TGeoShapeAssembly.cxx

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// @(#)root/geom:$Id$
// Author: Andrei Gheata   02/06/05

/*************************************************************************
 * 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 "Riostream.h"

#include "TGeoManager.h"
#include "TGeoVoxelFinder.h"
#include "TGeoMatrix.h"
#include "TGeoVolume.h"
#include "TGeoNode.h"
#include "TGeoShapeAssembly.h"
#include "TBuffer3D.h"
#include "TBuffer3DTypes.h"
#include "TMath.h"

/** \class TGeoShapeAssembly
\ingroup Geometry_classes

The shape encapsulating an assembly (union) of volumes.
Automatically created by TGeoVolumeAssembly class
*/

ClassImp(TGeoShapeAssembly);

////////////////////////////////////////////////////////////////////////////////
/// Default constructor

TGeoShapeAssembly::TGeoShapeAssembly()
{
   fVolume  = 0;
   fBBoxOK = kFALSE;
}


////////////////////////////////////////////////////////////////////////////////
/// Constructor specifying hyperboloid parameters.

TGeoShapeAssembly::TGeoShapeAssembly(TGeoVolumeAssembly *vol)
{
   fVolume  = vol;
   fBBoxOK = kFALSE;
}


////////////////////////////////////////////////////////////////////////////////
/// destructor

TGeoShapeAssembly::~TGeoShapeAssembly()
{
}

////////////////////////////////////////////////////////////////////////////////
/// Compute bounding box of the assembly

void TGeoShapeAssembly::ComputeBBox()
{
   if (!fVolume) {
      Fatal("ComputeBBox", "Assembly shape %s without volume", GetName());
      return;
   }
   // Make sure bbox is computed only once or recomputed only if invalidated (by alignment)
   if (fBBoxOK) return;
   Int_t nd = fVolume->GetNdaughters();
   if (!nd) {fBBoxOK = kTRUE; return;}
   TGeoNode *node;
   TGeoBBox *box;
   Double_t xmin, xmax, ymin, ymax, zmin, zmax;
   xmin = ymin = zmin = TGeoShape::Big();
   xmax = ymax = zmax = -TGeoShape::Big();
   Double_t vert[24];
   Double_t pt[3];
   for (Int_t i=0; i<nd; i++) {
      node = fVolume->GetNode(i);
      // Make sure that all assembly daughters have computed their bboxes
      if (node->GetVolume()->IsAssembly()) node->GetVolume()->GetShape()->ComputeBBox();
      box = (TGeoBBox*)node->GetVolume()->GetShape();
      box->SetBoxPoints(vert);
      for (Int_t ipt=0; ipt<8; ipt++) {
         node->LocalToMaster(&vert[3*ipt], pt);
         if (pt[0]<xmin) xmin=pt[0];
         if (pt[0]>xmax) xmax=pt[0];
         if (pt[1]<ymin) ymin=pt[1];
         if (pt[1]>ymax) ymax=pt[1];
         if (pt[2]<zmin) zmin=pt[2];
         if (pt[2]>zmax) zmax=pt[2];
      }
   }
   fDX = 0.5*(xmax-xmin);
   fOrigin[0] = 0.5*(xmin+xmax);
   fDY = 0.5*(ymax-ymin);
   fOrigin[1] = 0.5*(ymin+ymax);
   fDZ = 0.5*(zmax-zmin);
   fOrigin[2] = 0.5*(zmin+zmax);
   if (fDX>0 && fDY>0 && fDZ>0) fBBoxOK = kTRUE;
}

////////////////////////////////////////////////////////////////////////////////
/// Recompute bounding box of the assembly after adding a node.

