doc/v632/TGeoBuilder_8cxx_source.html

// @(#)root/geom:$Id$

// Author: Mihaela Gheata   30/05/07


/*************************************************************************

 * 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 TGeoBuilder

\ingroup Geometry_classes


Utility class for creating geometry objects.These will be associated

with the current selected geometry manager object:


`TGeoBuilder::Instance()->SetGeometry(gGeoManager);`


The geometry builder is a singleton that may be used to build one or more

geometries.

*/


#include "TList.h"

#include "TObjArray.h"


#include "TGeoManager.h"

#include "TGeoElement.h"

#include "TGeoMaterial.h"

#include "TGeoMedium.h"

#include "TGeoMatrix.h"

#include "TGeoPara.h"

#include "TGeoParaboloid.h"

#include "TGeoTube.h"

#include "TGeoEltu.h"

#include "TGeoHype.h"

#include "TGeoCone.h"

#include "TGeoSphere.h"

#include "TGeoArb8.h"

#include "TGeoPgon.h"

#include "TGeoTrd1.h"

#include "TGeoTrd2.h"

#include "TGeoTorus.h"

#include "TGeoXtru.h"

#include "TGeoNode.h"

#include "TGeoVolume.h"


#include "TGeoBuilder.h"


ClassImp(TGeoBuilder);


TGeoBuilder *TGeoBuilder::fgInstance = nullptr;


////////////////////////////////////////////////////////////////////////////////

/// Default constructor.


TGeoBuilder::TGeoBuilder() : fGeometry(nullptr)

{

   fgInstance = this;

}


////////////////////////////////////////////////////////////////////////////////

/// Destructor.


TGeoBuilder::~TGeoBuilder()

{

   fgInstance = nullptr;

}


////////////////////////////////////////////////////////////////////////////////

/// Return pointer to singleton.


TGeoBuilder *TGeoBuilder::Instance(TGeoManager *geom)

{

   if (!geom) {

      printf("ERROR: Cannot create geometry builder with NULL geometry\n");

      return nullptr;

   }

   if (!fgInstance)

      fgInstance = new TGeoBuilder();

   fgInstance->SetGeometry(geom);

   return fgInstance;

}


////////////////////////////////////////////////////////////////////////////////

/// Add a material to the list. Returns index of the material in list.


Int_t TGeoBuilder::AddMaterial(TGeoMaterial *material)

{

   if (!material)

      return -1;

   TList *materials = fGeometry->GetListOfMaterials();

   Int_t index = materials->GetSize();

   material->SetIndex(index);

   materials->Add(material);

   return index;

}


////////////////////////////////////////////////////////////////////////////////

/// Add a matrix to the list. Returns index of the matrix in list.


Int_t TGeoBuilder::AddTransformation(TGeoMatrix *matrix)

{

   Int_t index = -1;

   if (!matrix)

      return -1;

   TObjArray *matrices = fGeometry->GetListOfMatrices();

   index = matrices->GetEntriesFast();

   matrices->AddAtAndExpand(matrix, index);

   return index;

}


////////////////////////////////////////////////////////////////////////////////

/// Add a shape to the list. Returns index of the shape in list.


Int_t TGeoBuilder::AddShape(TGeoShape *shape)

{

   Int_t index = -1;

   if (!shape)

      return -1;

   TObjArray *shapes = fGeometry->GetListOfShapes();

   if (shape->IsRunTimeShape())

      shapes = fGeometry->GetListOfGShapes();

   index = shapes->GetEntriesFast();

   shapes->AddAtAndExpand(shape, index);

   return index;

}


////////////////////////////////////////////////////////////////////////////////

/// Register a matrix to the list of matrices. It will be cleaned-up at the

/// destruction TGeoManager.


void TGeoBuilder::RegisterMatrix(TGeoMatrix *matrix)

{

   if (matrix->IsRegistered())

      return;

   TObjArray *matrices = fGeometry->GetListOfMatrices();

   Int_t nmat = matrices->GetEntriesFast();

   matrices->AddAtAndExpand(matrix, nmat);

}


////////////////////////////////////////////////////////////////////////////////

/// Make an TGeoArb8 volume.


TGeoVolume *TGeoBuilder::MakeArb8(const char *name, TGeoMedium *medium, Double_t dz, Double_t *vertices)

{

   TGeoArb8 *arb = new TGeoArb8(name, dz, vertices);

   TGeoVolume *vol = new TGeoVolume(name, arb, medium);

   return vol;

}


////////////////////////////////////////////////////////////////////////////////

/// Make in one step a volume pointing to a box shape with given medium.


TGeoVolume *TGeoBuilder::MakeBox(const char *name, TGeoMedium *medium, Double_t dx, Double_t dy, Double_t dz)

{

   TGeoBBox *box = new TGeoBBox(name, dx, dy, dz);

   TGeoVolume *vol = nullptr;

   if (box->IsRunTimeShape()) {

      vol = fGeometry->MakeVolumeMulti(name, medium);

      vol->SetShape(box);

   } else {

      vol = new TGeoVolume(name, box, medium);

   }

   return vol;

}


////////////////////////////////////////////////////////////////////////////////

/// Make in one step a volume pointing to a parallelepiped shape with given medium.


TGeoVolume *TGeoBuilder::MakePara(const char *name, TGeoMedium *medium, Double_t dx, Double_t dy, Double_t dz,

                                  Double_t alpha, Double_t theta, Double_t phi)

{

   if (TMath::Abs(alpha) < TGeoShape::Tolerance() && TMath::Abs(theta) < TGeoShape::Tolerance()) {

      Warning("MakePara", "parallelepiped %s having alpha=0, theta=0 -> making box instead", name);

      return MakeBox(name, medium, dx, dy, dz);

   }

   TGeoPara *para = nullptr;

   para = new TGeoPara(name, dx, dy, dz, alpha, theta, phi);

   TGeoVolume *vol = nullptr;

   if (para->IsRunTimeShape()) {

      vol = fGeometry->MakeVolumeMulti(name, medium);

      vol->SetShape(para);

   } else {

      vol = new TGeoVolume(name, para, medium);

   }

   return vol;

}


////////////////////////////////////////////////////////////////////////////////

/// Make in one step a volume pointing to a sphere shape with given medium


TGeoVolume *TGeoBuilder::MakeSphere(const char *name, TGeoMedium *medium, Double_t rmin, Double_t rmax, Double_t themin,

                                    Double_t themax, Double_t phimin, Double_t phimax)

{

   TGeoSphere *sph = new TGeoSphere(name, rmin, rmax, themin, themax, phimin, phimax);

   TGeoVolume *vol = new TGeoVolume(name, sph, medium);

   return vol;

}


////////////////////////////////////////////////////////////////////////////////

/// Make in one step a volume pointing to a torus shape with given medium.


TGeoVolume *TGeoBuilder::MakeTorus(const char *name, TGeoMedium *medium, Double_t r, Double_t rmin, Double_t rmax,

                                   Double_t phi1, Double_t dphi)

{

   TGeoTorus *tor = new TGeoTorus(name, r, rmin, rmax, phi1, dphi);

   TGeoVolume *vol = new TGeoVolume(name, tor, medium);

   return vol;

}


////////////////////////////////////////////////////////////////////////////////

/// Make in one step a volume pointing to a tube shape with given medium.


TGeoVolume *TGeoBuilder::MakeTube(const char *name, TGeoMedium *medium, Double_t rmin, Double_t rmax, Double_t dz)

{

   if (rmin > rmax) {

      Error("MakeTube", "tube %s, Rmin=%g greater than Rmax=%g", name, rmin, rmax);

   }

   TGeoTube *tube = new TGeoTube(name, rmin, rmax, dz);

   TGeoVolume *vol = nullptr;

   if (tube->IsRunTimeShape()) {

      vol = fGeometry->MakeVolumeMulti(name, medium);

      vol->SetShape(tube);

   } else {

      vol = new TGeoVolume(name, tube, medium);

   }

   return vol;

}


////////////////////////////////////////////////////////////////////////////////

/// Make in one step a volume pointing to a tube segment shape with given medium.


