2] = fPhi1;
   param[3] = fPhi2;
}
//-----------------------------------------------------------------------------
TGeoShape *TGeoTubeSeg::GetMakeRuntimeShape(TGeoShape *mother, TGeoMatrix * /*mat*/) const
{
// in case shape has some negative parameters, these has to be computed
// in order to fit the mother
   if (!TestBit(kGeoRunTimeShape)) return 0;
   if (!mother->TestBit(kGeoTube)) {
      Error("GetMakeRuntimeShape", "invalid mother");
      return 0;
   }
   Double_t rmin, rmax, dz;
   rmin = fRmin;
   rmax = fRmax;
   dz = fDz;
   if (fDz<0) dz=((TGeoTube*)mother)->GetDz();
   if (fRmin<0)
      rmin = ((TGeoTube*)mother)->GetRmin();
   if ((fRmax<0) || (fRmax<=fRmin))
      rmax = ((TGeoTube*)mother)->GetRmax();
   
   return (new TGeoTubeSeg(rmin, rmax, dz, fPhi1, fPhi2));
}
//-----------------------------------------------------------------------------
void TGeoTubeSeg::InspectShape() const
{
// print shape parameters
   printf("*** TGeoTubeSeg parameters ***n");
   printf("    Rmin = %11.5fn", fRmin);
   printf("    Rmax = %11.5fn", fRmax);
   printf("    dz   = %11.5fn", fDz);
   printf("    phi1 = %11.5fn", fPhi1);
   printf("    phi2 = %11.5fn", fPhi2);
   TGeoBBox::InspectShape();
}
//-----------------------------------------------------------------------------
void *TGeoTubeSeg::Make3DBuffer(const TGeoVolume *vol) const
{
   TVirtualGeoPainter *painter = gGeoManager->GetGeomPainter();
   if (!painter) return 0;
   return painter->MakeTubs3DBuffer(vol);
}
//-----------------------------------------------------------------------------
void TGeoTubeSeg::Paint(Option_t *option)
{
// paint this shape according to option
   TVirtualGeoPainter *painter = gGeoManager->GetGeomPainter();
   if (!painter) return;
   TGeoVolume *vol = gGeoManager->GetCurrentVolume();
   if (vol->GetShape() != (TGeoShape*)this) return;
   painter->PaintTubs(this, option);
}
//-----------------------------------------------------------------------------
void TGeoTubeSeg::PaintNext(TGeoHMatrix *glmat, Option_t *option)
{
// paint this shape according to option
   TVirtualGeoPainter *painter = gGeoManager->GetGeomPainter();
   if (!painter) return;
   painter->PaintTubs(this, option, glmat);
}
//-----------------------------------------------------------------------------
void TGeoTubeSeg::NextCrossing(TGeoParamCurve * /*c*/, Double_t * /*point*/) const
{
// computes next intersection point of curve c with this shape
}
//-----------------------------------------------------------------------------
Double_t TGeoTubeSeg::Safety(Double_t *point, Bool_t in) const
{
// computes the closest distance from given point to this shape, according
// to option. The matching point on the shape is stored in spoint.
   Double_t saf[4];
   Double_t rsq = point[0]*point[0]+point[1]*point[1];
   Double_t r = TMath::Sqrt(rsq);
   Double_t phi1 = fPhi1*kDegRad;
   Double_t phi2 = fPhi2*kDegRad;
   Double_t c1 = TMath::Cos(phi1);
   Double_t s1 = TMath::Sin(phi1);
   Double_t c2 = TMath::Cos(phi2);
   Double_t s2 = TMath::Sin(phi2);
   
   saf[0] = fDz-TMath::Abs(point[2]); // positive if inside
   saf[1] = r-fRmin;
   saf[2] = fRmax-r;
   saf[3] = TGeoShape::SafetyPhi(point,in,c1,s1,c2,s2);
   
   if (in) return saf[TMath::LocMin(4,saf)];

   for (Int_t i=0; i<4; i++) saf[i]=-saf[i];
   return saf[TMath::LocMax(4,saf)];
}

//-----------------------------------------------------------------------------
Double_t TGeoTubeSeg::SafetyS(Double_t *point, Bool_t in, Double_t rmin, Double_t rmax, Double_t dz, 
                              Double_t c1, Double_t s1, Double_t c2, Double_t s2, Int_t skipz)
{
// Static method to compute the closest distance from given point to this shape.
   Double_t saf[4];
   Double_t rsq = point[0]*point[0]+point[1]*point[1];
   Double_t r = TMath::Sqrt(rsq);
   
