// function to convert this transformation to a TGeo transformation
// mainly used for the benchmark comparisons with ROOT
TGeoMatrix * Transformation3D::ConvertToTGeoMatrix() const
{
  if( fIdentity ){
      return new TGeoIdentity();
  }
  if( fHasTranslation && ! fHasRotation ) {
      return new TGeoTranslation(fTranslation[0], fTranslation[1], fTranslation[2]);
  }
  if( fHasRotation && ! fHasTranslation ) {
      TGeoRotation * tmp = new TGeoRotation();
      tmp->SetMatrix( Rotation() );
      return tmp;
  }
  if( fHasTranslation && fHasRotation )
  {
      TGeoRotation * tmp = new TGeoRotation();
      tmp->SetMatrix( Rotation() );
      return  new TGeoCombiTrans(fTranslation[0], fTranslation[1],
                     fTranslation[2], tmp);
  }
  return 0;
}
Exemple #2
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void Draw3D(AliITSOnlineCalibrationSPDhandler *h){

  TGeoHMatrix m2t[240];
  for(Int_t imod=0; imod<240; imod++){
    int vid = AliITSAlignMille2Module::GetVolumeIDFromIndex(imod);
    AliITSAlignMille2Module::SensVolMatrix(vid,&m2t[imod]);
  }

  delete gGeoManager;

  new TGeoManager("SPD","active");

  TGeoMaterial *vacuum = new TGeoMaterial("vacuum",0,0,0);
  TGeoMedium *none = new TGeoMedium("Vacuum",0,vacuum);
  TGeoVolume *top = gGeoManager->MakeBox("TOP",none,500,500,500);
  gGeoManager->SetTopVolume(top);

  TGeoVolume *ladder = gGeoManager->MakeBox("ladder",none,0.6375,0.001/2,3.48);

  Int_t nActive[2]={0,0};
  for(Int_t imod=0; imod<240; imod++){
    TGeoRotation *rot  = new TGeoRotation();
    rot->SetMatrix(m2t[imod].GetRotationMatrix());
    TGeoCombiTrans *matrix = new TGeoCombiTrans(m2t[imod].GetTranslation()[0],m2t[imod].GetTranslation()[1],m2t[imod].GetTranslation()[2],rot);
    if((40960-h->GetNrBad(imod))>0) {
      top->AddNode(ladder,imod,matrix);
      if(imod<80) nActive[0]++;
      else nActive[1]++;
    }
  }

  printf("  \n\n   Number of Active SPD modules (->Total)  : inner %i (80) outer %i (160) \n\n\n",nActive[0],nActive[1]);
  gGeoManager->CloseGeometry();
  top->Draw("ogl");
  gPad->GetView()->ShowAxis();

}
TGeoCombiTrans* GetGlobalPosition(TGeoCombiTrans *fRef)
{
  if (fLocalTrans == kTRUE ) {

    if ( ( fThetaX == 0 )  && ( fThetaY==0 )  && ( fThetaZ == 0 )
	 &&
	 ( fX == 0 ) && ( fY == 0 ) && ( fZ == 0 )
	 )  return fRef;


    // X axis
    Double_t xAxis[3] = { 1. , 0. , 0. };
    Double_t yAxis[3] = { 0. , 1. , 0. };
    Double_t zAxis[3] = { 0. , 0. , 1. };
    // Reference Rotation
    fRefRot = fRef->GetRotation();

    if (fRefRot) {
      Double_t mX[3] = {0.,0.,0.};
      Double_t mY[3] = {0.,0.,0.};
      Double_t mZ[3] = {0.,0.,0.};

      fRefRot->LocalToMasterVect(xAxis,mX);
      fRefRot->LocalToMasterVect(yAxis,mY);
      fRefRot->LocalToMasterVect(zAxis,mZ);

      Double_t a[4]={ mX[0],mX[1],mX[2], fThetaX };
      Double_t b[4]={ mY[0],mY[1],mY[2], fThetaY };
      Double_t c[4]={ mZ[0],mZ[1],mZ[2], fThetaZ };

