TGeoEltu.cxx

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// @(#)root/geom:$Id$
// Author: Mihaela Gheata   05/06/02
 
/*************************************************************************
 * 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.             *
 *************************************************************************/
 
/** \class TGeoEltu
\ingroup Tubes
 
An elliptical tube is defined by the two semi-axes `A` and `B`. It ranges
from `-dZ` to `+dZ` as all other tubes:
 
~~~ {.cpp}
TGeoEltu(Double_t a,Double_t b,Double_t dz);
~~~
 
Begin_Macro
{
   TCanvas *c = new TCanvas("c", "c",0,0,600,600);
   new TGeoManager("eltu", "poza6");
   TGeoMaterial *mat = new TGeoMaterial("Al", 26.98,13,2.7);
   TGeoMedium *med = new TGeoMedium("MED",1,mat);
   TGeoVolume *top = gGeoManager->MakeBox("TOP",med,100,100,100);
   gGeoManager->SetTopVolume(top);
   TGeoVolume *vol = gGeoManager->MakeEltu("ELTU",med, 30,10,40);
   top->AddNode(vol,1);
   gGeoManager->CloseGeometry();
   gGeoManager->SetNsegments(50);
   top->Draw();
   TView *view = gPad->GetView();
   if (view) view->ShowAxis();
}
End_Macro
*/
 
#include <iostream>
 
#include "TGeoManager.h"
#include "TGeoVolume.h"
#include "TGeoEltu.h"
#include "TBuffer3D.h"
#include "TBuffer3DTypes.h"
#include "TMath.h"
 
ClassImp(TGeoEltu);
 
////////////////////////////////////////////////////////////////////////////////
/// Dummy constructor
 
TGeoEltu::TGeoEltu()
{
   SetShapeBit(TGeoShape::kGeoEltu);
}
 
////////////////////////////////////////////////////////////////////////////////
/// Default constructor specifying X and Y semiaxis length
 
TGeoEltu::TGeoEltu(Double_t a, Double_t b, Double_t dz) : TGeoTube(0, 0, 0)
{
   SetShapeBit(TGeoShape::kGeoEltu);
   SetEltuDimensions(a, b, dz);
   ComputeBBox();
}
 
////////////////////////////////////////////////////////////////////////////////
/// Default constructor specifying X and Y semiaxis length
 
TGeoEltu::TGeoEltu(const char *name, Double_t a, Double_t b, Double_t dz) : TGeoTube(name, 0., b, dz)
{
   SetName(name);
   SetShapeBit(TGeoShape::kGeoEltu);
   SetEltuDimensions(a, b, dz);
   ComputeBBox();
}
 
////////////////////////////////////////////////////////////////////////////////
/// Default constructor specifying minimum and maximum radius
/// param[0] =  A
/// param[1] =  B
/// param[2] = dz
 
TGeoEltu::TGeoEltu(Double_t *param)
{
   SetShapeBit(TGeoShape::kGeoEltu);
   SetDimensions(param);
   ComputeBBox();
}
 
////////////////////////////////////////////////////////////////////////////////
/// destructor
 
TGeoEltu::~TGeoEltu() {}
 
////////////////////////////////////////////////////////////////////////////////
/// Computes capacity of the shape in [length^3]
 
Double_t TGeoEltu::Capacity() const
{
   Double_t capacity = 2. * TMath::Pi() * fDz * fRmin * fRmax;
   return capacity;
}
 
////////////////////////////////////////////////////////////////////////////////
/// compute bounding box of the tube
 
void TGeoEltu::ComputeBBox()
{
   fDX = fRmin;
   fDY = fRmax;
   fDZ = fDz;
}
 
////////////////////////////////////////////////////////////////////////////////
/// Compute normal to closest surface from POINT.
 
void TGeoEltu::ComputeNormal(const Double_t *point, const Double_t *dir, Double_t *norm) const
{
   Double_t a = fRmin;
   Double_t b = fRmax;
   Double_t safr = TMath::Abs(TMath::Sqrt(point[0] * point[0] / (a * a) + point[1] * point[1] / (b * b)) - 1.);
   safr *= TMath::Min(a, b);
   Double_t safz = TMath::Abs(fDz - TMath::Abs(point[2]));
   if (safz < safr) {
      norm[0] = norm[1] = 0;
      norm[2] = TMath::Sign(1., dir[2]);
      return;
   }
   norm[2] = 0.;
   norm[0] = point[0] * b * b;
   norm[1] = point[1] * a * a;
   TMath::Normalize(norm);
}
 