   switch (skipz) {
      case 1: // skip lower Z plane
         saf[0] = dz - point[2];
         break;
      case 2: // skip upper Z plane
         saf[0] = dz + point[2];
         break;
      case 3: // skip both
         saf[0] = kBig;
         break;
      default:
         saf[0] = dz-TMath::Abs(point[2]);         
   }
   saf[1] = r-rmin;
   saf[2] = rmax-r;
   saf[3] = TGeoShape::SafetyPhi(point,in,c1,s1,c2,s2);

   if (in)  return saf[TMath::LocMin(4,saf)];
   
   for (Int_t i=0; i<4; i++) saf[i]=-saf[i];
   return saf[TMath::LocMax(4,saf)];
}

//-----------------------------------------------------------------------------
void TGeoTubeSeg::SetTubsDimensions(Double_t rmin, Double_t rmax, Double_t dz,
                          Double_t phi1, Double_t phi2)
{
   fRmin = rmin;
   fRmax = rmax;
   fDz   = dz;
   fPhi1 = phi1;
   if (fPhi1 < 0) fPhi1+=360.;
   fPhi2 = phi2;
   while (fPhi2<=fPhi1) fPhi2+=360.;
   if (fPhi1==fPhi2) Error("SetTubsDimensions", "Invalid phi1=%g, phi2=%gn", fPhi1, fPhi2);
}   
//-----------------------------------------------------------------------------
void TGeoTubeSeg::SetDimensions(Double_t *param)
{
   Double_t rmin = param[0];
   Double_t rmax = param[1];
   Double_t dz   = param[2];
   Double_t phi1 = param[3];
   Double_t phi2 = param[4];
   SetTubsDimensions(rmin, rmax, dz, phi1, phi2);
}   
//-----------------------------------------------------------------------------
void TGeoTubeSeg::SetPoints(Double_t *buff) const
{
// create sphere mesh points
    Double_t dz;
    Int_t j, n;
    Double_t phi, phi1, phi2, dphi;
    phi1 = fPhi1;
    phi2 = fPhi2;
    if (phi2<phi1) phi2+=360.;
    n = gGeoManager->GetNsegments()+1;

    dphi = (phi2-phi1)/(n-1);
    dz   = fDz;

    if (buff) {
        Int_t indx = 0;

        for (j = 0; j < n; j++) {
            phi = (phi1+j*dphi)*kDegRad;
            buff[indx+6*n] = buff[indx] = fRmin * TMath::Cos(phi);
            indx++;
            buff[indx+6*n] = buff[indx] = fRmin * TMath::Sin(phi);
            indx++;
            buff[indx+6*n] = dz;
            buff[indx]     =-dz;
            indx++;
        }
        for (j = 0; j < n; j++) {
            phi = (phi1+j*dphi)*kDegRad;
            buff[indx+6*n] = buff[indx] = fRmax * TMath::Cos(phi);
            indx++;
            buff[indx+6*n] = buff[indx] = fRmax * TMath::Sin(phi);
            indx++;
            buff[indx+6*n]= dz;
            buff[indx]    =-dz;
            indx++;
        }
    }
}
//-----------------------------------------------------------------------------
void TGeoTubeSeg::SetPoints(Float_t *buff) const
{
// create sphere mesh points
    Double_t dz;
    Int_t j, n;
    Double_t phi, phi1, phi2, dphi;
    phi1 = fPhi1;
    phi2 = fPhi2;
    if (phi2<phi1) phi2+=360.;
    n = gGeoManager->GetNsegments()+1;

    dphi = (phi2-phi1)/(n-1);
    dz   = fDz;

    if (buff) {
        Int_t indx = 0;

        for (j = 0; j < n; j++) {
            phi = (phi1+j*dphi)*kDegRad;
            buff[indx+6*n] = buff[indx] = fRmin * TMath::Cos(phi);
            indx++;
            buff[indx+6*n] = buff[indx] = fRmin * TMath::Sin(phi);
            indx++;
            buff[indx+6*n] = dz;
            buff[indx]     =-dz;
            indx++;
        }
        for (j = 0; j < n; j++) {
            phi = (phi1+j*dphi)*kDegRad;
            buff[indx+6*n] = buff[indx] = fRmax * TMath::Cos(phi);
            indx++;
            buff[indx+6*n] = buff[indx] = fRmax * TMath::Sin(phi);
            indx++;
            buff[indx+6*n]= dz;
            buff[indx]    =-dz;
            indx++;
        }
    }
}
//-----------------------------------------------------------------------------
void TGeoTubeSeg::Sizeof3D() const
{
// fill size of this 3-D object
    TVirtualGeoPainter *painter = gGeoManager->GetGeomPainter();
    if (!painter) return;