      ROOT::Math::AxisAngle aX(a,a+4);
      ROOT::Math::AxisAngle aY(b,b+4);
      ROOT::Math::AxisAngle aZ(c,c+4);

      ROOT::Math::Rotation3D fMatX( aX );
      ROOT::Math::Rotation3D fMatY( aY );
      ROOT::Math::Rotation3D fMatZ( aZ );

      ROOT::Math::Rotation3D  fRotXYZ = (fMatZ * (fMatY * fMatX));

      //cout << fRotXYZ << endl;

      Double_t fRotable[9]={0.0,0.0,0.0,0.0,0.0,0.0,0.0,0.0,0.0};
      fRotXYZ.GetComponents(
			    fRotable[0],fRotable[3],fRotable[6],
			    fRotable[1],fRotable[4],fRotable[7],
			    fRotable[2],fRotable[5],fRotable[8]
			    );
      TGeoRotation *pRot = new TGeoRotation();
      pRot->SetMatrix(fRotable);
      TGeoCombiTrans *pTmp = new TGeoCombiTrans(*fGlobalTrans,*pRot);

      // ne peut pas etre applique ici
      // il faut differencier trans et rot dans la multi.
      TGeoRotation rot_id;
      rot_id.SetAngles(0.0,0.0,0.0);

      TGeoCombiTrans c1;
      c1.SetRotation(rot_id);
      const Double_t *t = pTmp->GetTranslation();
      c1.SetTranslation(t[0],t[1],t[2]);

      TGeoCombiTrans c2;
      c2.SetRotation(rot_id);
      const Double_t *tt = fRefRot->GetTranslation();
      c2.SetTranslation(tt[0],tt[1],tt[2]);

      TGeoCombiTrans cc = c1 * c2 ;

      TGeoCombiTrans c3;
      c3.SetRotation(pTmp->GetRotation());
      TGeoCombiTrans c4;
      c4.SetRotation(fRefRot);

      TGeoCombiTrans ccc = c3 * c4;

      TGeoCombiTrans pGlobal;
      pGlobal.SetRotation(ccc.GetRotation());
      const Double_t *allt = cc.GetTranslation();
      pGlobal.SetTranslation(allt[0],allt[1],allt[2]);

      return  ( new TGeoCombiTrans( pGlobal ) );

    }else{

      cout << "-E- R3BDetector::GetGlobalPosition() \
	      No. Ref. Transformation defined ! " << endl;
      cout << "-E- R3BDetector::GetGlobalPosition() \
	      cannot create Local Transformation " << endl;
      return NULL;
    } //! fRefRot

  } else {
    // Lab Transf.
    if ( ( fPhi == 0 )  && ( fTheta==0 )  && ( fPsi == 0 )
void EUTelGeometryTelescopeGeoDescription::translateSiPlane2TGeo(TGeoVolume* pvolumeWorld, int SensorId ) {
	double xc, yc, zc;   // volume center position 
	double alpha, beta, gamma;
	double rotRef1, rotRef2, rotRef3, rotRef4;

	std::stringstream strId;
	strId << SensorId;

	// Get sensor center position
	xc = siPlaneXPosition( SensorId );
	yc = siPlaneYPosition( SensorId );
	zc = siPlaneZPosition( SensorId );

	// Get sensor orientation
	alpha = siPlaneXRotation( SensorId ); //  in degrees !
	beta  = siPlaneYRotation( SensorId ); // 
	gamma = siPlaneZRotation( SensorId ); // 

	rotRef1 = siPlaneRotation1( SensorId );
	rotRef2 = siPlaneRotation2( SensorId );
	rotRef3 = siPlaneRotation3( SensorId );
	rotRef4 = siPlaneRotation4( SensorId );