TGeoVolume *TGeoBuilder::MakeTubs(const char *name, TGeoMedium *medium, Double_t rmin, Double_t rmax, Double_t dz,

                                  Double_t phi1, Double_t phi2)

{

   TGeoTubeSeg *tubs = new TGeoTubeSeg(name, rmin, rmax, dz, phi1, phi2);

   TGeoVolume *vol = nullptr;

   if (tubs->IsRunTimeShape()) {

      vol = fGeometry->MakeVolumeMulti(name, medium);

      vol->SetShape(tubs);

   } else {

      vol = new TGeoVolume(name, tubs, medium);

   }

   return vol;

}


////////////////////////////////////////////////////////////////////////////////

/// Make in one step a volume pointing to a tube shape with given medium


TGeoVolume *TGeoBuilder::MakeEltu(const char *name, TGeoMedium *medium, Double_t a, Double_t b, Double_t dz)

{

   TGeoEltu *eltu = new TGeoEltu(name, a, b, dz);

   TGeoVolume *vol = nullptr;

   if (eltu->IsRunTimeShape()) {

      vol = fGeometry->MakeVolumeMulti(name, medium);

      vol->SetShape(eltu);

   } else {

      vol = new TGeoVolume(name, eltu, medium);

   }

   return vol;

}


////////////////////////////////////////////////////////////////////////////////

/// Make in one step a volume pointing to a tube shape with given medium


TGeoVolume *TGeoBuilder::MakeHype(const char *name, TGeoMedium *medium, Double_t rin, Double_t stin, Double_t rout,

                                  Double_t stout, Double_t dz)

{

   TGeoHype *hype = new TGeoHype(name, rin, stin, rout, stout, dz);

   TGeoVolume *vol = nullptr;

   if (hype->IsRunTimeShape()) {

      vol = fGeometry->MakeVolumeMulti(name, medium);

      vol->SetShape(hype);

   } else {

      vol = new TGeoVolume(name, hype, medium);

   }

   return vol;

}


////////////////////////////////////////////////////////////////////////////////

/// Make in one step a volume pointing to a tube shape with given medium


TGeoVolume *TGeoBuilder::MakeParaboloid(const char *name, TGeoMedium *medium, Double_t rlo, Double_t rhi, Double_t dz)

{

   TGeoParaboloid *parab = new TGeoParaboloid(name, rlo, rhi, dz);

   TGeoVolume *vol = nullptr;

   if (parab->IsRunTimeShape()) {

      vol = fGeometry->MakeVolumeMulti(name, medium);

      vol->SetShape(parab);

   } else {

      vol = new TGeoVolume(name, parab, medium);

   }

   return vol;

}


////////////////////////////////////////////////////////////////////////////////

/// Make in one step a volume pointing to a tube segment shape with given medium


TGeoVolume *TGeoBuilder::MakeCtub(const char *name, TGeoMedium *medium, 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)

{

   TGeoCtub *ctub = new TGeoCtub(name, rmin, rmax, dz, phi1, phi2, lx, ly, lz, tx, ty, tz);

   TGeoVolume *vol = new TGeoVolume(name, ctub, medium);

   return vol;

}


////////////////////////////////////////////////////////////////////////////////

/// Make in one step a volume pointing to a cone shape with given medium.


TGeoVolume *TGeoBuilder::MakeCone(const char *name, TGeoMedium *medium, Double_t dz, Double_t rmin1, Double_t rmax1,

                                  Double_t rmin2, Double_t rmax2)

{

   TGeoCone *cone = new TGeoCone(name, dz, rmin1, rmax1, rmin2, rmax2);

   TGeoVolume *vol = nullptr;

   if (cone->IsRunTimeShape()) {

      vol = fGeometry->MakeVolumeMulti(name, medium);

      vol->SetShape(cone);

   } else {

      vol = new TGeoVolume(name, cone, medium);

   }

   return vol;

}


////////////////////////////////////////////////////////////////////////////////

/// Make in one step a volume pointing to a cone segment shape with given medium


TGeoVolume *TGeoBuilder::MakeCons(const char *name, TGeoMedium *medium, Double_t dz, Double_t rmin1, Double_t rmax1,

                                  Double_t rmin2, Double_t rmax2, Double_t phi1, Double_t phi2)

{

   TGeoConeSeg *cons = new TGeoConeSeg(name, dz, rmin1, rmax1, rmin2, rmax2, phi1, phi2);

   TGeoVolume *vol = nullptr;

   if (cons->IsRunTimeShape()) {

      vol = fGeometry->MakeVolumeMulti(name, medium);

      vol->SetShape(cons);

   } else {

      vol = new TGeoVolume(name, cons, medium);

   }

   return vol;

}


////////////////////////////////////////////////////////////////////////////////

/// Make in one step a volume pointing to a polycone shape with given medium.


TGeoVolume *TGeoBuilder::MakePcon(const char *name, TGeoMedium *medium, Double_t phi, Double_t dphi, Int_t nz)

{

   TGeoPcon *pcon = new TGeoPcon(name, phi, dphi, nz);

   TGeoVolume *vol = new TGeoVolume(name, pcon, medium);

   return vol;

}


////////////////////////////////////////////////////////////////////////////////

/// Make in one step a volume pointing to a polygone shape with given medium.


TGeoVolume *

TGeoBuilder::MakePgon(const char *name, TGeoMedium *medium, Double_t phi, Double_t dphi, Int_t nedges, Int_t nz)

{

   TGeoPgon *pgon = new TGeoPgon(name, phi, dphi, nedges, nz);

   TGeoVolume *vol = new TGeoVolume(name, pgon, medium);

   return vol;

}


////////////////////////////////////////////////////////////////////////////////

/// Make in one step a volume pointing to a TGeoTrd1 shape with given medium.


TGeoVolume *

TGeoBuilder::MakeTrd1(const char *name, TGeoMedium *medium, Double_t dx1, Double_t dx2, Double_t dy, Double_t dz)

{

   TGeoTrd1 *trd1 = new TGeoTrd1(name, dx1, dx2, dy, dz);

   TGeoVolume *vol = nullptr;

   if (trd1->IsRunTimeShape()) {

      vol = fGeometry->MakeVolumeMulti(name, medium);

      vol->SetShape(trd1);

   } else {

      vol = new TGeoVolume(name, trd1, medium);

   }

   return vol;

}


////////////////////////////////////////////////////////////////////////////////

/// Make in one step a volume pointing to a TGeoTrd2 shape with given medium.


TGeoVolume *TGeoBuilder::MakeTrd2(const char *name, TGeoMedium *medium, Double_t dx1, Double_t dx2, Double_t dy1,

                                  Double_t dy2, Double_t dz)

{

   TGeoTrd2 *trd2 = new TGeoTrd2(name, dx1, dx2, dy1, dy2, dz);

   TGeoVolume *vol = nullptr;

   if (trd2->IsRunTimeShape()) {

      vol = fGeometry->MakeVolumeMulti(name, medium);

      vol->SetShape(trd2);

   } else {

      vol = new TGeoVolume(name, trd2, medium);

   }

   return vol;

}


////////////////////////////////////////////////////////////////////////////////

/// Make in one step a volume pointing to a trapezoid shape with given medium.


TGeoVolume *TGeoBuilder::MakeTrap(const char *name, TGeoMedium *medium, Double_t dz, Double_t theta, Double_t phi,

                                  Double_t h1, Double_t bl1, Double_t tl1, Double_t alpha1, Double_t h2, Double_t bl2,

                                  Double_t tl2, Double_t alpha2)

{

   TGeoTrap *trap = new TGeoTrap(name, dz, theta, phi, h1, bl1, tl1, alpha1, h2, bl2, tl2, alpha2);

   TGeoVolume *vol = new TGeoVolume(name, trap, medium);

   return vol;

}


////////////////////////////////////////////////////////////////////////////////

/// Make in one step a volume pointing to a twisted trapezoid shape with given medium.


TGeoVolume *TGeoBuilder::MakeGtra(const char *name, TGeoMedium *medium, Double_t dz, Double_t theta, Double_t phi,

                                  Double_t twist, Double_t h1, Double_t bl1, Double_t tl1, Double_t alpha1, Double_t h2,

                                  Double_t bl2, Double_t tl2, Double_t alpha2)

{

   TGeoGtra *gtra = new TGeoGtra(name, dz, theta, phi, twist, h1, bl1, tl1, alpha1, h2, bl2, tl2, alpha2);

   TGeoVolume *vol = new TGeoVolume(name, gtra, medium);

   return vol;

}

////////////////////////////////////////////////////////////////////////////////

/// Make a TGeoXtru-shaped volume with nz planes


TGeoVolume *TGeoBuilder::MakeXtru(const char *name, TGeoMedium *medium, Int_t nz)

{

   TGeoXtru *xtru = new TGeoXtru(nz);

   xtru->SetName(name);

   TGeoVolume *vol = new TGeoVolume(name, xtru, medium);

   return vol;

}


////////////////////////////////////////////////////////////////////////////////

/// Make an assembly of volumes.


TGeoVolumeAssembly *TGeoBuilder::MakeVolumeAssembly(const char *name)

{

   return (new TGeoVolumeAssembly(name));

}


////////////////////////////////////////////////////////////////////////////////

/// Make a TGeoVolumeMulti handling a list of volumes.