    Int_t n = gGeoManager->GetNsegments()+1;
    Int_t numPoints = n*4;
    Int_t numSegs   = n*8;
    Int_t numPolys  = n*4-2;

    painter->AddSize3D(numPoints, numSegs, numPolys);
}


ClassImp(TGeoCtub)

TGeoCtub::TGeoCtub()
{
// default ctor
   fNlow[0] = fNlow[1] = fNhigh[0] = fNhigh[1] = 0.;
   fNlow[2] = -1;
   fNhigh[2] = 1;
}
//-----------------------------------------------------------------------------
TGeoCtub::TGeoCtub(Double_t rmin, Double_t rmax, Double_t dz, Double_t phi1, Double_t phi2,
                   Double_t lx, Double_t ly, Double_t lz, Double_t tx, Double_t ty, Double_t tz)
         :TGeoTubeSeg(rmin, rmax, dz, phi1, phi2)
{         
// ctor
   fNlow[0] = lx;
   fNlow[1] = ly;
   fNlow[2] = lz;
   fNhigh[0] = tx;
   fNhigh[1] = ty;
   fNhigh[2] = tz;
   SetBit(kGeoCtub);
   ComputeBBox();
}
//-----------------------------------------------------------------------------
TGeoCtub::TGeoCtub(const char *name, Double_t rmin, Double_t rmax, Double_t dz, Double_t phi1, Double_t phi2,
                   Double_t lx, Double_t ly, Double_t lz, Double_t tx, Double_t ty, Double_t tz)
         :TGeoTubeSeg(name, rmin, rmax, dz, phi1, phi2)
{         
// ctor
   fNlow[0] = lx;
   fNlow[1] = ly;
   fNlow[2] = lz;
   fNhigh[0] = tx;
   fNhigh[1] = ty;
   fNhigh[2] = tz;
   SetBit(kGeoCtub);
   ComputeBBox();
}
//-----------------------------------------------------------------------------
TGeoCtub::TGeoCtub(Double_t *params)
         :TGeoTubeSeg(0,0,0,0,0)
{
// ctor with parameters
   SetCtubDimensions(params[0], params[1], params[2], params[3], params[4], params[5],
                     params[6], params[7], params[8], params[9], params[10]);
   SetBit(kGeoCtub);
}
//-----------------------------------------------------------------------------
TGeoCtub::~TGeoCtub()
{
// dtor
}   
//-----------------------------------------------------------------------------
void TGeoCtub::ComputeBBox()
{
// compute minimum bounding box of the ctub
   TGeoTubeSeg::ComputeBBox();
   if ((fNlow[2]>-(1E-10)) || (fNhigh[2]<1E-10)) {
      Error("ComputeBBox", "Wrong definition of cut planes");
      return;
   }   
   Double_t xc=0, yc=0;
   Double_t zmin=0, zmax=0;
   Double_t z1;
   Double_t z[8];
   // check if nxy is in the phi range
   Double_t phi_low = TMath::ATan2(fNlow[1], fNlow[0]) *kRadDeg;
   Double_t phi_hi = TMath::ATan2(fNhigh[1], fNhigh[0]) *kRadDeg;
   Bool_t in_range_low = kFALSE;
   Bool_t in_range_hi = kFALSE;
   
   Int_t i;
   for (i=0; i<2; i++) {
      if (phi_low<0) phi_low+=360.;
      Double_t dphi = fPhi2 -fPhi1;
      if (dphi < 0) dphi+=360.;
      Double_t ddp = phi_low-fPhi1;
      if (ddp<0) ddp += 360.;
      if (ddp <= dphi) {
         xc = fRmin*TMath::Cos(phi_low*kDegRad);
         yc = fRmin*TMath::Sin(phi_low*kDegRad);
         z1 = GetZcoord(xc, yc, -fDz);
         xc = fRmax*TMath::Cos(phi_low*kDegRad);
         yc = fRmax*TMath::Sin(phi_low*kDegRad);
         z1 = TMath::Min(z1, GetZcoord(xc, yc, -fDz));
         if (in_range_low)
            zmin = TMath::Min(zmin, z1);
         else 
            zmin = z1;
         in_range_low = kTRUE;
      }     
      phi_low += 180;
      if (phi_low>360) phi_low-=360.;
   }   