void TGeoShapeAssembly::RecomputeBoxLast()
{
   Int_t nd = fVolume->GetNdaughters();
   if (!nd) {
      Warning("RecomputeBoxLast", "No daughters for volume %s yet", fVolume->GetName());
      return;
   }
   TGeoNode *node = fVolume->GetNode(nd-1);
   Double_t xmin, xmax, ymin, ymax, zmin, zmax;
   if (nd==1) {
      xmin = ymin = zmin = TGeoShape::Big();
      xmax = ymax = zmax = -TGeoShape::Big();
   } else {
      xmin = fOrigin[0]-fDX;
      xmax = fOrigin[0]+fDX;
      ymin = fOrigin[1]-fDY;
      ymax = fOrigin[1]+fDY;
      zmin = fOrigin[2]-fDZ;
      zmax = fOrigin[2]+fDZ;
   }
   Double_t vert[24];
   Double_t pt[3];
   TGeoBBox *box = (TGeoBBox*)node->GetVolume()->GetShape();
   if (TGeoShape::IsSameWithinTolerance(box->GetDX(), 0) ||
       node->GetVolume()->IsAssembly()) node->GetVolume()->GetShape()->ComputeBBox();
   box->SetBoxPoints(vert);
   for (Int_t ipt=0; ipt<8; ipt++) {
      node->LocalToMaster(&vert[3*ipt], pt);
      if (pt[0]<xmin) xmin=pt[0];
      if (pt[0]>xmax) xmax=pt[0];
      if (pt[1]<ymin) ymin=pt[1];
      if (pt[1]>ymax) ymax=pt[1];
      if (pt[2]<zmin) zmin=pt[2];
      if (pt[2]>zmax) zmax=pt[2];
   }
   fDX = 0.5*(xmax-xmin);
   fOrigin[0] = 0.5*(xmin+xmax);
   fDY = 0.5*(ymax-ymin);
   fOrigin[1] = 0.5*(ymin+ymax);
   fDZ = 0.5*(zmax-zmin);
   fOrigin[2] = 0.5*(zmin+zmax);
   fBBoxOK = kTRUE;
}

////////////////////////////////////////////////////////////////////////////////
/// Compute normal to closest surface from POINT. Should not be called.

void TGeoShapeAssembly::ComputeNormal(const Double_t *point, const Double_t *dir, Double_t *norm)
{
   if (!fBBoxOK) ((TGeoShapeAssembly*)this)->ComputeBBox();
   Int_t inext = fVolume->GetNextNodeIndex();
   if (inext<0) {
      DistFromOutside(point,dir,3);
      inext = fVolume->GetNextNodeIndex();
      if (inext<0) {
         Error("ComputeNormal","Invalid inext=%i (Ncomponents=%i)",inext,fVolume->GetNdaughters());
         return;
      }
   }
   TGeoNode *node = fVolume->GetNode(inext);
   Double_t local[3],ldir[3],lnorm[3];
   node->MasterToLocal(point,local);
   node->MasterToLocalVect(dir,ldir);
   node->GetVolume()->GetShape()->ComputeNormal(local,ldir,lnorm);
   node->LocalToMasterVect(lnorm,norm);
}

////////////////////////////////////////////////////////////////////////////////
/// Test if point is inside the assembly

Bool_t TGeoShapeAssembly::Contains(const Double_t *point) const
{
   if (!fBBoxOK) ((TGeoShapeAssembly*)this)->ComputeBBox();
   if (!TGeoBBox::Contains(point)) return kFALSE;
   TGeoVoxelFinder *voxels = fVolume->GetVoxels();
   TGeoNode *node;
   TGeoShape *shape;
   Int_t *check_list = 0;
   Int_t ncheck, id;
   Double_t local[3];
   if (voxels) {
      // get the list of nodes passing thorough the current voxel
      TGeoNavigator *nav = gGeoManager->GetCurrentNavigator();
      TGeoStateInfo &td = *nav->GetCache()->GetInfo();
      check_list = voxels->GetCheckList(point, ncheck, td);
      if (!check_list) {
         nav->GetCache()->ReleaseInfo();
         return kFALSE;
      }
      for (id=0; id<ncheck; id++) {
         node = fVolume->GetNode(check_list[id]);
         shape = node->GetVolume()->GetShape();
         node->MasterToLocal(point,local);
         if (shape->Contains(local)) {
            fVolume->SetCurrentNodeIndex(check_list[id]);
            fVolume->SetNextNodeIndex(check_list[id]);
            nav->GetCache()->ReleaseInfo();
            return kTRUE;
         }
      }
      nav->GetCache()->ReleaseInfo();
      return kFALSE;
   }
   Int_t nd = fVolume->GetNdaughters();
   for (id=0; id<nd; id++) {
      node = fVolume->GetNode(id);
      shape = node->GetVolume()->GetShape();
      node->MasterToLocal(point,local);
      if (shape->Contains(local)) {
         fVolume->SetCurrentNodeIndex(id);
         fVolume->SetNextNodeIndex(id);
         return kTRUE;
      }
   }
   return kFALSE;
}

////////////////////////////////////////////////////////////////////////////////
/// compute closest distance from point px,py to each vertex. Should not be called.