TGeoVolumeMulti *TGeoBuilder::MakeVolumeMulti(const char *name, TGeoMedium *medium)

{

   return (new TGeoVolumeMulti(name, medium));

}


////////////////////////////////////////////////////////////////////////////////

/// Create a new volume by dividing an existing one (GEANT3 like)

///

/// Divides MOTHER into NDIV divisions called NAME

/// along axis IAXIS starting at coordinate value START

/// and having size STEP. The created volumes will have tracking

/// media ID=NUMED (if NUMED=0 -> same media as MOTHER)

///    The behavior of the division operation can be triggered using OPTION (case insensitive):

///

///  - N  - divide all range in NDIV cells (same effect as STEP<=0) (GSDVN in G3)

///  - NX - divide range starting with START in NDIV cells          (GSDVN2 in G3)

///  - S  - divide all range with given STEP. NDIV is computed and divisions will be centered

///        in full range (same effect as NDIV<=0)                (GSDVS, GSDVT in G3)

///  - SX - same as DVS, but from START position.                   (GSDVS2, GSDVT2 in G3)


TGeoVolume *TGeoBuilder::Division(const char *name, const char *mother, Int_t iaxis, Int_t ndiv, Double_t start,

                                  Double_t step, Int_t numed, Option_t *option)

{

   TGeoVolume *amother;

   TString sname = name;

   sname = sname.Strip();

   const char *vname = sname.Data();

   TString smname = mother;

   smname = smname.Strip();

   const char *mname = smname.Data();


   amother = (TGeoVolume *)fGeometry->GetListOfGVolumes()->FindObject(mname);

   if (!amother)

      amother = fGeometry->GetVolume(mname);

   if (amother)

      return amother->Divide(vname, iaxis, ndiv, start, step, numed, option);


   Error("Division", "VOLUME: \"%s\" not defined", mname);


   return nullptr;

}


////////////////////////////////////////////////////////////////////////////////

/// Create rotation matrix named 'mat<index>'.

///

///  - index    rotation matrix number

///  - theta1   polar angle for axis X

///  - phi1     azimuthal angle for axis X

///  - theta2   polar angle for axis Y

///  - phi2     azimuthal angle for axis Y

///  - theta3   polar angle for axis Z

///  - phi3     azimuthal angle for axis Z

///


void TGeoBuilder::Matrix(Int_t index, Double_t theta1, Double_t phi1, Double_t theta2, Double_t phi2, Double_t theta3,

                         Double_t phi3)

{

   TGeoRotation *rot = new TGeoRotation("", theta1, phi1, theta2, phi2, theta3, phi3);

   rot->SetUniqueID(index);

   rot->RegisterYourself();

}


////////////////////////////////////////////////////////////////////////////////

/// Create material with given A, Z and density, having an unique id.


TGeoMaterial *TGeoBuilder::Material(const char *name, Double_t a, Double_t z, Double_t dens, Int_t uid, Double_t radlen,

                                    Double_t intlen)

{

   TGeoMaterial *material = new TGeoMaterial(name, a, z, dens, radlen, intlen);

   material->SetUniqueID(uid);

   return material;

}


////////////////////////////////////////////////////////////////////////////////

/// Create mixture OR COMPOUND IMAT as composed by THE BASIC nelem

/// materials defined by arrays A,Z and WMAT, having an unique id.


TGeoMaterial *

TGeoBuilder::Mixture(const char *name, Float_t *a, Float_t *z, Double_t dens, Int_t nelem, Float_t *wmat, Int_t uid)

{

   TGeoMixture *mix = new TGeoMixture(name, nelem, dens);

   mix->SetUniqueID(uid);

   Int_t i;

   for (i = 0; i < nelem; i++) {

      mix->DefineElement(i, a[i], z[i], wmat[i]);

   }

   return (TGeoMaterial *)mix;

}


////////////////////////////////////////////////////////////////////////////////

/// Create mixture OR COMPOUND IMAT as composed by THE BASIC nelem

/// materials defined by arrays A,Z and WMAT, having an unique id.


TGeoMaterial *

TGeoBuilder::Mixture(const char *name, Double_t *a, Double_t *z, Double_t dens, Int_t nelem, Double_t *wmat, Int_t uid)

{

   TGeoMixture *mix = new TGeoMixture(name, nelem, dens);

   mix->SetUniqueID(uid);

   Int_t i;

   for (i = 0; i < nelem; i++) {

      mix->DefineElement(i, a[i], z[i], wmat[i]);

   }

   return (TGeoMaterial *)mix;

}


////////////////////////////////////////////////////////////////////////////////

/// Create tracking medium

///

///  - numed      tracking medium number assigned

///  - name      tracking medium name

///  - nmat      material number

///  - isvol     sensitive volume flag

///  - ifield    magnetic field

///  - fieldm    max. field value (kilogauss)

///  - tmaxfd    max. angle due to field (deg/step)

///  - stemax    max. step allowed

///  - deemax    max. fraction of energy lost in a step

///  - epsil     tracking precision (cm)

///  - stmin     min. step due to continuous processes (cm)

///

///  - ifield = 0 if no magnetic field; ifield = -1 if user decision in guswim;

///  - ifield = 1 if tracking performed with g3rkuta; ifield = 2 if tracking

///    performed with g3helix; ifield = 3 if tracking performed with g3helx3.

///


TGeoMedium *TGeoBuilder::Medium(const char *name, Int_t numed, Int_t nmat, Int_t isvol, Int_t ifield, Double_t fieldm,

                                Double_t tmaxfd, Double_t stemax, Double_t deemax, Double_t epsil, Double_t stmin)

{

   return new TGeoMedium(name, numed, nmat, isvol, ifield, fieldm, tmaxfd, stemax, deemax, epsil, stmin);

}


////////////////////////////////////////////////////////////////////////////////

/// Create a node called `<name_nr>` pointing to the volume called `<name>`

/// as daughter of the volume called `<mother>` (gspos). The relative matrix is

/// made of : a translation (x,y,z) and a rotation matrix named `<matIROT>`.

/// In case npar>0, create the volume to be positioned in mother, according

/// its actual parameters (gsposp).

///  - NAME   Volume name

///  - NUMBER Copy number of the volume

///  - MOTHER Mother volume name

///  - X      X coord. of the volume in mother ref. sys.

///  - Y      Y coord. of the volume in mother ref. sys.

///  - Z      Z coord. of the volume in mother ref. sys.

///  - IROT   Rotation matrix number w.r.t. mother ref. sys.

///  - ISONLY ONLY/MANY flag


void TGeoBuilder::Node(const char *name, Int_t nr, const char *mother, Double_t x, Double_t y, Double_t z, Int_t irot,

                       Bool_t isOnly, Float_t *upar, Int_t npar)

{

   TGeoVolume *amother = nullptr;

   TGeoVolume *volume = nullptr;


   // look into special volume list first

   amother = fGeometry->FindVolumeFast(mother, kTRUE);

   if (!amother)

      amother = fGeometry->FindVolumeFast(mother);

   if (!amother) {

      TString mname = mother;

      mname = mname.Strip();

      Error("Node", "Mother VOLUME \"%s\" not defined", mname.Data());

      return;

   }

   Int_t i;

   if (npar <= 0) {

      //---> acting as G3 gspos

      if (gDebug > 0)

         Info("Node", "Calling gspos, mother=%s, name=%s, nr=%d, x=%g, y=%g, z=%g, irot=%d, konly=%i", mother, name, nr,

              x, y, z, irot, (Int_t)isOnly);

      // look into special volume list first

      volume = fGeometry->FindVolumeFast(name, kTRUE);

      if (!volume)

         volume = fGeometry->FindVolumeFast(name);

      if (!volume) {

         TString vname = name;

         vname = vname.Strip();

         Error("Node", "VOLUME: \"%s\" not defined", vname.Data());

         return;

      }

      if (((TObject *)volume)->TestBit(TGeoVolume::kVolumeMulti) && !volume->GetShape()) {

         Error("Node", "cannot add multiple-volume object %s as node", volume->GetName());

         return;

      }

   } else {

      //---> acting as G3 gsposp

      TGeoVolumeMulti *vmulti = (TGeoVolumeMulti *)fGeometry->FindVolumeFast(name, kTRUE);

      if (!vmulti) {

         volume = fGeometry->FindVolumeFast(name);

         if (volume) {

            Warning("Node", "volume: %s is defined as single -> ignoring shape parameters", volume->GetName());

            Node(name, nr, mother, x, y, z, irot, isOnly, upar);

            return;

         }

         TString vname = name;

         vname = vname.Strip();

         Error("Node", "VOLUME: \"%s\" not defined ", vname.Data());

         return;

      }

      TGeoMedium *medium = vmulti->GetMedium();

      TString sh = vmulti->GetTitle();

      sh.ToLower();

      if (sh.Contains("box")) {

         volume = MakeBox(name, medium, upar[0], upar[1], upar[2]);

      } else if (sh.Contains("trd1")) {

         volume = MakeTrd1(name, medium, upar[0], upar[1], upar[2], upar[3]);