   for (i=0; i<2; i++) {
      if (phi_hi<0) phi_hi+=360.;
      Double_t dphi = fPhi2 -fPhi1;
      if (dphi < 0) dphi+=360.;
      Double_t ddp = phi_hi-fPhi1;
      if (ddp<0) ddp += 360.;
      if (ddp <= dphi) {
         xc = fRmin*TMath::Cos(phi_hi*kDegRad);
         yc = fRmin*TMath::Sin(phi_hi*kDegRad);
         z1 = GetZcoord(xc, yc, fDz);
         xc = fRmax*TMath::Cos(phi_hi*kDegRad);
         yc = fRmax*TMath::Sin(phi_hi*kDegRad);
         z1 = TMath::Max(z1, GetZcoord(xc, yc, fDz));
         if (in_range_hi) 
            zmax = TMath::Max(zmax, z1);
         else 
            zmax = z1;   
         in_range_hi = kTRUE;
      }     
      phi_hi += 180;
      if (phi_hi>360) phi_hi-=360.;
   }   


   xc = fRmin*TMath::Cos(fPhi1*kDegRad);
   yc = fRmin*TMath::Sin(fPhi1*kDegRad);
   z[0] = GetZcoord(xc, yc, -fDz);
   z[4] = GetZcoord(xc, yc, fDz);

   xc = fRmin*TMath::Cos(fPhi2*kDegRad);
   yc = fRmin*TMath::Sin(fPhi2*kDegRad);
   z[1] = GetZcoord(xc, yc, -fDz);
   z[5] = GetZcoord(xc, yc, fDz);
   
   xc = fRmax*TMath::Cos(fPhi1*kDegRad);
   yc = fRmax*TMath::Sin(fPhi1*kDegRad);
   z[2] = GetZcoord(xc, yc, -fDz);
   z[6] = GetZcoord(xc, yc, fDz);

   xc = fRmax*TMath::Cos(fPhi2*kDegRad);
   yc = fRmax*TMath::Sin(fPhi2*kDegRad); 
   z[3] = GetZcoord(xc, yc, -fDz);
   z[7] = GetZcoord(xc, yc, fDz);
   
   z1 = z[TMath::LocMin(4, &z[0])];
   if (in_range_low)
      zmin = TMath::Min(zmin, z1);
   else 
      zmin = z1;
         
   z1 = z[TMath::LocMax(4, &z[4])+4];
   if (in_range_hi) 
      zmax = TMath::Max(zmax, z1);
   else 
      zmax = z1;
         
   fDZ = 0.5*(zmax-zmin);
   fOrigin[2] = 0.5*(zmax+zmin);
}
//-----------------------------------------------------------------------------
Bool_t TGeoCtub::Contains(Double_t *point) const
{
// check if point is contained in the cut tube
   // check the lower cut plane
   Double_t zin = point[0]*fNlow[0]+point[1]*fNlow[1]+(point[2]+fDz)*fNlow[2];
   if (zin>0) return kFALSE;
   // check the higher cut plane
   zin = point[0]*fNhigh[0]+point[1]*fNhigh[1]+(point[2]-fDz)*fNhigh[2];
   if (zin>0) return kFALSE;
   // check radius
   Double_t r2 = point[0]*point[0]+point[1]*point[1];
   if ((r2<fRmin*fRmin) || (r2>fRmax*fRmax)) return kFALSE;
   // check phi
   Double_t phi = TMath::ATan2(point[1], point[0]) * kRadDeg;
   if (phi < 0 ) phi+=360.;
   Double_t dphi = fPhi2 -fPhi1;
   Double_t ddp = phi-fPhi1;
   if (ddp<0) ddp += 360.;
//   if (ddp>360) ddp-=360;
   if (ddp > dphi) return kFALSE;
   return kTRUE;    
}

//-----------------------------------------------------------------------------
Double_t TGeoCtub::GetAxisRange(Int_t iaxis, Double_t &xlo, Double_t &xhi) const
{
// Get range of shape for a given axis.
   xlo = 0;
   xhi = 0;
   Double_t dx = 0;
   switch (iaxis) {
      case 1:
         xlo = fRmin;
         xhi = fRmax;
         dx = xhi-xlo;
         return dx;
      case 2:
         xlo = fPhi1;
         xhi = fPhi2;
         dx = xhi-xlo;
         return dx;
   }
   return dx;
}         
            
