#include <Alignment/MuonAlignment/interface/MuonAlignmentOutputXML.h>

Public Member Functions
	MuonAlignmentOutputXML (const edm::ParameterSet &iConfig)

void	write (AlignableMuon *alignableMuon, const edm::EventSetup &iSetup) const

virtual	~MuonAlignmentOutputXML ()

Private Member Functions
	MuonAlignmentOutputXML (const MuonAlignmentOutputXML &)

const MuonAlignmentOutputXML &	operator= (const MuonAlignmentOutputXML &)

void	writeComponents (align::Alignables &alignables, align::Alignables &ideals, std::map< align::ID, CLHEP::HepSymMatrix > &errors, std::ofstream &outputFile, bool DT) const

Private Attributes
bool	m_eulerAngles

std::string	m_fileName

int	m_precision

bool	m_rawIds

int	m_relativeto

bool	m_suppressCSCChambers

bool	m_suppressCSCEndcaps

bool	m_suppressCSCLayers

bool	m_suppressCSCRings

bool	m_suppressCSCStations

bool	m_suppressDTBarrel

bool	m_suppressDTChambers

bool	m_suppressDTLayers

bool	m_suppressDTStations

bool	m_suppressDTSuperLayers

bool	m_suppressDTWheels

bool	m_survey

Detailed Description

Description: <one line="" class="" summary>="">

Usage: <usage>

Definition at line 34 of file MuonAlignmentOutputXML.h.

Constructor & Destructor Documentation

MuonAlignmentOutputXML::MuonAlignmentOutputXML ( const edm::ParameterSet & iConfig )

Definition at line 44 of file MuonAlignmentOutputXML.cc.

References Exception, edm::ParameterSet::getParameter(), m_relativeto, and AlCaHLTBitMon_QueryRunRegistry::string.

    : m_fileName(iConfig.getParameter<std::string>("fileName"))
    , m_survey(iConfig.getParameter<bool>("survey"))
    , m_rawIds(iConfig.getParameter<bool>("rawIds"))
    , m_eulerAngles(iConfig.getParameter<bool>("eulerAngles"))
    , m_precision(iConfig.getParameter<int>("precision"))
    , m_suppressDTBarrel(iConfig.getUntrackedParameter<bool>("suppressDTBarrel", false))
    , m_suppressDTWheels(iConfig.getUntrackedParameter<bool>("suppressDTWheels", false))
    , m_suppressDTStations(iConfig.getUntrackedParameter<bool>("suppressDTStations", false))
    , m_suppressDTChambers(iConfig.getUntrackedParameter<bool>("suppressDTChambers", false))
    , m_suppressDTSuperLayers(iConfig.getUntrackedParameter<bool>("suppressDTSuperLayers", false))
    , m_suppressDTLayers(iConfig.getUntrackedParameter<bool>("suppressDTLayers", false))
    , m_suppressCSCEndcaps(iConfig.getUntrackedParameter<bool>("suppressCSCEndcaps", false))
    , m_suppressCSCStations(iConfig.getUntrackedParameter<bool>("suppressCSCStations", false))
    , m_suppressCSCRings(iConfig.getUntrackedParameter<bool>("suppressCSCRings", false))
    , m_suppressCSCChambers(iConfig.getUntrackedParameter<bool>("suppressCSCChambers", false))
    , m_suppressCSCLayers(iConfig.getUntrackedParameter<bool>("suppressCSCLayers", false))
 {
    std::string str_relativeto = iConfig.getParameter<std::string>("relativeto");
 
    if (str_relativeto == std::string("none")) {
       m_relativeto = 0;
    }
    else if (str_relativeto == std::string("ideal")) {
       m_relativeto = 1;
    }
    else if (str_relativeto == std::string("container")) {
       m_relativeto = 2;
    }
    else {
       throw cms::Exception("BadConfig") << "relativeto must be \"none\", \"ideal\", or \"container\"" << std::endl;
    }
 }

MuonAlignmentOutputXML::~MuonAlignmentOutputXML ( )

virtual

Definition at line 83 of file MuonAlignmentOutputXML.cc.