      } else if (sh.Contains("trd2")) {

         volume = MakeTrd2(name, medium, upar[0], upar[1], upar[2], upar[3], upar[4]);

      } else if (sh.Contains("trap")) {

         volume = MakeTrap(name, medium, upar[0], upar[1], upar[2], upar[3], upar[4], upar[5], upar[6], upar[7],

                           upar[8], upar[9], upar[10]);

      } else if (sh.Contains("gtra")) {

         volume = MakeGtra(name, medium, upar[0], upar[1], upar[2], upar[3], upar[4], upar[5], upar[6], upar[7],

                           upar[8], upar[9], upar[10], upar[11]);

      } else if (sh.Contains("tube")) {

         volume = MakeTube(name, medium, upar[0], upar[1], upar[2]);

      } else if (sh.Contains("tubs")) {

         volume = MakeTubs(name, medium, upar[0], upar[1], upar[2], upar[3], upar[4]);

      } else if (sh.Contains("cone")) {

         volume = MakeCone(name, medium, upar[0], upar[1], upar[2], upar[3], upar[4]);

      } else if (sh.Contains("cons")) {

         volume = MakeCons(name, medium, upar[0], upar[1], upar[2], upar[3], upar[4], upar[5], upar[6]);

      } else if (sh.Contains("pgon")) {

         volume = MakePgon(name, medium, upar[0], upar[1], (Int_t)upar[2], (Int_t)upar[3]);

         Int_t nz = (Int_t)upar[3];

         for (i = 0; i < nz; i++) {

            ((TGeoPgon *)volume->GetShape())->DefineSection(i, upar[3 * i + 4], upar[3 * i + 5], upar[3 * i + 6]);

         }

      } else if (sh.Contains("pcon")) {

         volume = MakePcon(name, medium, upar[0], upar[1], (Int_t)upar[2]);

         Int_t nz = (Int_t)upar[2];

         for (i = 0; i < nz; i++) {

            ((TGeoPcon *)volume->GetShape())->DefineSection(i, upar[3 * i + 3], upar[3 * i + 4], upar[3 * i + 5]);

         }

      } else if (sh.Contains("eltu")) {

         volume = MakeEltu(name, medium, upar[0], upar[1], upar[2]);

      } else if (sh.Contains("sphe")) {

         volume = MakeSphere(name, medium, upar[0], upar[1], upar[2], upar[3], upar[4], upar[5]);

      } else if (sh.Contains("ctub")) {

         volume = MakeCtub(name, medium, upar[0], upar[1], upar[2], upar[3], upar[4], upar[5], upar[6], upar[7],

                           upar[8], upar[9], upar[10]);

      } else if (sh.Contains("para")) {

         volume = MakePara(name, medium, upar[0], upar[1], upar[2], upar[3], upar[4], upar[5]);

      } else {

         Error("Node", "cannot create shape %s", sh.Data());

      }


      if (!volume)

         return;

      vmulti->AddVolume(volume);

   }

   if (irot) {

      TGeoRotation *matrix = nullptr;

      TGeoMatrix *mat;

      TIter next(fGeometry->GetListOfMatrices());

      while ((mat = (TGeoMatrix *)next())) {

         if (mat->GetUniqueID() == UInt_t(irot)) {

            matrix = dynamic_cast<TGeoRotation *>(mat);

            break;

         }

      }

      if (!matrix) {

         Fatal("Node", "Node %s/%s_%d rotation %i not found", mother, name, nr, irot);

         return;

      }

      if (isOnly)

         amother->AddNode(volume, nr, new TGeoCombiTrans(x, y, z, matrix));

      else

         amother->AddNodeOverlap(volume, nr, new TGeoCombiTrans(x, y, z, matrix));

   } else {

      if (TMath::Abs(x) < TGeoShape::Tolerance() && TMath::Abs(y) < TGeoShape::Tolerance() &&

          TMath::Abs(z) < TGeoShape::Tolerance()) {

         if (isOnly)

            amother->AddNode(volume, nr);

         else

            amother->AddNodeOverlap(volume, nr);

      } else {

         if (isOnly)

            amother->AddNode(volume, nr, new TGeoTranslation(x, y, z));

         else

            amother->AddNodeOverlap(volume, nr, new TGeoTranslation(x, y, z));

      }

   }

}


////////////////////////////////////////////////////////////////////////////////

/// Create a node called `<name_nr>` pointing to the volume called `<name>`

/// as daughter of the volume called `<mother>` (gspos). The relative matrix is

/// made of : a translation (x,y,z) and a rotation matrix named `<matIROT>`.

/// In case npar>0, create the volume to be positioned in mother, according

/// its actual parameters (gsposp).

///  - NAME   Volume name

///  - NUMBER Copy number of the volume

///  - MOTHER Mother volume name

///  - X      X coord. of the volume in mother ref. sys.

///  - Y      Y coord. of the volume in mother ref. sys.

///  - Z      Z coord. of the volume in mother ref. sys.

///  - IROT   Rotation matrix number w.r.t. mother ref. sys.

///  - ISONLY ONLY/MANY flag


void TGeoBuilder::Node(const char *name, Int_t nr, const char *mother, Double_t x, Double_t y, Double_t z, Int_t irot,

                       Bool_t isOnly, Double_t *upar, Int_t npar)

{

   TGeoVolume *amother = nullptr;

   TGeoVolume *volume = nullptr;


   // look into special volume list first

   amother = fGeometry->FindVolumeFast(mother, kTRUE);

   if (!amother)

      amother = fGeometry->FindVolumeFast(mother);

   if (!amother) {

      TString mname = mother;

      mname = mname.Strip();

      Error("Node", "Mother VOLUME \"%s\" not defined", mname.Data());

      return;

   }

   Int_t i;

   if (npar <= 0) {

      //---> acting as G3 gspos

      if (gDebug > 0)

         Info("Node", "Calling gspos, mother=%s, name=%s, nr=%d, x=%g, y=%g, z=%g, irot=%d, konly=%i", mother, name, nr,

              x, y, z, irot, (Int_t)isOnly);

      // look into special volume list first

      volume = fGeometry->FindVolumeFast(name, kTRUE);

      if (!volume)

         volume = fGeometry->FindVolumeFast(name);

      if (!volume) {

         TString vname = name;

         vname = vname.Strip();

         Error("Node", "VOLUME: \"%s\" not defined", vname.Data());

         return;

      }

      if (((TObject *)volume)->TestBit(TGeoVolume::kVolumeMulti) && !volume->GetShape()) {

         Error("Node", "cannot add multiple-volume object %s as node", volume->GetName());

         return;

      }

   } else {

      //---> acting as G3 gsposp

      TGeoVolumeMulti *vmulti = (TGeoVolumeMulti *)fGeometry->FindVolumeFast(name, kTRUE);

      if (!vmulti) {

         volume = fGeometry->FindVolumeFast(name);

         if (volume) {

            Warning("Node", "volume: %s is defined as single -> ignoring shape parameters", volume->GetName());

            Node(name, nr, mother, x, y, z, irot, isOnly, upar);

            return;

         }

         TString vname = name;

         vname = vname.Strip();

         Error("Node", "VOLUME: \"%s\" not defined ", vname.Data());

         return;

      }

      TGeoMedium *medium = vmulti->GetMedium();

      TString sh = vmulti->GetTitle();

      sh.ToLower();

      if (sh.Contains("box")) {

         volume = MakeBox(name, medium, upar[0], upar[1], upar[2]);

      } else if (sh.Contains("trd1")) {

         volume = MakeTrd1(name, medium, upar[0], upar[1], upar[2], upar[3]);

      } else if (sh.Contains("trd2")) {

         volume = MakeTrd2(name, medium, upar[0], upar[1], upar[2], upar[3], upar[4]);

      } else if (sh.Contains("trap")) {

         volume = MakeTrap(name, medium, upar[0], upar[1], upar[2], upar[3], upar[4], upar[5], upar[6], upar[7],

                           upar[8], upar[9], upar[10]);

      } else if (sh.Contains("gtra")) {

         volume = MakeGtra(name, medium, upar[0], upar[1], upar[2], upar[3], upar[4], upar[5], upar[6], upar[7],

                           upar[8], upar[9], upar[10], upar[11]);

      } else if (sh.Contains("tube")) {

         volume = MakeTube(name, medium, upar[0], upar[1], upar[2]);

      } else if (sh.Contains("tubs")) {

         volume = MakeTubs(name, medium, upar[0], upar[1], upar[2], upar[3], upar[4]);

      } else if (sh.Contains("cone")) {

         volume = MakeCone(name, medium, upar[0], upar[1], upar[2], upar[3], upar[4]);