//-----------------------------------------------------------------------------
Double_t TGeoCtub::GetZcoord(Double_t xc, Double_t yc, Double_t zc) const
{
// compute real Z coordinate of a point belonging to either lower or 
// higher caps (z should be either +fDz or -fDz)
   Double_t newz = 0;
   if (zc<0) newz =  -fDz-(xc*fNlow[0]+yc*fNlow[1])/fNlow[2];
   else      newz = fDz-(xc*fNhigh[0]+yc*fNhigh[1])/fNhigh[2];
   return newz;
}   
//-----------------------------------------------------------------------------
Double_t TGeoCtub::DistToIn(Double_t *point, Double_t *dir, Int_t iact, Double_t step, Double_t *safe) const
{
// compute distance from outside point to surface of the cut tube
   if (iact<3 && safe) {
      *safe = Safety(point, kFALSE);
      if (iact==0) return kBig;
      if ((iact==1) && (step<=*safe)) return kBig;
   }
   Double_t saf[2];
   saf[0] = point[0]*fNlow[0] + point[1]*fNlow[1] + (fDz+point[2])*fNlow[2];
   saf[1] = point[0]*fNhigh[0] + point[1]*fNhigh[1] + (point[2]-fDz)*fNhigh[2];
   Double_t rsq = point[0]*point[0]+point[1]*point[1];
   Double_t r = TMath::Sqrt(rsq);
   Double_t c1=0,s1=0,c2=0,s2=0;
   Double_t fio=0, cfio=0, sfio=0, dfi=0, cdfi=0, cpsi=0;
   Double_t phi1 = fPhi1*kDegRad;
   Double_t phi2 = fPhi2*kDegRad;
   Bool_t tub = kFALSE;
   if (TMath::Abs(fPhi2-fPhi1-360.)<1E-8) tub = kTRUE;
   if (!tub) {
      c1   = TMath::Cos(phi1);
      c2   = TMath::Cos(phi2);
      s1   = TMath::Sin(phi1);
      s2   = TMath::Sin(phi2);
      fio  = 0.5*(phi1+phi2);
      cfio = TMath::Cos(fio);
      sfio = TMath::Sin(fio);
      dfi  = 0.5*(phi2-phi1);
      cdfi = TMath::Cos(dfi);
   }

   // find distance to shape
   Double_t r2;
   Double_t calf = dir[0]*fNlow[0]+dir[1]*fNlow[1]+dir[2]*fNlow[2];
   // check Z planes
   Double_t xi, yi, zi;
   Double_t s = kBig;
   if (saf[0]>0) {
      if (calf<0) {
         s = -saf[0]/calf;
         xi = point[0]+s*dir[0];
         yi = point[1]+s*dir[1];
         r2=xi*xi+yi*yi;
         if (((fRmin*fRmin)<=r2) && (r2<=(fRmax*fRmax))) {
            if (tub) return s;
            cpsi=(xi*cfio+yi*sfio)/TMath::Sqrt(r2);
            if (cpsi>=cdfi) return s;
         }
      }
   }      
   calf = dir[0]*fNhigh[0]+dir[1]*fNhigh[1]+dir[2]*fNhigh[2];   
   if (saf[1]>0) {
      if (calf<0) {
         s = -saf[1]/calf;
         xi = point[0]+s*dir[0];
         yi = point[1]+s*dir[1];
         r2=xi*xi+yi*yi;
         if (((fRmin*fRmin)<=r2) && (r2<=(fRmax*fRmax))) {
            if (tub) return s;
            cpsi=(xi*cfio+yi*sfio)/TMath::Sqrt(r2);
            if (cpsi>=cdfi) return s;
         }
      }
   }      
   