84 {

85 }

MuonAlignmentOutputXML::MuonAlignmentOutputXML ( const MuonAlignmentOutputXML & )

private

Member Function Documentation

const MuonAlignmentOutputXML& MuonAlignmentOutputXML::operator= ( const MuonAlignmentOutputXML & )

private

void MuonAlignmentOutputXML::write	(	AlignableMuon *	alignableMuon,
		const edm::EventSetup &	iSetup
	)		const

Definition at line 103 of file MuonAlignmentOutputXML.cc.

References CSCGeometryBuilderFromDDD::build(), DTGeometryBuilderFromDDD::build(), AlignableMuon::cscAlignmentErrorsExtended(), AlignableMuon::CSCEndcaps(), AlignableMuon::dtAlignmentErrorsExtended(), AlignableMuon::DTBarrel(), benchmark_cfg::errors, edm::EventSetup::get(), AlignmentErrorsExtended::m_alignError, m_fileName, m_precision, m_relativeto, download_sqlite_cfg::outputFile, and writeComponents().

Referenced by pkg.AbstractPkg::generate(), querying.connection::write_and_commit(), and MuonAlignment::writeXML().

                                                                                                   {
    std::ofstream outputFile(m_fileName.c_str());
    outputFile << std::setprecision(m_precision) << std::fixed;
 
    outputFile << "<?xml version=\"1.0\" encoding=\"UTF-8\"?>" << std::endl;
    outputFile << "<?xml-stylesheet type=\"text/xml\" href=\"MuonAlignment.xsl\"?>" << std::endl;
    outputFile << "<MuonAlignment>" << std::endl << std::endl;
    
    std::map<align::ID, CLHEP::HepSymMatrix> errors;
    AlignmentErrorsExtended *dtErrors = alignableMuon->dtAlignmentErrorsExtended();
    AlignmentErrorsExtended *cscErrors = alignableMuon->cscAlignmentErrorsExtended();
    for (std::vector<AlignTransformErrorExtended>::const_iterator dtError = dtErrors->m_alignError.begin();  dtError != dtErrors->m_alignError.end();  ++dtError) {
       errors[dtError->rawId()] = dtError->matrix();
    }
    for (std::vector<AlignTransformErrorExtended>::const_iterator cscError = cscErrors->m_alignError.begin();  cscError != cscErrors->m_alignError.end();  ++cscError) {
       errors[cscError->rawId()] = cscError->matrix();
    }
 
    align::Alignables barrels = alignableMuon->DTBarrel();
    align::Alignables endcaps = alignableMuon->CSCEndcaps();
 
    if (m_relativeto == 1) {
       edm::ESTransientHandle<DDCompactView> cpv;
       iSetup.get<IdealGeometryRecord>().get(cpv);
 
       edm::ESHandle<MuonDDDConstants> mdc;
       iSetup.get<MuonNumberingRecord>().get(mdc);
       DTGeometryBuilderFromDDD DTGeometryBuilder;
       CSCGeometryBuilderFromDDD CSCGeometryBuilder;
  
       boost::shared_ptr<DTGeometry> dtGeometry(new DTGeometry );
       DTGeometryBuilder.build(dtGeometry, &(*cpv), *mdc);
 
       boost::shared_ptr<CSCGeometry> boost_cscGeometry(new CSCGeometry);
       CSCGeometryBuilder.build(boost_cscGeometry, &(*cpv), *mdc);
 
