#include <EmcMcHitCnv.h>
Inheritance diagram for EmcMcHitCnv:
Public Types | |
typedef Ty2 | destination |
typedef Ty2 | destination |
typedef Ty1 | source |
typedef Ty1 | source |
Public Member Functions | |
virtual StatusCode | createObj (IOpaqueAddress *addr, DataObject *&dat) |
Convert the persistent object to transient. | |
virtual StatusCode | createObj (IOpaqueAddress *addr, DataObject *&dat) |
Convert the persistent object to transient. | |
virtual StatusCode | createRep (DataObject *pObject, IOpaqueAddress *&refpAddress) |
Convert the transient object to the requested representation. | |
virtual StatusCode | createRep (DataObject *pObject, IOpaqueAddress *&refpAddress) |
Convert the transient object to the requested representation. | |
void | declareObject (const std::string &fullPath, const CLID &clid, const std::string &treename, const std::string &branchname) |
Store TDS path to link a particular converter to an object on the TDS. | |
void | declareObject (const std::string &fullPath, const CLID &clid, const std::string &treename, const std::string &branchname) |
Store TDS path to link a particular converter to an object on the TDS. | |
virtual StatusCode | fillObjRefs (IOpaqueAddress *pAddress, DataObject *pObject) |
Resolve the references of the converted object. | |
virtual StatusCode | fillObjRefs (IOpaqueAddress *pAddress, DataObject *pObject) |
Resolve the references of the converted object. | |
virtual StatusCode | fillRepRefs (IOpaqueAddress *pAddress, DataObject *pObject) |
Resolve the references of the converted object. | |
virtual StatusCode | fillRepRefs (IOpaqueAddress *pAddress, DataObject *pObject) |
Resolve the references of the converted object. | |
virtual StatusCode | finalize () |
virtual StatusCode | finalize () |
TObject * | getReadObject () const |
get the object to be read | |
TObject * | getReadObject () const |
get the object to be read | |
virtual StatusCode | initialize () |
virtual StatusCode | initialize () |
destination * | operator (const source &) const |
destination * | operator (const source &) const |
virtual long | repSvcType () const |
virtual long | repSvcType () const |
virtual | ~EmcMcHitCnv () |
virtual | ~EmcMcHitCnv () |
Static Public Member Functions | |
const CLID & | classID () |
const CLID & | classID () |
const unsigned char | storageType () |
Storage type and class ID. | |
const unsigned char | storageType () |
Storage type and class ID. | |
Protected Member Functions | |
virtual destination * | convert (const source &) const =0 |
virtual destination * | convert (const source &) const =0 |
virtual StatusCode | DataObjectToTObject (DataObject *obj, RootAddress *addr) |
transformation to root | |
virtual StatusCode | DataObjectToTObject (DataObject *obj, RootAddress *addr) |
transformation to root | |
EmcMcHitCnv (ISvcLocator *svc) | |
EmcMcHitCnv (ISvcLocator *svc) | |
virtual StatusCode | TObjectToDataObject (DataObject *&obj) |
transformation from root | |
virtual StatusCode | TObjectToDataObject (DataObject *&obj) |
transformation from root | |
Protected Attributes | |
CLID | CLID_top |
the CLID of the upper converter if any | |
std::vector< void * > | m_adresses |
each converter knows the corresponding adresses | |
std::vector< void * > | m_adresses |
each converter knows the corresponding adresses | |
int | m_branchNr |
the branchNr of this converter for writing | |
int | m_branchNrDst |
int | m_branchNrEvtHeader |
int | m_branchNrEvtRec |
int | m_branchNrMc |
int | m_branchNrRecon |
TArrayS * | m_branchNumbers |
array with number of branches for reading | |
TArrayS * | m_branchNumbers |
array with number of branches for reading | |
RootCnvSvc * | m_cnvSvc |
RootCnvSvc * | m_cnvSvc |
std::string | m_currentFileName |
IDataProviderSvc * | m_eds |
pointer to eventdataservice | |
IDataProviderSvc * | m_eds |
pointer to eventdataservice | |
RootEvtSelector * | m_evtsel |
RootEvtSelector * | m_evtsel |