	//We must check that the input is correct. Since this is a combination of initial rotations and reflections the determinate must be 1 or -1
	float determinant = rotRef1*rotRef4 - rotRef2*rotRef3  ;
	if(determinant==1 or determinant==-1) { 
		streamlog_out(DEBUG5) << "SensorID: " << SensorId << ". Determinant =  " <<determinant <<"  This is the correct determinate for this transformation." << std::endl;   
	} else {
		streamlog_out(ERROR5) << "SensorID: " << SensorId << ". Determinant =  " <<determinant << std::endl;   
		throw(lcio::Exception("The initial rotation and reflection matrix does not have determinant of 1 or -1. Gear file input must be wrong.")); 	
	}
	//Create spatial TGeoTranslation object.
	std::string stTranslationName = "matrixTranslationSensor";
	stTranslationName.append( strId.str() );
	TGeoTranslation* pMatrixTrans = new TGeoTranslation( stTranslationName.c_str(), xc, yc, zc );
	//ALL clsses deriving from TGeoMatrix are not owned by the ROOT geometry manager, invoking RegisterYourself() transfers
	//ownership and thus ROOT will clean up
	pMatrixTrans->RegisterYourself();      

	//Create TGeoRotation object. 
	//Translations are of course just positional changes in the global frame.
	//Note that each subsequent rotation is using the new coordinate system of the last transformation all the way back to the global frame.
	//The way to think about this is that each rotation is the multiplication of the last rotation matrix by a new one.
	//The order is:
	//Integer Z rotation and reflections.
	//Z rotations specified by in degrees.
	//X rotations 
	//Y rotations
	TGeoRotation* pMatrixRotRefCombined = new TGeoRotation();
	//We have to ensure that we retain a right handed coordinate system, i.e. if we only flip the x or y axis, we have to also flip the z-axis. If we flip both we have to flip twice.	
	double integerRotationsAndReflections[9]={rotRef1,rotRef2,0,rotRef3,rotRef4,0,0,0, determinant};
	pMatrixRotRefCombined->SetMatrix(integerRotationsAndReflections);
	std::cout << "Rotating plane " << SensorId << " to gamma: " << gamma << std::endl;
	pMatrixRotRefCombined->RotateZ(gamma);//Z Rotation (degrees)//This will again rotate a vector around z axis usign the right hand rule.  
	pMatrixRotRefCombined->RotateX(alpha);//X Rotations (degrees)//This will rotate a vector usign the right hand rule round the x-axis
	pMatrixRotRefCombined->RotateY(beta);//Y Rotations (degrees)//Same again for Y axis
	pMatrixRotRefCombined->RegisterYourself();//We must allow the matrix to be used by the TGeo manager.
	// Combined translation and orientation
	TGeoCombiTrans* combi = new TGeoCombiTrans( *pMatrixTrans, *pMatrixRotRefCombined );
	//This is to print to screen the rotation and translation matrices used to transform from local to global frame.
	streamlog_out(MESSAGE9) << "THESE MATRICES ARE USED TO TAKE A POINT IN THE LOCAL FRAME AND MOVE IT TO THE GLOBAL FRAME."  << std::endl;   
	streamlog_out(MESSAGE9) << "SensorID: " << SensorId << " Rotation/Reflection matrix for this object."  << std::endl;   
	const double* rotationMatrix =  combi->GetRotationMatrix();	
	streamlog_out(MESSAGE9) << std::setw(10) <<rotationMatrix[0]<<"  "<<rotationMatrix[1]<<"   "<<rotationMatrix[2]<< std::endl;
	streamlog_out(MESSAGE9) << std::setw(10) <<rotationMatrix[3]<<"  "<<rotationMatrix[4]<<"   "<<rotationMatrix[5]<< std::endl;
	streamlog_out(MESSAGE9) << std::setw(10) <<rotationMatrix[6]<<"  "<<rotationMatrix[7]<<"   "<<rotationMatrix[8]<< std::endl;