////////////////////////////////////////////////////////////////////////////////
/// test if point is inside the elliptical tube
 
Bool_t TGeoEltu::Contains(const Double_t *point) const
{
   if (TMath::Abs(point[2]) > fDz)
      return kFALSE;
   Double_t r2 = (point[0] * point[0]) / (fRmin * fRmin) + (point[1] * point[1]) / (fRmax * fRmax);
   if (r2 > 1.)
      return kFALSE;
   return kTRUE;
}
 
////////////////////////////////////////////////////////////////////////////////
/// compute closest distance from point px,py to each vertex
 
Int_t TGeoEltu::DistancetoPrimitive(Int_t px, Int_t py)
{
   Int_t n = gGeoManager->GetNsegments();
   const Int_t numPoints = 4 * n;
   return ShapeDistancetoPrimitive(numPoints, px, py);
}
 
////////////////////////////////////////////////////////////////////////////////
/// compute distance from inside point to surface of the tube
 
Double_t
TGeoEltu::DistFromInside(const Double_t *point, const Double_t *dir, Int_t iact, Double_t step, Double_t *safe) const
{
   Double_t a2 = fRmin * fRmin;
   Double_t b2 = fRmax * fRmax;
   Double_t safz1 = fDz - point[2];
   Double_t safz2 = fDz + point[2];
 
   if (iact < 3 && safe) {
      Double_t x0 = TMath::Abs(point[0]);
      Double_t y0 = TMath::Abs(point[1]);
      Double_t x1 = x0;
      Double_t y1 = TMath::Sqrt((fRmin - x0) * (fRmin + x0)) * fRmax / fRmin;
      Double_t y2 = y0;
      Double_t x2 = TMath::Sqrt((fRmax - y0) * (fRmax + y0)) * fRmin / fRmax;
      Double_t d1 = (x1 - x0) * (x1 - x0) + (y1 - y0) * (y1 - y0);
      Double_t d2 = (x2 - x0) * (x2 - x0) + (y2 - y0) * (y2 - y0);
      Double_t x3, y3;
 
      Double_t safz = TMath::Min(safz1, safz2);
      for (Int_t i = 0; i < 8; i++) {
         if (fRmax < fRmin) {
            x3 = 0.5 * (x1 + x2);
            y3 = TMath::Sqrt((fRmin - x3) * (fRmin + x3)) * fRmax / fRmin;
            ;
         } else {
            y3 = 0.5 * (y1 + y2);
            x3 = TMath::Sqrt((fRmax - y3) * (fRmax + y3)) * fRmin / fRmax;
         }
         if (d1 < d2) {
            x2 = x3;
            y2 = y3;
            d2 = (x2 - x0) * (x2 - x0) + (y2 - y0) * (y2 - y0);
         } else {
            x1 = x3;
            y1 = y3;
            d1 = (x1 - x0) * (x1 - x0) + (y1 - y0) * (y1 - y0);
         }
      }
      Double_t safr = TMath::Sqrt(d1) - 1.0E-3;
      *safe = TMath::Min(safz, safr);
      if (iact == 0)
         return TGeoShape::Big();
      if ((iact == 1) && (*safe > step))
         return TGeoShape::Big();
   }
   // compute distance to surface
   // Do Z
   Double_t snxt = TGeoShape::Big();
   if (dir[2] > 0) {
      snxt = safz1 / dir[2];
   } else {
      if (dir[2] < 0)
         snxt = -safz2 / dir[2];
   }
   Double_t sz = snxt;
   Double_t xz = point[0] + dir[0] * sz;
   Double_t yz = point[1] + dir[1] * sz;
   if ((xz * xz / a2 + yz * yz / b2) <= 1)
      return snxt;
   // do elliptical surface
   Double_t tolerance = TGeoShape::Tolerance();
   Double_t u = dir[0] * dir[0] * b2 + dir[1] * dir[1] * a2;
   Double_t v = point[0] * dir[0] * b2 + point[1] * dir[1] * a2;
   Double_t w = point[0] * point[0] * b2 + point[1] * point[1] * a2 - a2 * b2;
   Double_t d = v * v - u * w;
   if (d < 0 || TGeoShape::IsSameWithinTolerance(u, 0))
      return tolerance;
   Double_t sd = TMath::Sqrt(d);
   snxt = (-v + sd) / u;
 
   if (snxt < 0)
      return tolerance;
   return snxt;
}
 
////////////////////////////////////////////////////////////////////////////////
/// compute distance from outside point to surface of the tube and safe distance
 