       AlignableMuon ideal_alignableMuon(&(*dtGeometry), &(*boost_cscGeometry));
 
       align::Alignables ideal_barrels = ideal_alignableMuon.DTBarrel();
       align::Alignables ideal_endcaps = ideal_alignableMuon.CSCEndcaps();
 
       writeComponents(barrels, ideal_barrels, errors, outputFile, true);
       writeComponents(endcaps, ideal_endcaps, errors, outputFile, false);
    }
    else {
       align::Alignables empty1, empty2;
 
       writeComponents(barrels, empty1, errors, outputFile, true);
       writeComponents(endcaps, empty2, errors, outputFile, false);
    }
 
    outputFile << "</MuonAlignment>" << std::endl;
 }

void MuonAlignmentOutputXML::writeComponents	(	align::Alignables &	alignables,
		align::Alignables &	ideals,
		std::map< align::ID, CLHEP::HepSymMatrix > &	errors,
		std::ofstream &	outputFile,
		bool	DT
	)		const

private

Definition at line 157 of file MuonAlignmentOutputXML.cc.

References align::AlignableCSCChamber, align::AlignableCSCEndcap, align::AlignableCSCRing, align::AlignableCSCStation, align::AlignableDetUnit, align::AlignableDTBarrel, align::AlignableDTChamber, align::AlignableDTStation, align::AlignableDTSuperLayer, align::AlignableDTWheel, assert(), PV3DBase< T, PVType, FrameType >::basicVector(), makeMuonMisalignmentScenario::components, gather_cfg::cout, Reference_intrackfit_cff::endcap, CSCDetId::endcap(), Exception, AlignableObjectId::idToString(), m_eulerAngles, m_rawIds, m_relativeto, m_suppressCSCChambers, m_suppressCSCEndcaps, m_suppressCSCLayers, m_suppressCSCRings, m_suppressCSCStations, m_suppressDTBarrel, m_suppressDTChambers, m_suppressDTLayers, m_suppressDTStations, m_suppressDTSuperLayers, m_suppressDTWheels, m_survey, NULL, relativeConstraints::ring, makeMuonMisalignmentScenario::rot, relativeConstraints::station, AlCaHLTBitMon_QueryRunRegistry::string, align::toAngles(), TkRotation< T >::transposed(), DTChamberId::wheel(), PV3DBase< T, PVType, FrameType >::x(), TkRotation< T >::xx(), TkRotation< T >::xy(), TkRotation< T >::xz(), PV3DBase< T, PVType, FrameType >::y(), TkRotation< T >::yz(), PV3DBase< T, PVType, FrameType >::z(), and TkRotation< T >::zz().

Referenced by write().

                                                                                                              {
    align::Alignables::const_iterator ideal = ideals.begin();
    for (align::Alignables::const_iterator alignable = alignables.begin();  alignable != alignables.end();  ++alignable) {
       if (m_survey  &&  (*alignable)->survey() == NULL) {
      throw cms::Exception("Alignment") << "SurveyDets must all be defined when writing to XML" << std::endl;
       } // now I can assume it's okay everywhere
 
       align::StructureType alignableObjectId = (*alignable)->alignableObjectId();
 
       if ((alignableObjectId == align::AlignableDTBarrel  &&  !m_suppressDTBarrel)  ||
       (alignableObjectId == align::AlignableDTWheel  &&  !m_suppressDTWheels)  ||
       (alignableObjectId == align::AlignableDTStation  &&  !m_suppressDTStations)  ||
       (alignableObjectId == align::AlignableDTChamber  &&  !m_suppressDTChambers)  ||
       (DT  &&  alignableObjectId == align::AlignableDTSuperLayer  &&  !m_suppressDTSuperLayers)  ||
       (DT  &&  alignableObjectId == align::AlignableDetUnit  &&  !m_suppressDTLayers)  ||
       (alignableObjectId == align::AlignableCSCEndcap  &&  !m_suppressCSCEndcaps)  ||
       (alignableObjectId == align::AlignableCSCStation  &&  !m_suppressCSCStations)  ||
       (alignableObjectId == align::AlignableCSCRing  &&  !m_suppressCSCRings)  ||
       (alignableObjectId == align::AlignableCSCChamber  &&  !m_suppressCSCChambers)  ||
       (!DT  &&  alignableObjectId == align::AlignableDetUnit  &&  !m_suppressCSCLayers)) {
 