   // check outer cyl. surface
   Double_t nsq=dir[0]*dir[0]+dir[1]*dir[1];
   if (TMath::Abs(nsq)<1E-10) return kBig;
   Double_t rdotn=point[0]*dir[0]+point[1]*dir[1];
   Double_t b,d;
   // only r>fRmax has to be considered
   if (r>fRmax) {
      TGeoTube::DistToTube(rsq, nsq, rdotn, fRmax, b, d);
      if (d>0) {
         s=-b-d;
         if (s>0) {
            xi=point[0]+s*dir[0];
            yi=point[1]+s*dir[1];
            zi=point[2]+s*dir[2];
            if ((-xi*fNlow[0]-yi*fNlow[1]-(zi+fDz)*fNlow[2])>0) {
               if ((-xi*fNhigh[0]-yi*fNhigh[1]+(fDz-zi)*fNhigh[2])>0) {
                  if (tub) return s;
                  cpsi=(xi*cfio+yi*sfio)/fRmax;
                  if (cpsi>=cdfi) return s;
               }   
            }
         }
      }
   }         
   // check inner cylinder
   Double_t snxt=kBig;
   if (fRmin>0) {
      TGeoTube::DistToTube(rsq, nsq, rdotn, fRmin, b, d);
      if (d>0) {
         s=-b+d;
         if (s>0) {
            xi=point[0]+s*dir[0];
            yi=point[1]+s*dir[1];
            zi=point[2]+s*dir[2];
            if ((-xi*fNlow[0]-yi*fNlow[1]-(zi+fDz)*fNlow[2])>0) {
               if ((-xi*fNhigh[0]-yi*fNhigh[1]+(fDz-zi)*fNhigh[2])>0) {
                  if (tub) return s;                  
                  cpsi=(xi*cfio+yi*sfio)/fRmin;
                  if (cpsi>=cdfi) snxt=s;
               }   
            }
         }
      }
   }         
   // check phi planes
   if (tub) return snxt;
   Double_t un=dir[0]*s1-dir[1]*c1;
   if (un != 0) {
      s=(point[1]*c1-point[0]*s1)/un;
      if (s>=0) {
         xi=point[0]+s*dir[0];
         yi=point[1]+s*dir[1];
         zi=point[2]+s*dir[2];
         if ((-xi*fNlow[0]-yi*fNlow[1]-(zi+fDz)*fNlow[2])>0) {
            if ((-xi*fNhigh[0]-yi*fNhigh[1]+(fDz-zi)*fNhigh[2])>0) {
               r2=xi*xi+yi*yi;
               if ((fRmin*fRmin<=r2) && (r2<=fRmax*fRmax)) {
                  if ((yi*cfio-xi*sfio)<=0) {
                     if (s<snxt) snxt=s;
                  }
               }
            }            
         }
      }
   }   
   un=dir[0]*s2-dir[1]*c2;
   if (un != 0) {
      s=(point[1]*c2-point[0]*s2)/un;
      if (s>=0) {
         xi=point[0]+s*dir[0];
         yi=point[1]+s*dir[1];
         zi=point[2]+s*dir[2];
         if ((-xi*fNlow[0]-yi*fNlow[1]-(zi+fDz)*fNlow[2])>0) {
            if ((-xi*fNhigh[0]-yi*fNhigh[1]+(fDz-zi)*fNhigh[2])>0) {
               r2=xi*xi+yi*yi;
               if ((fRmin*fRmin<=r2) && (r2<=fRmax*fRmax)) {
                  if ((yi*cfio-xi*sfio)>=0) {
                     if (s<snxt) snxt=s;
                  }
               }
            }            
         }
      }   
   }
   return snxt;
}   
//-----------------------------------------------------------------------------
Double_t TGeoCtub::DistToOut(Double_t *point, Double_t *dir, Int_t iact, Double_t step, Double_t *safe) const
{
// compute distance from inside point to surface of the cut tube
   if (iact<3 && safe) *safe = Safety(point, kTRUE);
   if (iact==0) return kBig;
   if ((iact==1) && (*safe>step)) return kBig;
   Double_t rsq = point[0]*point[0]+point[1]*point[1];
   Double_t c1=0,s1=0,c2=0,s2=0,cm=0,sm=0,phim=0;
   Double_t phi1 = fPhi1*kDegRad;
   Double_t phi2 = fPhi2*kDegRad;
   Bool_t tub = kFALSE;
   if (TMath::Abs(fPhi2-fPhi1-360.)<1E-8) tub = kTRUE;
   if (!tub) {
      if (phi2<phi1) phi2+=2.*TMath::Pi();
      phim = 0.5*(phi1+phi2);
      c1 = TMath::Cos(phi1);
      c2 = TMath::Cos(phi2);
      s1 = TMath::Sin(phi1);
      s2 = TMath::Sin(phi2);
      cm = TMath::Cos(phim);
      sm = TMath::Sin(phim);
   }
   // compute distance to surface 
   // Do Z
   Double_t sz = kBig;
   Double_t saf[2];
   saf[0] = -point[0]*fNlow[0] - point[1]*fNlow[1] - (fDz+point[2])*fNlow[2];
   saf[1] = -point[0]*fNhigh[0] - point[1]*fNhigh[1] + (fDz-point[2])*fNhigh[2];
   Double_t calf = dir[0]*fNlow[0]+dir[1]*fNlow[1]+dir[2]*fNlow[2];
   if (calf>0) sz = saf[0]/calf;
   
   Double_t sz1=kBig;
   calf = dir[0]*fNhigh[0]+dir[1]*fNhigh[1]+dir[2]*fNhigh[2];   
   if (calf>0) {
      sz1 = saf[1]/calf;
      if (sz1<sz) sz = sz1;
   }
         