Double_t
TGeoEltu::DistFromOutside(const Double_t *point, const Double_t *dir, Int_t iact, Double_t step, Double_t *safe) const
{
   Double_t safz = TMath::Abs(point[2]) - fDz;
   Double_t a2 = fRmin * fRmin;
   Double_t b2 = fRmax * fRmax;
   if (iact < 3 && safe) {
      Double_t x0 = TMath::Abs(point[0]);
      Double_t y0 = TMath::Abs(point[1]);
      *safe = 0.;
      if ((x0 * x0 / a2 + y0 * y0 / b2) >= 1) {
         Double_t phi1 = 0;
         Double_t phi2 = 0.5 * TMath::Pi();
         Double_t phi3;
         Double_t x3 = 0., y3 = 0., d;
         for (Int_t i = 0; i < 10; i++) {
            phi3 = (phi1 + phi2) * 0.5;
            x3 = fRmin * TMath::Cos(phi3);
            y3 = fRmax * TMath::Sin(phi3);
            d = y3 * a2 * (x0 - x3) - x3 * b2 * (y0 - y3);
            if (d < 0)
               phi1 = phi3;
            else
               phi2 = phi3;
         }
         *safe = TMath::Sqrt((x0 - x3) * (x0 - x3) + (y0 - y3) * (y0 - y3));
      }
      if (safz > 0) {
         *safe = TMath::Sqrt((*safe) * (*safe) + safz * safz);
      }
      if (iact == 0)
         return TGeoShape::Big();
      if ((iact == 1) && (step < *safe))
         return TGeoShape::Big();
   }
   // compute vector distance
   Double_t zi, tau;
   Double_t epsil = 10. * TGeoShape::Tolerance();
   if (safz > -epsil) {
      // point beyond the z limit (up or down)
      // Check if direction is outgoing
      if (point[2] * dir[2] > 0)
         return TGeoShape::Big();
      // Check if direction is perpendicular to Z axis
      if (TGeoShape::IsSameWithinTolerance(dir[2], 0))
         return TGeoShape::Big();
      // select +z or -z depending on the side of the point
      zi = (point[2] > 0) ? fDz : -fDz;
      // Distance to zi plane position
      tau = (zi - point[2]) / dir[2];
      // Extrapolated coordinates at the z position of the end plane.
      Double_t xz = point[0] + dir[0] * tau;
      Double_t yz = point[1] + dir[1] * tau;
      if ((xz * xz / a2 + yz * yz / b2) < 1)
         return tau;
   }
 
   // Check if the bounding box is crossed within the requested distance
   Double_t sdist = TGeoBBox::DistFromOutside(point, dir, fDX, fDY, fDZ, fOrigin, step);
   if (sdist >= step)
      return TGeoShape::Big();
   Double_t u = dir[0] * dir[0] * b2 + dir[1] * dir[1] * a2; // positive
   if (TGeoShape::IsSameWithinTolerance(u, 0))
      return TGeoShape::Big();
   Double_t v = point[0] * dir[0] * b2 + point[1] * dir[1] * a2;
   Double_t w = point[0] * point[0] * b2 + point[1] * point[1] * a2 - a2 * b2;
   Double_t d = v * v - u * w;
   if (d < 0)
      return TGeoShape::Big();
   Double_t dsq = TMath::Sqrt(d);
   // Biggest solution - if negative, or very close to boundary
   // no crossing (just exiting, no re-entering possible)
   tau = (-v + dsq) / u;
   if (tau < epsil)
      return TGeoShape::Big();
   // only entering crossing must be considered (smallest)
   tau = (-v - dsq) / u;
   zi = point[2] + tau * dir[2];
   // If the crossing point is not in the Z range, there is no crossing
   if ((TMath::Abs(zi) - fDz) > 0)
      return TGeoShape::Big();
   // crossing is backwards (point inside the ellipse) in Z range
   if (tau < 0)
      return 0.;
   // Point is outside and crossing the elliptical tube in Z range
   return tau;
}
 
////////////////////////////////////////////////////////////////////////////////
/// Divide the shape along one axis.
 