Int_t TGeoShapeAssembly::DistancetoPrimitive(Int_t /*px*/, Int_t /*py*/)
{
   return 9999;
}

////////////////////////////////////////////////////////////////////////////////
/// Compute distance from inside point to surface of the hyperboloid.

Double_t TGeoShapeAssembly::DistFromInside(const Double_t * /*point*/, const Double_t * /*dir*/, Int_t /*iact*/, Double_t /*step*/, Double_t * /*safe*/) const
{
   Info("DistFromInside", "Cannot compute distance from inside the assembly (but from a component)");
   return TGeoShape::Big();
}


////////////////////////////////////////////////////////////////////////////////
/// compute distance from outside point to surface of the hyperboloid.
///   fVolume->SetNextNodeIndex(-1);

Double_t TGeoShapeAssembly::DistFromOutside(const Double_t *point, const Double_t *dir, Int_t iact, Double_t step, Double_t *safe) const
{
#ifdef TGEO_DEBUG
   static int indent=0;
   indent++;
   TString sindent = "";
   for (Int_t k=0; k<indent; k++) sindent += "  ";
   Int_t idebug = TGeoManager::GetVerboseLevel();
#endif
   if (!fBBoxOK) ((TGeoShapeAssembly*)this)->ComputeBBox();
   if (iact<3 && safe) {
      *safe = Safety(point, kFALSE);
#ifdef TGEO_DEBUG
      indent--;
#endif
      if (iact==0) return TGeoShape::Big();
      if ((iact==1) && (step<=*safe)) return TGeoShape::Big();
#ifdef TGEO_DEBUG
      indent++;
#endif
   }
   // find distance to assembly
   Double_t snext = 0.0;
   Double_t dist;
   Double_t stepmax = step;
   Double_t pt[3];
   Int_t i;
   Bool_t found = kFALSE;
   memcpy(pt,point,3*sizeof(Double_t));
#ifdef TGEO_DEBUG
   if (idebug>4) printf("%s[%d] assembly %s checking distance to %d daughters...\n", sindent.Data(), indent, fVolume->GetName(), fVolume->GetNdaughters());
#endif

   if (!TGeoBBox::Contains(point)) {
      snext = TGeoBBox::DistFromOutside(point, dir, 3, stepmax);
      // Approach bounding box to minimize errors
      snext = TMath::Min(0.01*snext, 1.E-6);
#ifdef TGEO_DEBUG
      if (idebug>4 && snext > stepmax) printf("%s[%d] %s: bbox not crossed\n",sindent.Data(), indent, fVolume->GetName());
      indent--;
#endif
      if (snext > stepmax) return TGeoShape::Big();
#ifdef TGEO_DEBUG
      indent++;
#endif
      for (i=0; i<3; i++) pt[i] += snext*dir[i];
//      if (Contains(pt)) {
#ifdef TGEO_DEBUG
//         if (idebug>4) printf("%s[%d] Propagation to BBox of %s entered the component %s at %f\n", sindent.Data(), indent, fVolume->GetName(), fVolume->GetNode(fVolume->GetCurrentNodeIndex())->GetName(), snext);
//         indent--;
#endif
//         fVolume->SetNextNodeIndex(fVolume->GetCurrentNodeIndex());
//         return snext;
//      }
//      snext += TGeoShape::Tolerance();
      stepmax -= snext;
   }
   // Point represented by pt is now inside the bounding box - find distance to components
   Int_t nd = fVolume->GetNdaughters();
   TGeoNode *node;
   Double_t lpoint[3],ldir[3];
   TGeoVoxelFinder *voxels = fVolume->GetVoxels();
   if (nd<5 || !voxels) {
      for (i=0; i<nd; i++) {
         node = fVolume->GetNode(i);
         if (voxels && voxels->IsSafeVoxel(pt, i, stepmax)) continue;
         node->MasterToLocal(pt, lpoint);
         node->MasterToLocalVect(dir, ldir);
#ifdef TGEO_DEBUG
         if (idebug>4) printf("%s[%d] distance to %s ...\n", sindent.Data(), indent, node->GetName());
#endif
         dist = node->GetVolume()->GetShape()->DistFromOutside(lpoint, ldir, 3, stepmax);
         if (dist<stepmax) {
#ifdef TGEO_DEBUG
            if (idebug>4) {
               printf("%s[%d] %s -> from local=(%19.16f, %19.16f, %19.16f, %19.16f, %19.16f, %19.16f)\n",
                      sindent.Data(), indent, fVolume->GetName(), lpoint[0],lpoint[1],lpoint[2],ldir[0],ldir[1],ldir[2]);
               printf("%s[%d] -> (l)to: %s shape %s snext=%g\n", sindent.Data(), indent, node->GetName(),
                      node->GetVolume()->GetShape()->ClassName(), dist);
            }
#endif