      unsigned int rawId = (*alignable)->geomDetId().rawId();
      outputFile << "<operation>" << std::endl;
 
      if (DT) {
         if (m_rawIds  &&  rawId != 0) {
            std::string typeName = AlignableObjectId::idToString(alignableObjectId);
            if (alignableObjectId == align::AlignableDTSuperLayer) typeName = std::string("DTSuperLayer");
            if (alignableObjectId == align::AlignableDetUnit) typeName = std::string("DTLayer");
            outputFile << "  <" << typeName << " rawId=\"" << rawId << "\" />" << std::endl;
         }
         else {
            if (alignableObjectId == align::AlignableDetUnit) {
           DTLayerId id(rawId);
           outputFile << "  <DTLayer wheel=\"" << id.wheel() << "\" station=\"" << id.station() << "\" sector=\"" << id.sector() << "\" superlayer=\"" << id.superlayer() << "\" layer=\"" << id.layer() << "\" />" << std::endl;
            }
            else if (alignableObjectId == align::AlignableDTSuperLayer) {
           DTSuperLayerId id(rawId);
           outputFile << "  <DTSuperLayer wheel=\"" << id.wheel() << "\" station=\"" << id.station() << "\" sector=\"" << id.sector() << "\" superlayer=\"" << id.superlayer() << "\" />" << std::endl;
            }
            else if (alignableObjectId == align::AlignableDTChamber) {
           DTChamberId id(rawId);
           outputFile << "  <DTChamber wheel=\"" << id.wheel() << "\" station=\"" << id.station() << "\" sector=\"" << id.sector() << "\" />" << std::endl;
            }
 
            else {
           DTChamberId id((*alignable)->id());
           if (alignableObjectId == align::AlignableDTStation) {
              outputFile << "  <DTStation wheel=\"" << id.wheel() << "\" station=\"" << id.station() << "\" />" << std::endl;
           }
           else if (alignableObjectId == align::AlignableDTWheel) {
              outputFile << "  <DTWheel wheel=\"" << id.wheel() << "\" />" << std::endl;
           }
           else if (alignableObjectId == align::AlignableDTBarrel) {
              outputFile << "  <DTBarrel />" << std::endl;
           }
           else throw cms::Exception("Alignment") << "Unknown DT Alignable StructureType" << std::endl;
            }
 
         } // end if not rawId
      } // end if DT
 
      else { // CSC
         if (m_rawIds  &&  rawId != 0) {
            std::string typeName = AlignableObjectId::idToString(alignableObjectId);
            if (alignableObjectId == align::AlignableDetUnit) typeName = std::string("CSCLayer");
            outputFile << "  <" << typeName << " rawId=\"" << rawId << "\" />" << std::endl;
         }
         else {
            if (alignableObjectId == align::AlignableDetUnit) {
           CSCDetId id(rawId);
           outputFile << "  <CSCLayer endcap=\"" << id.endcap() << "\" station=\"" << id.station() << "\" ring=\"" << id.ring() << "\" chamber=\"" << id.chamber() << "\" layer=\"" << id.layer() << "\" />" << std::endl;
            }
            else if (alignableObjectId == align::AlignableCSCChamber) {
           CSCDetId id(rawId);
           outputFile << "  <CSCChamber endcap=\"" << id.endcap() << "\" station=\"" << id.station() << "\" ring=\"" << id.ring() << "\" chamber=\"" << id.chamber() << "\" />" << std::endl;
            }
            else {
           CSCDetId id((*alignable)->id());
           if (alignableObjectId == align::AlignableCSCRing) {
              outputFile << "  <CSCRing endcap=\"" << id.endcap() << "\" station=\"" << id.station() << "\" ring=\"" << id.ring() << "\" />" << std::endl;
           }
           else if (alignableObjectId == align::AlignableCSCStation) {
              outputFile << "  <CSCStation endcap=\"" << id.endcap() << "\" station=\"" << id.station() << "\" />" << std::endl;
           }
           else if (alignableObjectId == align::AlignableCSCEndcap) {
              outputFile << "  <CSCEndcap endcap=\"" << id.endcap() << "\" />" << std::endl;
           }
           else throw cms::Exception("Alignment") << "Unknown CSC Alignable StructureType" << std::endl;
            