TGeoVolume *TGeoEltu::Divide(TGeoVolume * /*voldiv*/, const char * /*divname*/, Int_t /*iaxis*/, Int_t /*ndiv*/,
                             Double_t /*start*/, Double_t /*step*/)
{
   Error("Divide", "Elliptical tubes divisions not implemented");
   return nullptr;
}
 
////////////////////////////////////////////////////////////////////////////////
/// Fill vector param[4] with the bounding cylinder parameters. The order
/// is the following : Rmin, Rmax, Phi1, Phi2
 
void TGeoEltu::GetBoundingCylinder(Double_t *param) const
{
   param[0] = 0.;                       // Rmin
   param[1] = TMath::Max(fRmin, fRmax); // Rmax
   param[1] *= param[1];
   param[2] = 0.;   // Phi1
   param[3] = 360.; // Phi2
}
 
////////////////////////////////////////////////////////////////////////////////
/// in case shape has some negative parameters, these has to be computed
/// in order to fit the mother
 
TGeoShape *TGeoEltu::GetMakeRuntimeShape(TGeoShape *mother, TGeoMatrix * /*mat*/) const
{
   if (!TestShapeBit(kGeoRunTimeShape))
      return nullptr;
   if (!mother->TestShapeBit(kGeoEltu)) {
      Error("GetMakeRuntimeShape", "invalid mother");
      return nullptr;
   }
   Double_t a, b, dz;
   a = fRmin;
   b = fRmax;
   dz = fDz;
   if (fDz < 0)
      dz = ((TGeoEltu *)mother)->GetDz();
   if (fRmin < 0)
      a = ((TGeoEltu *)mother)->GetA();
   if (fRmax < 0)
      a = ((TGeoEltu *)mother)->GetB();
 
   return (new TGeoEltu(a, b, dz));
}
 
////////////////////////////////////////////////////////////////////////////////
/// print shape parameters
 
void TGeoEltu::InspectShape() const
{
   printf("*** Shape %s: TGeoEltu ***\n", GetName());
   printf("    A    = %11.5f\n", fRmin);
   printf("    B    = %11.5f\n", fRmax);
   printf("    dz   = %11.5f\n", fDz);
   printf(" Bounding box:\n");
   TGeoBBox::InspectShape();
}
 
////////////////////////////////////////////////////////////////////////////////
/// 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 TGeoEltu::Safety(const Double_t *point, Bool_t /*in*/) const
{
   Double_t x0 = TMath::Abs(point[0]);
   Double_t y0 = TMath::Abs(point[1]);
   Double_t x1, y1, dx, dy;
   Double_t safr, safz;
   Double_t onepls = 1. + TGeoShape::Tolerance();
   Double_t onemin = 1. - TGeoShape::Tolerance();
   Double_t sqdist = x0 * x0 / (fRmin * fRmin) + y0 * y0 / (fRmax * fRmax);
   Bool_t in = kTRUE;
   if (sqdist > onepls)
      in = kFALSE;
   else if (sqdist < onemin)
      in = kTRUE;
   else
      return 0.;
 
   if (in) {
      x1 = fRmin * TMath::Sqrt(1. - (y0 * y0) / (fRmax * fRmax));
      y1 = fRmax * TMath::Sqrt(1. - (x0 * x0) / (fRmin * fRmin));
      dx = x1 - x0;
      dy = y1 - y0;
      if (TMath::Abs(dx) < TGeoShape::Tolerance())
         return 0;
      safr = dx * dy / TMath::Sqrt(dx * dx + dy * dy);
      safz = fDz - TMath::Abs(point[2]);
      return TMath::Min(safr, safz);
   }
 
   if (TMath::Abs(x0) < TGeoShape::Tolerance()) {
      safr = y0 - fRmax;
   } else {
      if (TMath::Abs(y0) < TGeoShape::Tolerance()) {
         safr = x0 - fRmin;
      } else {
         Double_t f = fRmin * fRmax / TMath::Sqrt(x0 * x0 * fRmax * fRmax + y0 * y0 * fRmin * fRmin);
         x1 = f * x0;
         y1 = f * y0;
         dx = x0 - x1;
         dy = y0 - y1;
         Double_t ast = fRmin * y1 / fRmax;
         Double_t bct = fRmax * x1 / fRmin;
         Double_t d = TMath::Sqrt(bct * bct + ast * ast);
         safr = (dx * bct + dy * ast) / d;
      }
   }
   safz = TMath::Abs(point[2]) - fDz;
   return TMath::Max(safr, safz);
}
 