      } else if (sh.Contains("cons")) {

         volume = MakeCons(name, medium, upar[0], upar[1], upar[2], upar[3], upar[4], upar[5], upar[6]);

      } else if (sh.Contains("pgon")) {

         volume = MakePgon(name, medium, upar[0], upar[1], (Int_t)upar[2], (Int_t)upar[3]);

         Int_t nz = (Int_t)upar[3];

         for (i = 0; i < nz; i++) {

            ((TGeoPgon *)volume->GetShape())->DefineSection(i, upar[3 * i + 4], upar[3 * i + 5], upar[3 * i + 6]);

         }

      } else if (sh.Contains("pcon")) {

         volume = MakePcon(name, medium, upar[0], upar[1], (Int_t)upar[2]);

         Int_t nz = (Int_t)upar[2];

         for (i = 0; i < nz; i++) {

            ((TGeoPcon *)volume->GetShape())->DefineSection(i, upar[3 * i + 3], upar[3 * i + 4], upar[3 * i + 5]);

         }

      } else if (sh.Contains("eltu")) {

         volume = MakeEltu(name, medium, upar[0], upar[1], upar[2]);

      } else if (sh.Contains("sphe")) {

         volume = MakeSphere(name, medium, upar[0], upar[1], upar[2], upar[3], upar[4], upar[5]);

      } else if (sh.Contains("ctub")) {

         volume = MakeCtub(name, medium, upar[0], upar[1], upar[2], upar[3], upar[4], upar[5], upar[6], upar[7],

                           upar[8], upar[9], upar[10]);

      } else if (sh.Contains("para")) {

         volume = MakePara(name, medium, upar[0], upar[1], upar[2], upar[3], upar[4], upar[5]);

      } else {

         Error("Node", "cannot create shape %s", sh.Data());

      }


      if (!volume)

         return;

      vmulti->AddVolume(volume);

   }

   if (irot) {

      TGeoRotation *matrix = nullptr;

      TGeoMatrix *mat;

      TIter next(fGeometry->GetListOfMatrices());

      while ((mat = (TGeoMatrix *)next())) {

         if (mat->GetUniqueID() == UInt_t(irot)) {

            matrix = dynamic_cast<TGeoRotation *>(mat);

            break;

         }

      }

      if (!matrix) {

         Fatal("Node", "Node %s/%s_%d rotation %i not found", mother, name, nr, irot);

         return;

      }

      if (isOnly)

         amother->AddNode(volume, nr, new TGeoCombiTrans(x, y, z, matrix));

      else

         amother->AddNodeOverlap(volume, nr, new TGeoCombiTrans(x, y, z, matrix));

   } else {

      if (TMath::Abs(x) < TGeoShape::Tolerance() && TMath::Abs(y) < TGeoShape::Tolerance() &&

          TMath::Abs(z) < TGeoShape::Tolerance()) {

         if (isOnly)

            amother->AddNode(volume, nr);

         else

            amother->AddNodeOverlap(volume, nr);

      } else {

         if (isOnly)

            amother->AddNode(volume, nr, new TGeoTranslation(x, y, z));

         else

            amother->AddNodeOverlap(volume, nr, new TGeoTranslation(x, y, z));

      }

   }

}


////////////////////////////////////////////////////////////////////////////////

/// Create a volume in GEANT3 style.

///  - NAME   Volume name

///  - SHAPE  Volume type

///  - NMED   Tracking medium number

///  - NPAR   Number of shape parameters

///  - UPAR   Vector containing shape parameters


TGeoVolume *TGeoBuilder::Volume(const char *name, const char *shape, Int_t nmed, Float_t *upar, Int_t npar)

{

   Int_t i;

   TGeoVolume *volume = nullptr;

   TGeoMedium *medium = fGeometry->GetMedium(nmed);

   if (!medium) {

      Error("Volume", "cannot create volume: %s, medium: %d is unknown", name, nmed);

      return nullptr;

   }

   TString sh = shape;

   TString sname = name;

   sname = sname.Strip();

   const char *vname = sname.Data();

   if (npar <= 0) {

      //--- create a TGeoVolumeMulti

      volume = MakeVolumeMulti(vname, medium);

      volume->SetTitle(shape);

      TGeoVolumeMulti *vmulti = (TGeoVolumeMulti *)fGeometry->GetListOfGVolumes()->FindObject(vname);

      if (!vmulti) {

         Error("Volume", "volume multi: %s not created", vname);

         return nullptr;

      }

      return vmulti;

   }

   //---> create a normal volume

   sh.ToLower();

   if (sh.Contains("box")) {

      volume = MakeBox(vname, medium, upar[0], upar[1], upar[2]);

   } else if (sh.Contains("trd1")) {

      volume = MakeTrd1(vname, medium, upar[0], upar[1], upar[2], upar[3]);

   } else if (sh.Contains("trd2")) {

      volume = MakeTrd2(vname, medium, upar[0], upar[1], upar[2], upar[3], upar[4]);

   } else if (sh.Contains("trap")) {

      volume = MakeTrap(vname, medium, upar[0], upar[1], upar[2], upar[3], upar[4], upar[5], upar[6], upar[7], upar[8],

                        upar[9], upar[10]);

   } else if (sh.Contains("gtra")) {

      volume = MakeGtra(vname, medium, upar[0], upar[1], upar[2], upar[3], upar[4], upar[5], upar[6], upar[7], upar[8],

                        upar[9], upar[10], upar[11]);

   } else if (sh.Contains("tube")) {

      volume = MakeTube(vname, medium, upar[0], upar[1], upar[2]);

   } else if (sh.Contains("tubs")) {

      volume = MakeTubs(vname, medium, upar[0], upar[1], upar[2], upar[3], upar[4]);

   } else if (sh.Contains("cone")) {

      volume = MakeCone(vname, medium, upar[0], upar[1], upar[2], upar[3], upar[4]);

   } else if (sh.Contains("cons")) {

      volume = MakeCons(vname, medium, upar[0], upar[1], upar[2], upar[3], upar[4], upar[5], upar[6]);

   } else if (sh.Contains("pgon")) {

      volume = MakePgon(vname, medium, upar[0], upar[1], (Int_t)upar[2], (Int_t)upar[3]);

      Int_t nz = (Int_t)upar[3];

      for (i = 0; i < nz; i++) {

         ((TGeoPgon *)volume->GetShape())->DefineSection(i, upar[3 * i + 4], upar[3 * i + 5], upar[3 * i + 6]);

      }

   } else if (sh.Contains("pcon")) {

      volume = MakePcon(vname, medium, upar[0], upar[1], (Int_t)upar[2]);

      Int_t nz = (Int_t)upar[2];

      for (i = 0; i < nz; i++) {

         ((TGeoPcon *)volume->GetShape())->DefineSection(i, upar[3 * i + 3], upar[3 * i + 4], upar[3 * i + 5]);

      }

   } else if (sh.Contains("eltu")) {

      volume = MakeEltu(vname, medium, upar[0], upar[1], upar[2]);

   } else if (sh.Contains("sphe")) {

      volume = MakeSphere(vname, medium, upar[0], upar[1], upar[2], upar[3], upar[4], upar[5]);

   } else if (sh.Contains("ctub")) {

      volume = MakeCtub(vname, medium, upar[0], upar[1], upar[2], upar[3], upar[4], upar[5], upar[6], upar[7], upar[8],

                        upar[9], upar[10]);

   } else if (sh.Contains("para")) {

      volume = MakePara(vname, medium, upar[0], upar[1], upar[2], upar[3], upar[4], upar[5]);

   } else if (sh.Contains("tor")) {

      volume = MakeTorus(vname, medium, upar[0], upar[1], upar[2], upar[3], upar[4]);

   }


   if (!volume) {

      Error("Volume", "volume: %s not created", vname);

      return nullptr;

   }

   return volume;

}


////////////////////////////////////////////////////////////////////////////////

/// Create a volume in GEANT3 style.