            stepmax = dist;
            fVolume->SetNextNodeIndex(i);
            found = kTRUE;
         }
      }
      if (found) {
         snext += stepmax;
#ifdef TGEO_DEBUG
         if (idebug>4) printf("%s[%d] %s: found %s at %f\n", sindent.Data(), indent, fVolume->GetName(), fVolume->GetNode(fVolume->GetNextNodeIndex())->GetName(), snext);
         indent--;
#endif
         return snext;
      }
#ifdef TGEO_DEBUG
      if (idebug>4) printf("%s[%d] %s: no daughter crossed\n", sindent.Data(), indent, fVolume->GetName());
      indent--;
#endif
      return TGeoShape::Big();
   }
   // current volume is voxelized, first get current voxel
   Int_t ncheck = 0;
   Int_t *vlist = 0;
   TGeoNavigator *nav = gGeoManager->GetCurrentNavigator();
   TGeoStateInfo &td = *nav->GetCache()->GetInfo();

   voxels->SortCrossedVoxels(pt, dir, td);
   while ((vlist=voxels->GetNextVoxel(pt, dir, ncheck, td))) {
      for (i=0; i<ncheck; i++) {
         node = fVolume->GetNode(vlist[i]);
         node->MasterToLocal(pt, lpoint);
         node->MasterToLocalVect(dir, ldir);
#ifdef TGEO_DEBUG
         if (idebug>4) printf("%s[%d] distance to %s ...\n", sindent.Data(), indent, node->GetName());
#endif
         dist = node->GetVolume()->GetShape()->DistFromOutside(lpoint, ldir, 3, stepmax);
         if (dist<stepmax) {
#ifdef TGEO_DEBUG
            if (idebug>4) {
               printf("%s[%d] %s -> from local=(%19.16f, %19.16f, %19.16f, %19.16f, %19.16f, %19.16f)\n",
                      sindent.Data(), indent, fVolume->GetName(), lpoint[0],lpoint[1],lpoint[2], ldir[0],ldir[1],ldir[2]);
               printf("%s[%d] -> to: %s shape %s snext=%g\n", sindent.Data(), indent, node->GetName(),
                      node->GetVolume()->GetShape()->ClassName(), dist);
            }
#endif
            stepmax = dist;
            fVolume->SetNextNodeIndex(vlist[i]);
            found = kTRUE;
         }
      }
   }
   nav->GetCache()->ReleaseInfo();
   if (found) {
      snext += stepmax;
#ifdef TGEO_DEBUG
      if (idebug>4) printf("%s[%d] %s: found %s at %f\n", sindent.Data(), indent, fVolume->GetName(), fVolume->GetNode(fVolume->GetNextNodeIndex())->GetName(), snext);
      indent--;
#endif
      return snext;
   }
#ifdef TGEO_DEBUG
   if (idebug>4) printf("%s[%d] %s: no daughter crossed\n", sindent.Data(), indent, fVolume->GetName());
   indent--;
#endif
   return TGeoShape::Big();
}

////////////////////////////////////////////////////////////////////////////////
/// Cannot divide assemblies.

TGeoVolume *TGeoShapeAssembly::Divide(TGeoVolume * /*voldiv*/, const char *divname, Int_t /*iaxis*/, Int_t /*ndiv*/,
                             Double_t /*start*/, Double_t /*step*/)
{
   Error("Divide", "Assemblies cannot be divided. Division volume %s not created", divname);
   return 0;
}

////////////////////////////////////////////////////////////////////////////////
/// in case shape has some negative parameters, these has to be computed
/// in order to fit the mother

TGeoShape *TGeoShapeAssembly::GetMakeRuntimeShape(TGeoShape * /*mother*/, TGeoMatrix * /*mat*/) const
{
   Error("GetMakeRuntimeShape", "Assemblies cannot be parametrized.");
   return NULL;
}