   // Do R
   Double_t nsq=dir[0]*dir[0]+dir[1]*dir[1];  
   // track parralel to Z
   if (TMath::Abs(nsq)<1E-10) return sz;
   Double_t rdotn=point[0]*dir[0]+point[1]*dir[1];  
   Double_t sr=kBig;
   Double_t b, d;
   Bool_t skip_outer = kFALSE;
   // inner cylinder
   if (fRmin>1E-10) {
      TGeoTube::DistToTube(rsq, nsq, rdotn, fRmin, b, d);
      if (d>0) {
         sr=-b-d;
         if (sr>0) skip_outer = kTRUE;
      }
   }
   // outer cylinder
   if (!skip_outer) {
      TGeoTube::DistToTube(rsq, nsq, rdotn, fRmax, b, d);
      if (d>0) {
         sr=-b+d;
         if (sr<0) sr=kBig;
      } else {
         Error("DistToOut", "cannot get outside !");
      }      
   }
   // phi planes
   Double_t sfmin = kBig;
   if (!tub) sfmin=DistToPhiMin(point, dir, s1, c1, s2, c2, sm, cm);;
   return TMath::Min(TMath::Min(sz,sr), sfmin);      
}   
//-----------------------------------------------------------------------------
Double_t TGeoCtub::DistToSurf(Double_t * /*point*/, Double_t * /*dir*/) const
{
// computes the distance to next surface of the sphere along a ray
// starting from given point to the given direction.
   return kBig;
}
//-----------------------------------------------------------------------------
TGeoVolume *TGeoCtub::Divide(TGeoVolume * /*voldiv*/, const char * /*divname*/, Int_t /*iaxis*/, Int_t /*ndiv*/, 
                             Double_t /*start*/, Double_t /*step*/) 
{
   Warning("Divide", "Division of a cut tube not implemented");
   return 0;
}   

//-----------------------------------------------------------------------------
TGeoShape *TGeoCtub::GetMakeRuntimeShape(TGeoShape *mother, TGeoMatrix * /*mat*/) const
{
// in case shape has some negative parameters, these has to be computed
// in order to fit the mother
   if (!TestBit(kGeoRunTimeShape)) return 0;
   if (!mother->TestBit(kGeoTube)) {
      Error("GetMakeRuntimeShape", "invalid mother");
      return 0;
   }
   Double_t rmin, rmax, dz;
   rmin = fRmin;
   rmax = fRmax;
   dz = fDz;
   if (fDz<0) dz=((TGeoTube*)mother)->GetDz();
   if (fRmin<0)
      rmin = ((TGeoTube*)mother)->GetRmin();
   if ((fRmax<0) || (fRmax<=fRmin))
      rmax = ((TGeoTube*)mother)->GetRmax();
   
   return (new TGeoCtub(rmin, rmax, dz, fPhi1, fPhi2, fNlow[0], fNlow[1], fNlow[2], 
                        fNhigh[0], fNhigh[1], fNhigh[2]));
}
//-----------------------------------------------------------------------------
void TGeoCtub::InspectShape() const
{
// print shape parameters
   printf("*** TGeoCtub parameters ***n");
   printf("    lx = %11.5fn", fNlow[0]);
   printf("    ly = %11.5fn", fNlow[1]);
   printf("    lz = %11.5fn", fNlow[2]);
   printf("    tx = %11.5fn", fNhigh[0]);
   printf("    ty = %11.5fn", fNhigh[1]);
   printf("    tz = %11.5fn", fNhigh[2]);
   TGeoTubeSeg::InspectShape();
}
//-----------------------------------------------------------------------------
void TGeoCtub::NextCrossing(TGeoParamCurve * /*c*/, Double_t * /*point*/) const
{
// computes next intersection point of curve c with this shape
}

//-----------------------------------------------------------------------------
Double_t TGeoCtub::Safety(Double_t *point, Bool_t in) const
{
// computes the closest distance from given point to this shape, according
// to option. The matching point on the shape is stored in spoint.
   Double_t saf[5];
   Double_t rsq = point[0]*point[0]+point[1]*point[1];
   Double_t r = TMath::Sqrt(rsq);
   Bool_t isseg = kTRUE;
   if (TMath::Abs(fPhi2-fPhi1-360.)<1E-8) isseg=kFALSE;
   
   saf[0] = -point[0]*fNlow[0] - point[1]*fNlow[1] - (fDz+point[2])*fNlow[2];
   saf[1] = -point[0]*fNhigh[0] - point[1]*fNhigh[1] + (fDz-point[2])*fNhigh[2];
   saf[2] = (fRmin<1E-10 && !isseg)?kBig:(r-fRmin);
   saf[3] = fRmax-r;
   if (isseg) {
      Double_t phi1 = fPhi1*kDegRad;
      Double_t phi2 = fPhi2*kDegRad;
      Double_t c1 = TMath::Cos(phi1);
      Double_t s1 = TMath::Sin(phi1);
      Double_t c2 = TMath::Cos(phi2);
      Double_t s2 = TMath::Sin(phi2);
   