///  - NAME   Volume name

///  - SHAPE  Volume type

///  - NMED   Tracking medium number

///  - NPAR   Number of shape parameters

///  - UPAR   Vector containing shape parameters


TGeoVolume *TGeoBuilder::Volume(const char *name, const char *shape, Int_t nmed, Double_t *upar, Int_t npar)

{

   Int_t i;

   TGeoVolume *volume = nullptr;

   TGeoMedium *medium = fGeometry->GetMedium(nmed);

   if (!medium) {

      Error("Volume", "cannot create volume: %s, medium: %d is unknown", name, nmed);

      return nullptr;

   }

   TString sh = shape;

   TString sname = name;

   sname = sname.Strip();

   const char *vname = sname.Data();

   if (npar <= 0) {

      //--- create a TGeoVolumeMulti

      volume = MakeVolumeMulti(vname, medium);

      volume->SetTitle(shape);

      TGeoVolumeMulti *vmulti = (TGeoVolumeMulti *)fGeometry->GetListOfGVolumes()->FindObject(vname);

      if (!vmulti) {

         Error("Volume", "volume multi: %s not created", vname);

         return nullptr;

      }

      return vmulti;

   }

   //---> create a normal volume

   sh.ToLower();

   if (sh.Contains("box")) {

      volume = MakeBox(vname, medium, upar[0], upar[1], upar[2]);

   } else if (sh.Contains("trd1")) {

      volume = MakeTrd1(vname, medium, upar[0], upar[1], upar[2], upar[3]);

   } else if (sh.Contains("trd2")) {

      volume = MakeTrd2(vname, medium, upar[0], upar[1], upar[2], upar[3], upar[4]);

   } else if (sh.Contains("trap")) {

      volume = MakeTrap(vname, medium, upar[0], upar[1], upar[2], upar[3], upar[4], upar[5], upar[6], upar[7], upar[8],

                        upar[9], upar[10]);

   } else if (sh.Contains("gtra")) {

      volume = MakeGtra(vname, medium, upar[0], upar[1], upar[2], upar[3], upar[4], upar[5], upar[6], upar[7], upar[8],

                        upar[9], upar[10], upar[11]);

   } else if (sh.Contains("tube")) {

      volume = MakeTube(vname, medium, upar[0], upar[1], upar[2]);

   } else if (sh.Contains("tubs")) {

      volume = MakeTubs(vname, medium, upar[0], upar[1], upar[2], upar[3], upar[4]);

   } else if (sh.Contains("cone")) {

      volume = MakeCone(vname, medium, upar[0], upar[1], upar[2], upar[3], upar[4]);

   } else if (sh.Contains("cons")) {

      volume = MakeCons(vname, medium, upar[0], upar[1], upar[2], upar[3], upar[4], upar[5], upar[6]);

   } else if (sh.Contains("pgon")) {

      volume = MakePgon(vname, medium, upar[0], upar[1], (Int_t)upar[2], (Int_t)upar[3]);

      Int_t nz = (Int_t)upar[3];

      for (i = 0; i < nz; i++) {

         ((TGeoPgon *)volume->GetShape())->DefineSection(i, upar[3 * i + 4], upar[3 * i + 5], upar[3 * i + 6]);

      }

   } else if (sh.Contains("pcon")) {

      volume = MakePcon(vname, medium, upar[0], upar[1], (Int_t)upar[2]);

      Int_t nz = (Int_t)upar[2];

      for (i = 0; i < nz; i++) {

         ((TGeoPcon *)volume->GetShape())->DefineSection(i, upar[3 * i + 3], upar[3 * i + 4], upar[3 * i + 5]);

      }

   } else if (sh.Contains("eltu")) {

      volume = MakeEltu(vname, medium, upar[0], upar[1], upar[2]);

   } else if (sh.Contains("sphe")) {

      volume = MakeSphere(vname, medium, upar[0], upar[1], upar[2], upar[3], upar[4], upar[5]);

   } else if (sh.Contains("ctub")) {

      volume = MakeCtub(vname, medium, upar[0], upar[1], upar[2], upar[3], upar[4], upar[5], upar[6], upar[7], upar[8],

                        upar[9], upar[10]);

   } else if (sh.Contains("para")) {

      volume = MakePara(vname, medium, upar[0], upar[1], upar[2], upar[3], upar[4], upar[5]);

   } else if (sh.Contains("tor")) {

      volume = MakeTorus(vname, medium, upar[0], upar[1], upar[2], upar[3], upar[4]);

   }


   if (!volume) {

      Error("Volume", "volume: %s not created", vname);

      return nullptr;

   }

   return volume;

}

b
#define b(i)
Definition RSha256.hxx:100

a
#define a(i)
Definition RSha256.hxx:99

Int_t
int Int_t
Definition RtypesCore.h:45

Float_t
float Float_t
Definition RtypesCore.h:57

kTRUE
constexpr Bool_t kTRUE
Definition RtypesCore.h:100

Option_t
const char Option_t
Definition RtypesCore.h:66

ClassImp
#define ClassImp(name)
Definition Rtypes.h:377

option
Option_t Option_t option
Definition TGWin32VirtualXProxy.cxx:44

r
Option_t Option_t TPoint TPoint const char GetTextMagnitude GetFillStyle GetLineColor GetLineWidth GetMarkerStyle GetTextAlign GetTextColor GetTextSize void char Point_t Rectangle_t WindowAttributes_t Float_t r
Definition TGWin32VirtualXProxy.cxx:168

index
Option_t Option_t TPoint TPoint const char GetTextMagnitude GetFillStyle GetLineColor GetLineWidth GetMarkerStyle GetTextAlign GetTextColor GetTextSize void char Point_t Rectangle_t WindowAttributes_t index
Definition TGWin32VirtualXProxy.cxx:168

name
char name[80]
Definition TGX11.cxx:110

TGeoArb8.h

TGeoBuilder.h

TGeoCone.h

TGeoElement.h

TGeoEltu.h

TGeoHype.h

TGeoManager.h

TGeoMaterial.h

TGeoMatrix.h

TGeoMedium.h

TGeoNode.h

TGeoPara.h

TGeoParaboloid.h

TGeoPgon.h

TGeoSphere.h

TGeoTorus.h

TGeoTrd1.h

TGeoTrd2.h

TGeoTube.h

TGeoVolume.h

TGeoXtru.h

TList.h

TObjArray.h

gDebug
Int_t gDebug
Definition TROOT.cxx:597

TCollection::GetSize
virtual Int_t GetSize() const
Return the capacity of the collection, i.e.
Definition TCollection.h:184

TGeoArb8
An arbitrary trapezoid with less than 8 vertices standing on two parallel planes perpendicular to Z a...
Definition TGeoArb8.h:17

TGeoBBox
Box class.
Definition TGeoBBox.h:17

TGeoBuilder
Utility class for creating geometry objects.These will be associated with the current selected geomet...
Definition TGeoBuilder.h:26

TGeoBuilder::TGeoBuilder
TGeoBuilder()
static pointer to singleton
Definition TGeoBuilder.cxx:57

TGeoBuilder::Node
void Node(const char *name, Int_t nr, const char *mother, Double_t x, Double_t y, Double_t z, Int_t irot, Bool_t isOnly, Float_t *upar, Int_t npar=0)
Create a node called <name_nr> pointing to the volume called <name> as daughter of the volume called ...
Definition TGeoBuilder.cxx:589

TGeoBuilder::MakePgon
TGeoVolume * MakePgon(const char *name, TGeoMedium *medium, Double_t phi, Double_t dphi, Int_t nedges, Int_t nz)
Make in one step a volume pointing to a polygone shape with given medium.
Definition TGeoBuilder.cxx:357

TGeoBuilder::MakeGtra
TGeoVolume * MakeGtra(const char *name, TGeoMedium *medium, Double_t dz, Double_t theta, Double_t phi, Double_t twist, Double_t h1, Double_t bl1, Double_t tl1, Double_t alpha1, Double_t h2, Double_t bl2, Double_t tl2, Double_t alpha2)
Make in one step a volume pointing to a twisted trapezoid shape with given medium.
Definition TGeoBuilder.cxx:413

TGeoBuilder::MakeXtru
TGeoVolume * MakeXtru(const char *name, TGeoMedium *medium, Int_t nz)
Make a TGeoXtru-shaped volume with nz planes.
Definition TGeoBuilder.cxx:424

TGeoBuilder::MakePcon
TGeoVolume * MakePcon(const char *name, TGeoMedium *medium, Double_t phi, Double_t dphi, Int_t nz)
Make in one step a volume pointing to a polycone shape with given medium.
Definition TGeoBuilder.cxx:346

TGeoBuilder::MakeTrap
TGeoVolume * MakeTrap(const char *name, TGeoMedium *medium, Double_t dz, Double_t theta, Double_t phi, Double_t h1, Double_t bl1, Double_t tl1, Double_t alpha1, Double_t h2, Double_t bl2, Double_t tl2, Double_t alpha2)
Make in one step a volume pointing to a trapezoid shape with given medium.
Definition TGeoBuilder.cxx:401

TGeoBuilder::AddShape
Int_t AddShape(TGeoShape *shape)
Add a shape to the list. Returns index of the shape in list.
Definition TGeoBuilder.cxx:116

TGeoBuilder::MakeTorus
TGeoVolume * MakeTorus(const char *name, TGeoMedium *medium, Double_t r, Double_t rmin, Double_t rmax, Double_t phi1=0, Double_t dphi=360)
Make in one step a volume pointing to a torus shape with given medium.
Definition TGeoBuilder.cxx:204

TGeoBuilder::Instance
static TGeoBuilder * Instance(TGeoManager *geom)
Return pointer to singleton.
Definition TGeoBuilder.cxx:73