            }
 
         } // end if not rawId
      } // end if CSC
 
      align::PositionType pos = (*alignable)->globalPosition();
      align::RotationType rot = (*alignable)->globalRotation();
 
      if (m_survey) {
         pos = (*alignable)->survey()->position();
         rot = (*alignable)->survey()->rotation();
      }
 
      std::string str_relativeto;
      if (m_relativeto == 0) {
         str_relativeto = std::string("none");
      }
 
      else if (m_relativeto == 1) {
         if (ideal == ideals.end()  ||  (*ideal)->alignableObjectId() != alignableObjectId  ||  (*ideal)->id() != (*alignable)->id()) {
            throw cms::Exception("Alignment") << "AlignableMuon and ideal_AlignableMuon are out of sync!" << std::endl;
         }
 
         align::PositionType idealPosition = (*ideal)->globalPosition();
         align::RotationType idealRotation = (*ideal)->globalRotation();
 
         pos = align::PositionType(idealRotation * (pos.basicVector() - idealPosition.basicVector()));
         rot = rot * idealRotation.transposed();
 
         str_relativeto = std::string("ideal");
 
             bool csc_debug=0;
             if (csc_debug && !DT) {
               CSCDetId id(rawId);
               if(id.endcap()==1 && id.station()==1 && id.ring()==1 && id.chamber()==33 ){
                 std::cout<<" investigating "<<id<<std::endl<<(*alignable)->globalRotation()<<std::endl<<std::endl
                          <<idealRotation.transposed()<<std::endl<<std::endl<<rot<<std::endl<<std::endl;
                 double phix = atan2(rot.yz(), rot.zz());
                 double phiy = asin(-rot.xz());
                 double phiz = atan2(rot.xy(), rot.xx());
 
                 std::cout << "phix=\"" << phix << "\" phiy=\"" << phiy << "\" phiz=\"" << phiz << std::endl;
 
                 align::EulerAngles eulerAngles = align::toAngles((*alignable)->globalRotation());
                 std::cout << "alpha=\"" << eulerAngles(1) << "\" beta=\"" << eulerAngles(2) << "\" gamma=\"" << eulerAngles(3) << std::endl;
                 eulerAngles = align::toAngles(idealRotation);
                 std::cout << "alpha=\"" << eulerAngles(1) << "\" beta=\"" << eulerAngles(2) << "\" gamma=\"" << eulerAngles(3) << std::endl;
                 eulerAngles = align::toAngles(rot);
                 std::cout << "alpha=\"" << eulerAngles(1) << "\" beta=\"" << eulerAngles(2) << "\" gamma=\"" << eulerAngles(3) << std::endl;
               }
             }
      }
 
      else if (m_relativeto == 2  &&  (*alignable)->mother() != NULL) {
         align::PositionType globalPosition = (*alignable)->mother()->globalPosition();
         align::RotationType globalRotation = (*alignable)->mother()->globalRotation();
 
         pos = align::PositionType(globalRotation * (pos.basicVector() - globalPosition.basicVector()));
         rot = rot * globalRotation.transposed();
 