      saf[4] =  TGeoShape::SafetyPhi(point, in, c1,s1,c2,s2);
   } else {
      saf[4] = kBig;
   }   

   if (in) return saf[TMath::LocMin(5,saf)];
   for (Int_t i=0; i<5; i++) saf[i]=-saf[i];
   return saf[TMath::LocMax(5,saf)];
}
//-----------------------------------------------------------------------------
void TGeoCtub::SetCtubDimensions(Double_t rmin, Double_t rmax, Double_t dz, Double_t phi1, Double_t phi2,
                   Double_t lx, Double_t ly, Double_t lz, Double_t tx, Double_t ty, Double_t tz)
{
// set dimensions of a cut tube
   SetTubsDimensions(rmin, rmax, dz, phi1, phi2);
   fNlow[0] = lx;
   fNlow[1] = ly;
   fNlow[2] = lz;
   fNhigh[0] = tx;
   fNhigh[1] = ty;
   fNhigh[2] = tz;
   ComputeBBox();
}
//-----------------------------------------------------------------------------
void TGeoCtub::SetDimensions(Double_t *param)
{
   SetCtubDimensions(param[0], param[1], param[2], param[3], param[4], param[5],
                     param[6], param[7], param[8], param[9], param[10]);
   ComputeBBox();
}
//-----------------------------------------------------------------------------
void TGeoCtub::SetPoints(Double_t *buff) const
{
// create sphere mesh points
    Double_t dz;
    Int_t j, n;
    Double_t phi, phi1, phi2, dphi;
    phi1 = fPhi1;
    phi2 = fPhi2;
    if (phi2<phi1) phi2+=360.;
    n = gGeoManager->GetNsegments()+1;

    dphi = (phi2-phi1)/(n-1);
    dz   = fDz;

    if (buff) {
        Int_t indx = 0;

        for (j = 0; j < n; j++) {
            phi = (phi1+j*dphi)*kDegRad;
            buff[indx+6*n] = buff[indx] = fRmin * TMath::Cos(phi);
            indx++;
            buff[indx+6*n] = buff[indx] = fRmin * TMath::Sin(phi);
            indx++;
            buff[indx+6*n] = GetZcoord(buff[indx-2], buff[indx-1], dz);
            buff[indx]     = GetZcoord(buff[indx-2], buff[indx-1], -dz);
            indx++;
        }
        for (j = 0; j < n; j++) {
            phi = (phi1+j*dphi)*kDegRad;
            buff[indx+6*n] = buff[indx] = fRmax * TMath::Cos(phi);
            indx++;
            buff[indx+6*n] = buff[indx] = fRmax * TMath::Sin(phi);
            indx++;
            buff[indx+6*n]= GetZcoord(buff[indx-2], buff[indx-1], dz);
            buff[indx]    = GetZcoord(buff[indx-2], buff[indx-1], -dz);
            indx++;
        }
    }
}
//-----------------------------------------------------------------------------
void TGeoCtub::SetPoints(Float_t *buff) const
{
// create sphere mesh points
    Double_t dz;
    Int_t j, n;
    Double_t phi, phi1, phi2, dphi;
    phi1 = fPhi1;
    phi2 = fPhi2;
    if (phi2<phi1) phi2+=360.;
    n = gGeoManager->GetNsegments()+1;

    dphi = (phi2-phi1)/(n-1);
    dz   = fDz;

    if (buff) {
        Int_t indx = 0;

        for (j = 0; j < n; j++) {
            phi = (phi1+j*dphi)*kDegRad;
            buff[indx+6*n] = buff[indx] = fRmin * TMath::Cos(phi);
            indx++;
            buff[indx+6*n] = buff[indx] = fRmin * TMath::Sin(phi);
            indx++;
            buff[indx+6*n] = GetZcoord(buff[indx-2], buff[indx-1], dz);
            buff[indx]     = GetZcoord(buff[indx-2], buff[indx-1], -dz);
            indx++;
        }
        for (j = 0; j < n; j++) {
            phi = (phi1+j*dphi)*kDegRad;
            buff[indx+6*n] = buff[indx] = fRmax * TMath::Cos(phi);
            indx++;
            buff[indx+6*n] = buff[indx] = fRmax * TMath::Sin(phi);
            indx++;
            buff[indx+6*n]= GetZcoord(buff[indx-2], buff[indx-1], dz);
            buff[indx]    = GetZcoord(buff[indx-2], buff[indx-1], -dz);
            indx++;
        }
    }
}


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