TGeoBuilder::MakeEltu
TGeoVolume * MakeEltu(const char *name, TGeoMedium *medium, Double_t a, Double_t b, Double_t dz)
Make in one step a volume pointing to a tube shape with given medium.
Definition TGeoBuilder.cxx:251

TGeoBuilder::MakeHype
TGeoVolume * MakeHype(const char *name, TGeoMedium *medium, Double_t rin, Double_t stin, Double_t rout, Double_t stout, Double_t dz)
Make in one step a volume pointing to a tube shape with given medium.
Definition TGeoBuilder.cxx:267

TGeoBuilder::MakeArb8
TGeoVolume * MakeArb8(const char *name, TGeoMedium *medium, Double_t dz, Double_t *vertices=nullptr)
Make an TGeoArb8 volume.
Definition TGeoBuilder.cxx:145

TGeoBuilder::Material
TGeoMaterial * Material(const char *name, Double_t a, Double_t z, Double_t dens, Int_t uid, Double_t radlen=0, Double_t intlen=0)
Create material with given A, Z and density, having an unique id.
Definition TGeoBuilder.cxx:508

TGeoBuilder::~TGeoBuilder
~TGeoBuilder() override
Destructor.
Definition TGeoBuilder.cxx:65

TGeoBuilder::MakeTube
TGeoVolume * MakeTube(const char *name, TGeoMedium *medium, Double_t rmin, Double_t rmax, Double_t dz)
Make in one step a volume pointing to a tube shape with given medium.
Definition TGeoBuilder.cxx:215

TGeoBuilder::MakePara
TGeoVolume * MakePara(const char *name, TGeoMedium *medium, Double_t dx, Double_t dy, Double_t dz, Double_t alpha, Double_t theta, Double_t phi)
Make in one step a volume pointing to a parallelepiped shape with given medium.
Definition TGeoBuilder.cxx:171

TGeoBuilder::SetGeometry
void SetGeometry(TGeoManager *geom)
current geometry
Definition TGeoBuilder.h:37

TGeoBuilder::AddTransformation
Int_t AddTransformation(TGeoMatrix *matrix)
Add a matrix to the list. Returns index of the matrix in list.
Definition TGeoBuilder.cxx:102

TGeoBuilder::MakeSphere
TGeoVolume * MakeSphere(const char *name, TGeoMedium *medium, Double_t rmin, Double_t rmax, Double_t themin=0, Double_t themax=180, Double_t phimin=0, Double_t phimax=360)
Make in one step a volume pointing to a sphere shape with given medium.
Definition TGeoBuilder.cxx:193

TGeoBuilder::Medium
TGeoMedium * Medium(const char *name, Int_t numed, Int_t nmat, Int_t isvol, Int_t ifield, Double_t fieldm, Double_t tmaxfd, Double_t stemax, Double_t deemax, Double_t epsil, Double_t stmin)
Create tracking medium.
Definition TGeoBuilder.cxx:568

TGeoBuilder::MakeTubs
TGeoVolume * MakeTubs(const char *name, TGeoMedium *medium, Double_t rmin, Double_t rmax, Double_t dz, Double_t phi1, Double_t phi2)
Make in one step a volume pointing to a tube segment shape with given medium.
Definition TGeoBuilder.cxx:234

TGeoBuilder::MakeBox
TGeoVolume * MakeBox(const char *name, TGeoMedium *medium, Double_t dx, Double_t dy, Double_t dz)
Make in one step a volume pointing to a box shape with given medium.
Definition TGeoBuilder.cxx:155

TGeoBuilder::Matrix
void Matrix(Int_t index, Double_t theta1, Double_t phi1, Double_t theta2, Double_t phi2, Double_t theta3, Double_t phi3)
Create rotation matrix named 'mat<index>'.
Definition TGeoBuilder.cxx:497

TGeoBuilder::Division
TGeoVolume * Division(const char *name, const char *mother, Int_t iaxis, Int_t ndiv, Double_t start, Double_t step, Int_t numed=0, Option_t *option="")
Create a new volume by dividing an existing one (GEANT3 like)
Definition TGeoBuilder.cxx:463

TGeoBuilder::MakeParaboloid
TGeoVolume * MakeParaboloid(const char *name, TGeoMedium *medium, Double_t rlo, Double_t rhi, Double_t dz)
Make in one step a volume pointing to a tube shape with given medium.
Definition TGeoBuilder.cxx:284

TGeoBuilder::MakeTrd1
TGeoVolume * MakeTrd1(const char *name, TGeoMedium *medium, Double_t dx1, Double_t dx2, Double_t dy, Double_t dz)
Make in one step a volume pointing to a TGeoTrd1 shape with given medium.
Definition TGeoBuilder.cxx:368

TGeoBuilder::MakeVolumeAssembly
TGeoVolumeAssembly * MakeVolumeAssembly(const char *name)
Make an assembly of volumes.
Definition TGeoBuilder.cxx:435

TGeoBuilder::MakeCons
TGeoVolume * MakeCons(const char *name, TGeoMedium *medium, Double_t dz, Double_t rmin1, Double_t rmax1, Double_t rmin2, Double_t rmax2, Double_t phi1, Double_t phi2)
Make in one step a volume pointing to a cone segment shape with given medium.
Definition TGeoBuilder.cxx:329

TGeoBuilder::AddMaterial
Int_t AddMaterial(TGeoMaterial *material)
Add a material to the list. Returns index of the material in list.
Definition TGeoBuilder.cxx:88

TGeoBuilder::fGeometry
TGeoManager * fGeometry
Definition TGeoBuilder.h:35

TGeoBuilder::MakeVolumeMulti
TGeoVolumeMulti * MakeVolumeMulti(const char *name, TGeoMedium *medium)
Make a TGeoVolumeMulti handling a list of volumes.
Definition TGeoBuilder.cxx:443

TGeoBuilder::MakeTrd2
TGeoVolume * MakeTrd2(const char *name, TGeoMedium *medium, Double_t dx1, Double_t dx2, Double_t dy1, Double_t dy2, Double_t dz)
Make in one step a volume pointing to a TGeoTrd2 shape with given medium.
Definition TGeoBuilder.cxx:384

TGeoBuilder::Volume
TGeoVolume * Volume(const char *name, const char *shape, Int_t nmed, Float_t *upar, Int_t npar=0)
Create a volume in GEANT3 style.
Definition TGeoBuilder.cxx:886

TGeoBuilder::Mixture
TGeoMaterial * Mixture(const char *name, Float_t *a, Float_t *z, Double_t dens, Int_t nelem, Float_t *wmat, Int_t uid)
Create mixture OR COMPOUND IMAT as composed by THE BASIC nelem materials defined by arrays A,...
Definition TGeoBuilder.cxx:521

TGeoBuilder::MakeCone
TGeoVolume * MakeCone(const char *name, TGeoMedium *medium, Double_t dz, Double_t rmin1, Double_t rmax1, Double_t rmin2, Double_t rmax2)
Make in one step a volume pointing to a cone shape with given medium.
Definition TGeoBuilder.cxx:312

TGeoBuilder::RegisterMatrix
void RegisterMatrix(TGeoMatrix *matrix)
Register a matrix to the list of matrices.
Definition TGeoBuilder.cxx:133

TGeoBuilder::fgInstance
static TGeoBuilder * fgInstance
Definition TGeoBuilder.h:28

TGeoBuilder::MakeCtub
TGeoVolume * MakeCtub(const char *name, TGeoMedium *medium, 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)
Make in one step a volume pointing to a tube segment shape with given medium.
Definition TGeoBuilder.cxx:300

TGeoCombiTrans
Class describing rotation + translation.
Definition TGeoMatrix.h:317

TGeoConeSeg
A cone segment is a cone having a range in phi.
Definition TGeoCone.h:99

TGeoCone
The cones are defined by 5 parameters:
Definition TGeoCone.h:17

TGeoCtub
The cut tubes constructor has the form:
Definition TGeoTube.h:173

TGeoEltu
An elliptical tube is defined by the two semi-axes A and B.
Definition TGeoEltu.h:17

TGeoGtra
A twisted trapezoid.
Definition TGeoArb8.h:149

TGeoHype
A hyperboloid is represented as a solid limited by two planes perpendicular to the Z axis (top and bo...
Definition TGeoHype.h:17

TGeoManager
The manager class for any TGeo geometry.
Definition TGeoManager.h:44

TGeoManager::GetListOfGVolumes
TObjArray * GetListOfGVolumes() const
Definition TGeoManager.h:474

TGeoManager::GetListOfMatrices
TObjArray * GetListOfMatrices() const
Definition TGeoManager.h:470

TGeoManager::MakeVolumeMulti
TGeoVolumeMulti * MakeVolumeMulti(const char *name, TGeoMedium *medium)
Make a TGeoVolumeMulti handling a list of volumes.
Definition TGeoManager.cxx:3561