////////////////////////////////////////////////////////////////////////////////
/// Save a primitive as a C++ statement(s) on output stream "out".
 
void TGeoEltu::SavePrimitive(std::ostream &out, Option_t * /*option*/ /*= ""*/)
{
   if (TObject::TestBit(kGeoSavePrimitive))
      return;
   out << "   // Shape: " << GetName() << " type: " << ClassName() << std::endl;
   out << "   a  = " << fRmin << ";" << std::endl;
   out << "   b  = " << fRmax << ";" << std::endl;
   out << "   dz = " << fDz << ";" << std::endl;
   out << "   TGeoShape *" << GetPointerName() << " = new TGeoEltu(\"" << GetName() << "\",a,b,dz);" << std::endl;
   TObject::SetBit(TGeoShape::kGeoSavePrimitive);
}
 
////////////////////////////////////////////////////////////////////////////////
/// Set dimensions of the elliptical tube.
 
void TGeoEltu::SetEltuDimensions(Double_t a, Double_t b, Double_t dz)
{
   if ((a <= 0) || (b < 0) || (dz < 0)) {
      SetShapeBit(kGeoRunTimeShape);
   }
   fRmin = a;
   fRmax = b;
   fDz = dz;
}
 
////////////////////////////////////////////////////////////////////////////////
/// Set shape dimensions starting from an array.
 
void TGeoEltu::SetDimensions(Double_t *param)
{
   Double_t a = param[0];
   Double_t b = param[1];
   Double_t dz = param[2];
   SetEltuDimensions(a, b, dz);
}
 
////////////////////////////////////////////////////////////////////////////////
/// Create elliptical tube mesh points
 
void TGeoEltu::SetPoints(Double_t *points) const
{
   Double_t dz;
   Int_t j, n;
 
   n = gGeoManager->GetNsegments();
   Double_t dphi = 360. / n;
   Double_t phi = 0;
   Double_t cph, sph;
   dz = fDz;
 
   Int_t indx = 0;
   Double_t r2, r;
   Double_t a2 = fRmin * fRmin;
   Double_t b2 = fRmax * fRmax;
 
   if (points) {
      for (j = 0; j < n; j++) {
         points[indx + 6 * n] = points[indx] = 0;
         indx++;
         points[indx + 6 * n] = points[indx] = 0;
         indx++;
         points[indx + 6 * n] = dz;
         points[indx] = -dz;
         indx++;
      }
      for (j = 0; j < n; j++) {
         phi = j * dphi * TMath::DegToRad();
         sph = TMath::Sin(phi);
         cph = TMath::Cos(phi);
         r2 = (a2 * b2) / (b2 + (a2 - b2) * sph * sph);
         r = TMath::Sqrt(r2);
         points[indx + 6 * n] = points[indx] = r * cph;
         indx++;
         points[indx + 6 * n] = points[indx] = r * sph;
         indx++;
         points[indx + 6 * n] = dz;
         points[indx] = -dz;
         indx++;
      }
   }
}
 
////////////////////////////////////////////////////////////////////////////////
/// Returns numbers of vertices, segments and polygons composing the shape mesh.
 
void TGeoEltu::GetMeshNumbers(Int_t &nvert, Int_t &nsegs, Int_t &npols) const
{
   TGeoTube::GetMeshNumbers(nvert, nsegs, npols);
}
 
////////////////////////////////////////////////////////////////////////////////
/// Returns the number of vertices on the mesh.
 
Int_t TGeoEltu::GetNmeshVertices() const
{
   return TGeoTube::GetNmeshVertices();
}
 
////////////////////////////////////////////////////////////////////////////////
/// Create elliptical tube mesh points
 
void TGeoEltu::SetPoints(Float_t *points) const
{
   Double_t dz;
   Int_t j, n;
 
   n = gGeoManager->GetNsegments();
   Double_t dphi = 360. / n;
   Double_t phi = 0;
   Double_t cph, sph;
   dz = fDz;
 