////////////////////////////////////////////////////////////////////////////////
/// print shape parameters

void TGeoShapeAssembly::InspectShape() const
{
   printf("*** Shape %s: TGeoShapeAssembly ***\n", GetName());
   printf("    Volume assembly %s with %i nodes\n", fVolume->GetName(), fVolume->GetNdaughters());
   printf(" Bounding box:\n");
   if (!fBBoxOK) ((TGeoShapeAssembly*)this)->ComputeBBox();
   TGeoBBox::InspectShape();
}

////////////////////////////////////////////////////////////////////////////////
/// Fill TBuffer3D structure for segments and polygons.

void TGeoShapeAssembly::SetSegsAndPols(TBuffer3D & /*buff*/) const
{
   Error("SetSegsAndPols", "Drawing functions should not be called for assemblies, but rather for their content");
}

////////////////////////////////////////////////////////////////////////////////
/// 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 TGeoShapeAssembly::Safety(const Double_t *point, Bool_t in) const
{
   Double_t safety = TGeoShape::Big();
   Double_t pt[3], loc[3];
   if (!fBBoxOK) ((TGeoShapeAssembly*)this)->ComputeBBox();
   if (in) {
      Int_t index = fVolume->GetCurrentNodeIndex();
      TGeoVolume *vol = fVolume;
      TGeoNode *node;
      memcpy(loc, point, 3*sizeof(Double_t));
      while (index>=0) {
         memcpy(pt, loc, 3*sizeof(Double_t));
         node = vol->GetNode(index);
         node->GetMatrix()->MasterToLocal(pt,loc);
         vol = node->GetVolume();
         index = vol->GetCurrentNodeIndex();
         if (index<0) {
            safety = vol->GetShape()->Safety(loc, in);
            return safety;
         }
      }
      return TGeoShape::Big();
   }
   Double_t safe;
   TGeoVoxelFinder *voxels = fVolume->GetVoxels();
   Int_t nd = fVolume->GetNdaughters();
   Double_t *boxes = 0;
   if (voxels) boxes = voxels->GetBoxes();
   TGeoNode *node;
   for (Int_t id=0; id<nd; id++) {
      if (boxes && id>0) {
         Int_t ist = 6*id;
         Double_t dxyz = 0.;
         Double_t dxyz0 = TMath::Abs(point[0]-boxes[ist+3])-boxes[ist];
         if (dxyz0 > safety) continue;
         Double_t dxyz1 = TMath::Abs(point[1]-boxes[ist+4])-boxes[ist+1];
         if (dxyz1 > safety) continue;
         Double_t dxyz2 = TMath::Abs(point[2]-boxes[ist+5])-boxes[ist+2];
         if (dxyz2 > safety) continue;
         if (dxyz0>0) dxyz+=dxyz0*dxyz0;
         if (dxyz1>0) dxyz+=dxyz1*dxyz1;
         if (dxyz2>0) dxyz+=dxyz2*dxyz2;
         if (dxyz >= safety*safety) continue;
      }
      node = fVolume->GetNode(id);
      safe = node->Safety(point, kFALSE);
      if (safe<=0.0) return 0.0;
      if (safe<safety) safety = safe;
   }
   return safety;
}

////////////////////////////////////////////////////////////////////////////////
/// Save a primitive as a C++ statement(s) on output stream "out".

void TGeoShapeAssembly::SavePrimitive(std::ostream & /*out*/, Option_t * /*option*/ /*= ""*/)
{
}

////////////////////////////////////////////////////////////////////////////////
/// No mesh for assemblies.

void TGeoShapeAssembly::SetPoints(Double_t * /*points*/) const
{
   Error("SetPoints", "Drawing functions should not be called for assemblies, but rather for their content");
}

////////////////////////////////////////////////////////////////////////////////
/// No mesh for assemblies.

void TGeoShapeAssembly::SetPoints(Float_t * /*points*/) const
{
   Error("SetPoints", "Drawing functions should not be called for assemblies, but rather for their content");
}

////////////////////////////////////////////////////////////////////////////////
/// Returns numbers of vertices, segments and polygons composing the shape mesh.

void TGeoShapeAssembly::GetMeshNumbers(Int_t &nvert, Int_t &nsegs, Int_t &npols) const
{
   nvert = 0;
   nsegs = 0;
   npols = 0;
}

////////////////////////////////////////////////////////////////////////////////
/// 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 TGeoShapeAssembly::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 TGeoShapeAssembly::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 TGeoShapeAssembly::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 TGeoShapeAssembly::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 TGeoShapeAssembly::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]);
}