	//streamlog_out(MESSAGE9) << std::setw(10) <<rotationMatrix[0] << std::setw(10) <<rotationMatrix[1]<< std::setw(10) <<rotationMatrix[2]<< std::setw(10)<< std::endl<< std::endl; 
	//streamlog_out(MESSAGE9) << std::setw(10) <<rotationMatrix[3] << std::setw(10) <<rotationMatrix[4]<< std::setw(10) <<rotationMatrix[5]<< std::setw(10)<< std::endl<< std::endl; 
	//streamlog_out(MESSAGE9) << std::setw(10) <<rotationMatrix[6] << std::setw(10) <<rotationMatrix[7]<< std::setw(10) <<rotationMatrix[8]<< std::setw(10)<< std::endl<< std::endl; 
	const double* translationMatrix =  combi->GetTranslation();	
	streamlog_out(MESSAGE9) << "SensorID: " << SensorId << " Translation vector for this object."  << std::endl;   
	streamlog_out(MESSAGE9) << std::setw(10) <<translationMatrix[0] << std::setw(10) <<translationMatrix[1]<< std::setw(10) <<translationMatrix[2]<< std::setw(10)<< std::endl; 

	combi->RegisterYourself();   
	
	// Construct object medium. Required for radiation length determination
	// assume SILICON, though all information except of radiation length is ignored
	double a       = 28.085500;     
	double z       = 14.000000;
	double density = 2.330000;
	double radl    = siPlaneRadLength( SensorId );
	double absl    = 45.753206;
	std::string stMatName = "materialSensor";
	stMatName.append( strId.str() );
	TGeoMaterial* pMat = new TGeoMaterial( stMatName.c_str(), a, z, density, -radl, absl );
	pMat->SetIndex( 1 );
	// Medium: medium_Sensor_SILICON
	int numed   = 0;  // medium number
	double par[8];
	par[0]  = 0.000000; // isvol
	par[1]  = 0.000000; // ifield
	par[2]  = 0.000000; // fieldm
	par[3]  = 0.000000; // tmaxfd
	par[4]  = 0.000000; // stemax
	par[5]  = 0.000000; // deemax
	par[6]  = 0.000000; // epsil
	par[7]  = 0.000000; // stmin
	std::string stMedName = "mediumSensor";
	stMedName.append( strId.str() );
	TGeoMedium* pMed = new TGeoMedium( stMedName.c_str(), numed, pMat, par );

	// Construct object shape
	// Shape: Box type: TGeoBBox
	// TGeo requires half-width of box side
	Double_t dx = siPlaneXSize( SensorId ) / 2.;
	Double_t dy = siPlaneYSize( SensorId ) / 2.;
	Double_t dz = siPlaneZSize( SensorId ) / 2.;
	TGeoShape *pBoxSensor = new TGeoBBox( "BoxSensor", dx, dy, dz );

	std::cout << "Box for sensor: " << SensorId << " is: " << dx << "|" << dy  << "|" << dz << '\n';

	// Geometry navigation package requires following names for objects that have an ID  name:ID
	std::string stVolName = "volume_SensorID:";
	stVolName.append( strId.str() );

	_planePath.insert( std::make_pair(SensorId, "/volume_World_1/"+stVolName+"_1") );

	TGeoVolume* pvolumeSensor = new TGeoVolume( stVolName.c_str(), pBoxSensor, pMed );
	pvolumeSensor->SetVisLeaves( kTRUE );
	pvolumeWorld->AddNode(pvolumeSensor, 1/*(SensorId)*/, combi);

	//this line tells the pixel geometry manager to load the pixel geometry into the plane			
	streamlog_out(DEBUG1) << " sensorID: " << SensorId << " " << stVolName << std::endl;   
	std::string name = geoLibName(SensorId);

	if( name == "CAST" ) {
		_pixGeoMgr->addCastedPlane( SensorId, siPlaneXNpixels(SensorId), siPlaneYNpixels(SensorId), siPlaneXSize(SensorId), siPlaneYSize(SensorId), siPlaneZSize(SensorId), siPlaneRadLength(SensorId), stVolName);
	} else {
		_pixGeoMgr->addPlane( SensorId, name, stVolName);
		updatePlaneInfo(SensorId);
	}
}