   Int_t indx = 0;
   Double_t r2, r;
   Double_t a2 = fRmin * fRmin;
   Double_t b2 = fRmax * fRmax;
 
   if (points) {
      for (j = 0; j < n; j++) {
         points[indx + 6 * n] = points[indx] = 0;
         indx++;
         points[indx + 6 * n] = points[indx] = 0;
         indx++;
         points[indx + 6 * n] = dz;
         points[indx] = -dz;
         indx++;
      }
      for (j = 0; j < n; j++) {
         phi = j * dphi * TMath::DegToRad();
         sph = TMath::Sin(phi);
         cph = TMath::Cos(phi);
         r2 = (a2 * b2) / (b2 + (a2 - b2) * sph * sph);
         r = TMath::Sqrt(r2);
         points[indx + 6 * n] = points[indx] = r * cph;
         indx++;
         points[indx + 6 * n] = points[indx] = r * sph;
         indx++;
         points[indx + 6 * n] = dz;
         points[indx] = -dz;
         indx++;
      }
   }
}
 
////////////////////////////////////////////////////////////////////////////////
/// Fills a static 3D buffer and returns a reference.
 
const TBuffer3D &TGeoEltu::GetBuffer3D(Int_t reqSections, Bool_t localFrame) const
{
   static TBuffer3D buffer(TBuffer3DTypes::kGeneric);
   TGeoBBox::FillBuffer3D(buffer, reqSections, localFrame);
 
   if (reqSections & TBuffer3D::kRawSizes) {
      Int_t n = gGeoManager->GetNsegments();
      Int_t nbPnts = 4 * n;
      Int_t nbSegs = 8 * n;
      Int_t nbPols = 4 * n;
      if (buffer.SetRawSizes(nbPnts, 3 * nbPnts, nbSegs, 3 * nbSegs, nbPols, 6 * nbPols)) {
         buffer.SetSectionsValid(TBuffer3D::kRawSizes);
      }
   }
   if ((reqSections & TBuffer3D::kRaw) && buffer.SectionsValid(TBuffer3D::kRawSizes)) {
      SetPoints(buffer.fPnts);
      if (!buffer.fLocalFrame) {
         TransformPoints(buffer.fPnts, buffer.NbPnts());
      }
      SetSegsAndPols(buffer);
      buffer.SetSectionsValid(TBuffer3D::kRaw);
   }
 
   return buffer;
}
 
////////////////////////////////////////////////////////////////////////////////
/// Check the inside status for each of the points in the array.
/// Input: Array of point coordinates + vector size
/// Output: Array of Booleans for the inside of each point
 
void TGeoEltu::Contains_v(const Double_t *points, Bool_t *inside, Int_t vecsize) const
{
   for (Int_t i = 0; i < vecsize; i++)
      inside[i] = Contains(&points[3 * i]);
}
 
////////////////////////////////////////////////////////////////////////////////
/// Compute the normal for an array o points so that norm.dot.dir is positive
/// Input: Arrays of point coordinates and directions + vector size
/// Output: Array of normal directions
 
void TGeoEltu::ComputeNormal_v(const Double_t *points, const Double_t *dirs, Double_t *norms, Int_t vecsize)
{
   for (Int_t i = 0; i < vecsize; i++)
      ComputeNormal(&points[3 * i], &dirs[3 * i], &norms[3 * i]);
}
 
////////////////////////////////////////////////////////////////////////////////
/// Compute distance from array of input points having directions specified by dirs. Store output in dists
 
void TGeoEltu::DistFromInside_v(const Double_t *points, const Double_t *dirs, Double_t *dists, Int_t vecsize,
                                Double_t *step) const
{
   for (Int_t i = 0; i < vecsize; i++)
      dists[i] = DistFromInside(&points[3 * i], &dirs[3 * i], 3, step[i]);
}
 
////////////////////////////////////////////////////////////////////////////////
/// Compute distance from array of input points having directions specified by dirs. Store output in dists
 
void TGeoEltu::DistFromOutside_v(const Double_t *points, const Double_t *dirs, Double_t *dists, Int_t vecsize,
                                 Double_t *step) const
{
   for (Int_t i = 0; i < vecsize; i++)
      dists[i] = DistFromOutside(&points[3 * i], &dirs[3 * i], 3, step[i]);
}
 
////////////////////////////////////////////////////////////////////////////////
/// Compute safe distance from each of the points in the input array.
/// Input: Array of point coordinates, array of statuses for these points, size of the arrays
/// Output: Safety values
 
void TGeoEltu::Safety_v(const Double_t *points, const Bool_t *inside, Double_t *safe, Int_t vecsize) const
{
   for (Int_t i = 0; i < vecsize; i++)
      safe[i] = Safety(&points[3 * i], inside[i]);
}