TGeoManager::GetListOfGShapes
TObjArray * GetListOfGShapes() const
Definition TGeoManager.h:476

TGeoManager::GetVolume
TGeoVolume * GetVolume(const char *name) const
Search for a named volume. All trailing blanks stripped.
Definition TGeoManager.cxx:2942

TGeoManager::FindVolumeFast
TGeoVolume * FindVolumeFast(const char *name, Bool_t multi=kFALSE)
Fast search for a named volume. All trailing blanks stripped.
Definition TGeoManager.cxx:2953

TGeoManager::GetMedium
TGeoMedium * GetMedium(const char *medium) const
Search for a named tracking medium. All trailing blanks stripped.
Definition TGeoManager.cxx:3022

TGeoManager::GetListOfMaterials
TList * GetListOfMaterials() const
Definition TGeoManager.h:471

TGeoManager::GetListOfShapes
TObjArray * GetListOfShapes() const
Definition TGeoManager.h:475

TGeoMaterial
Base class describing materials.
Definition TGeoMaterial.h:34

TGeoMaterial::SetIndex
void SetIndex(Int_t index)
Definition TGeoMaterial.h:142

TGeoMatrix
Geometrical transformation package.
Definition TGeoMatrix.h:38

TGeoMatrix::RegisterYourself
virtual void RegisterYourself()
Register the matrix in the current manager, which will become the owner.
Definition TGeoMatrix.cxx:516

TGeoMatrix::IsRegistered
Bool_t IsRegistered() const
Definition TGeoMatrix.h:72

TGeoMedium
Media are used to store properties related to tracking and which are useful only when using geometry ...
Definition TGeoMedium.h:23

TGeoMixture
Mixtures of elements.
Definition TGeoMaterial.h:159

TGeoMixture::DefineElement
void DefineElement(Int_t iel, Double_t a, Double_t z, Double_t weight)
Definition TGeoMaterial.h:226

TGeoPara
Parallelepiped class.
Definition TGeoPara.h:17

TGeoParaboloid
A paraboloid is defined by the revolution surface generated by a parabola and is bounded by two plane...
Definition TGeoParaboloid.h:17

TGeoPcon
A polycone is represented by a sequence of tubes/cones, glued together at defined Z planes.
Definition TGeoPcon.h:17

TGeoPgon
Polygons are defined in the same way as polycones, the difference being just that the segments betwee...
Definition TGeoPgon.h:20

TGeoRotation
Class describing rotations.
Definition TGeoMatrix.h:168

TGeoShape
Base abstract class for all shapes.
Definition TGeoShape.h:25

TGeoShape::IsRunTimeShape
Bool_t IsRunTimeShape() const
Definition TGeoShape.h:142

TGeoShape::Tolerance
static Double_t Tolerance()
Definition TGeoShape.h:90

TGeoSphere
TGeoSphere are not just balls having internal and external radii, but sectors of a sphere having defi...
Definition TGeoSphere.h:17

TGeoTorus
The torus is defined by its axial radius, its inner and outer radius.
Definition TGeoTorus.h:17

TGeoTranslation
Class describing translations.
Definition TGeoMatrix.h:116

TGeoTrap
A general trapezoid.
Definition TGeoArb8.h:96

TGeoTrd1
A trapezoid with only X varying with Z.
Definition TGeoTrd1.h:17

TGeoTrd2
A trapezoid with only X varying with Z.
Definition TGeoTrd2.h:17

TGeoTubeSeg
A tube segment is a tube having a range in phi.
Definition TGeoTube.h:94

TGeoTube
Cylindrical tube class.
Definition TGeoTube.h:17

TGeoVolumeAssembly
Volume assemblies.
Definition TGeoVolume.h:316

TGeoVolumeMulti
Volume families.
Definition TGeoVolume.h:266

TGeoVolumeMulti::AddVolume
void AddVolume(TGeoVolume *vol)
Add a volume with valid shape to the list of volumes.
Definition TGeoVolume.cxx:2591

TGeoVolume
TGeoVolume, TGeoVolumeMulti, TGeoVolumeAssembly are the volume classes.
Definition TGeoVolume.h:43

TGeoVolume::GetMedium
TGeoMedium * GetMedium() const
Definition TGeoVolume.h:175

TGeoVolume::AddNode
virtual TGeoNode * AddNode(TGeoVolume *vol, Int_t copy_no, TGeoMatrix *mat=nullptr, Option_t *option="")
Add a TGeoNode to the list of nodes.
Definition TGeoVolume.cxx:975

TGeoVolume::kVolumeMulti
@ kVolumeMulti
Definition TGeoVolume.h:77

TGeoVolume::AddNodeOverlap
virtual void AddNodeOverlap(TGeoVolume *vol, Int_t copy_no, TGeoMatrix *mat=nullptr, Option_t *option="")
Add a TGeoNode to the list of nodes.
Definition TGeoVolume.cxx:1044

TGeoVolume::SetShape
void SetShape(const TGeoShape *shape)
set the shape associated with this volume
Definition TGeoVolume.cxx:2067

TGeoVolume::GetShape
TGeoShape * GetShape() const
Definition TGeoVolume.h:190

TGeoVolume::Divide
virtual TGeoVolume * Divide(const char *divname, Int_t iaxis, Int_t ndiv, Double_t start, Double_t step, Int_t numed=0, Option_t *option="")
Division a la G3.
Definition TGeoVolume.cxx:1103

TGeoXtru
A TGeoXtru shape is represented by the extrusion of an arbitrary polygon with fixed outline between s...
Definition TGeoXtru.h:22

TIter
Definition TCollection.h:235

TList
A doubly linked list.
Definition TList.h:38

TList::Add
void Add(TObject *obj) override
Definition TList.h:83

TNamed::SetTitle
virtual void SetTitle(const char *title="")
Set the title of the TNamed.
Definition TNamed.cxx:164

TNamed::GetName
const char * GetName() const override
Returns name of object.
Definition TNamed.h:47

TNamed::GetTitle
const char * GetTitle() const override
Returns title of object.
Definition TNamed.h:48

TNamed::SetName
virtual void SetName(const char *name)
Set the name of the TNamed.
Definition TNamed.cxx:140

TObjArray
An array of TObjects.
Definition TObjArray.h:31

TObjArray::GetEntriesFast
Int_t GetEntriesFast() const
Definition TObjArray.h:58

TObjArray::AddAtAndExpand
virtual void AddAtAndExpand(TObject *obj, Int_t idx)
Add object at position idx.
Definition TObjArray.cxx:235

TObjArray::FindObject
TObject * FindObject(const char *name) const override
Find an object in this collection using its name.
Definition TObjArray.cxx:415

TObject
Mother of all ROOT objects.
Definition TObject.h:41

TObject::GetName
virtual const char * GetName() const
Returns name of object.
Definition TObject.cxx:439

TObject::TestBit
R__ALWAYS_INLINE Bool_t TestBit(UInt_t f) const
Definition TObject.h:199

TObject::GetUniqueID
virtual UInt_t GetUniqueID() const
Return the unique object id.
Definition TObject.cxx:457

TObject::Warning
virtual void Warning(const char *method, const char *msgfmt,...) const
Issue warning message.
Definition TObject.cxx:973

TObject::Error
virtual void Error(const char *method, const char *msgfmt,...) const
Issue error message.
Definition TObject.cxx:987

TObject::Fatal
virtual void Fatal(const char *method, const char *msgfmt,...) const
Issue fatal error message.
Definition TObject.cxx:1015

TObject::SetUniqueID
virtual void SetUniqueID(UInt_t uid)
Set the unique object id.
Definition TObject.cxx:791

TObject::Info
virtual void Info(const char *method, const char *msgfmt,...) const
Issue info message.
Definition TObject.cxx:961

TString
Basic string class.
Definition TString.h:139

TString::ToLower
void ToLower()
Change string to lower-case.
Definition TString.cxx:1182

TString::Strip
TSubString Strip(EStripType s=kTrailing, char c=' ') const
Return a substring of self stripped at beginning and/or end.
Definition TString.cxx:1163

TString::Data
const char * Data() const
Definition TString.h:376

TString::Contains
Bool_t Contains(const char *pat, ECaseCompare cmp=kExact) const
Definition TString.h:632

bool

double

int

unsigned int

box
void box(Int_t pat, Double_t x1, Double_t y1, Double_t x2, Double_t y2)
Definition fillpatterns.C:1

y
Double_t y[n]
Definition legend1.C:17

x
Double_t x[n]
Definition legend1.C:17

h1
TH1F * h1
Definition legend1.C:5

TMath::Abs
Short_t Abs(Short_t d)
Returns the absolute value of parameter Short_t d.
Definition TMathBase.h:123

shapes
Definition shapes.py:1