         str_relativeto = std::string("container");
      }
 
      else assert(false);  // can't happen: see constructor
 
      outputFile << "  <setposition relativeto=\"" << str_relativeto << "\" "
             << "x=\"" << pos.x() << "\" y=\"" << pos.y() << "\" z=\"" << pos.z() << "\" ";
 
      if (m_eulerAngles) {
         align::EulerAngles eulerAngles = align::toAngles(rot);
         outputFile << "alpha=\"" << eulerAngles(1) << "\" beta=\"" << eulerAngles(2) << "\" gamma=\"" << eulerAngles(3) << "\" />" << std::endl;
      }
      
      else {
         // the angle convention originally used in alignment, also known as "non-standard Euler angles with a Z-Y-X convention"
         // this also gets the sign convention right
         double phix = atan2(rot.yz(), rot.zz());
         double phiy = asin(-rot.xz());
         double phiz = atan2(rot.xy(), rot.xx());
         
         outputFile << "phix=\"" << phix << "\" phiy=\"" << phiy << "\" phiz=\"" << phiz << "\" />" << std::endl;
      }
 
      if (m_survey) {
         align::ErrorMatrix err = (*alignable)->survey()->errors();
 
         outputFile << "  <setsurveyerr"
                <<   " xx=\"" << err(0,0) << "\" xy=\"" << err(0,1) << "\" xz=\"" << err(0,2) << "\" xa=\"" << err(0,3) << "\" xb=\"" << err(0,4) << "\" xc=\"" << err(0,5)
                << "\" yy=\"" << err(1,1) << "\" yz=\"" << err(1,2) << "\" ya=\"" << err(1,3) << "\" yb=\"" << err(1,4) << "\" yc=\"" << err(1,5)
                << "\" zz=\"" << err(2,2) << "\" za=\"" << err(2,3) << "\" zb=\"" << err(2,4) << "\" zc=\"" << err(2,5)
                << "\" aa=\"" << err(3,3) << "\" ab=\"" << err(3,4) << "\" ac=\"" << err(3,5)
                << "\" bb=\"" << err(4,4) << "\" bc=\"" << err(4,5)
                << "\" cc=\"" << err(5,5) << "\" />" << std::endl;
      }
 
      else if (rawId != 0) {
 
         CLHEP::HepSymMatrix err = errors[(*alignable)->id()];
 
             outputFile <<"  <setape xx=\"" << err(0,0) << "\" xy=\"" << err(0,1) << "\" xz=\"" << err(0,2) << "\" xa=\"" << err(0,3) << "\" xb=\"" << err(0,4) << "\" xc=\"" << err(0,5)
                        << "\" yy=\"" << err(1,1) << "\" yz=\"" << err(1,2) << "\" ya=\"" << err(1,3) << "\" yb=\"" << err(1,4) << "\" yc=\"" << err(1,5)
                        << "\" zz=\"" << err(2,2) << "\" za=\"" << err(2,3) << "\" zb=\"" << err(2,4) << "\" zc=\"" << err(2,5)
                        << "\" aa=\"" << err(3,3) << "\" ab=\"" << err(3,4) << "\" ac=\"" << err(3,5)
                        << "\" bb=\"" << err(4,4) << "\" bc=\"" << err(4,5)
                        << "\" cc=\"" << err(5,5) << "\" />" << std::endl;
      }
 
      outputFile << "</operation>" << std::endl << std::endl;
 
       } // end if not suppressed
 
       // write superstructures before substructures: this is important because <setape> overwrites all substructures' APEs
       if (ideal != ideals.end()) {
      align::Alignables components = (*alignable)->components();
      align::Alignables ideal_components = (*ideal)->components();
      writeComponents(components, ideal_components, errors, outputFile, DT);
      ++ideal; // important for synchronization in the "for" loop!
       }
       else {
      align::Alignables components = (*alignable)->components();
      align::Alignables dummy;
      writeComponents(components, dummy, errors, outputFile, DT);
       }
 
    } // end loop over alignables
 }