std::vector< RootCnvSvc::Leaf > | m_leaves |
std::vector< RootCnvSvc::Leaf > | m_leaves |
TObject * | m_objRead |
the object that was read | |
TObject * | m_objRead |
the object that was read | |
std::string | m_rootBranchname |
root branchname (may be concatenated of severals) | |
RootInterface * | m_rootInterface |
pointer to the RootInterface | |
RootInterface * | m_rootInterface |
pointer to the RootInterface | |
std::string | m_rootTreename |
each converter knows it's treename | |
Private Attributes | |
commonData | m_common |
relational maps | |
TObjArray * | m_emcMcHitCol |
root object to be read | |
TObjArray * | m_emcMcHitCol |
root object to be read | |
Friends | |
class | CnvFactory<EmcMcHitCnv> |
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00029 { };
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00029 : RootEventBaseCnv(classID(), svc) 00030 { 00031 // Here we associate this converter with the /Event path on the TDS. 00032 MsgStream log(msgSvc(), "EmcMcHitCnv"); 00033 // log << MSG::DEBUG << "Constructor called for " << objType() << endreq; 00034 m_rootBranchname ="m_emcMcHitCol"; 00035 //declareObject(EventModel::MC::EmcMcHitCol, objType(), m_rootTreename, m_rootBranchname); 00036 m_adresses.push_back(&m_emcMcHitCol); 00037 m_emcMcHitCol=0; 00038 }
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00029 { };
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00025 {
00026 return CLID_EmcMcHitCol;
00027 }
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00025 {
00026 return CLID_EmcMcHitCol;
00027 }
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Convert the persistent object to transient.
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Convert the persistent object to transient.
Reimplemented in EventCnv, and EventCnv. 00157 { 00158 // transform ROOT object to TDS object 00159 MsgStream log(msgSvc(), "RootEventBaseCnv"); 00160 log << MSG::DEBUG << "RootEventBaseCnv::createObj with clid " <<addr->clID()<< endreq; 00161 StatusCode sc; 00162 00163 // add 2005-11-29 00164 // log<<MSG::INFO<<"######### RootEventBaseCnv ::createObj begin of createObj: m_branchNumbers "<<m_branchNumbers->GetSize()<<"###############"<<endreq; 00165 00166 RootAddress *raddr=dynamic_cast<RootAddress *>(addr); 00167 if (!raddr) { 00168 log << MSG::ERROR << "Could not downcast to Root address" << endreq; 00169 return StatusCode::FAILURE; 00170 } 00171 00172 static int temp =0; //control the begin of each files 2005-12-01 00173 static int entryN =0; //control the event number of each files 2005-21-01 00174 static int brN =0; //control munber of branch of the tree; 00175 int lastBrn = brN; 00176 //lastBrn = brN; 00177 static int branchN=0; 00178 static bool isSet=true; 00179 00180 static int entryBefore = 0; 00181 static bool addEntryEachFile = true; 00182 00183 00184 if(m_rootInterface->getENDFILE() || (temp >0 && temp < branchN)){ // if the file has get the end:y the go to next file to create a new tree 00185 00186 if(m_rootInterface->getENDFILE() ) { 00187 entryN = 0; 00188 } 00189 00190 temp++; 00191 00192 delete m_branchNumbers; 00193 m_branchNumbers = new TArrayS(0); 00194 00195 if(temp == branchN) { 00196 temp =0; 00197 } 00198 } 00199 00200 if(m_rootInterface->getENDFILE()) addEntryEachFile = true; 00201 // the 2nd method 00202 if(m_evtsel->getRecId() - entryBefore == 0) { // first event in this file 00203 delete m_branchNumbers; 00204 m_branchNumbers = new TArrayS(0); 00205 } 00206 00207 //new method to initialize the branchNumber 00208 if(m_currentFileName=="") m_currentFileName = m_rootInterface->getCurrentFileName(); 00209 if(!(m_currentFileName == m_rootInterface->getCurrentFileName())){ 00210 m_currentFileName = m_rootInterface->getCurrentFileName(); 00211 delete m_branchNumbers; 00212 m_branchNumbers = new TArrayS(0); 00213 } 00214 //---------------------------------------- 00215 00216 00217 if (m_branchNumbers->GetSize()<=0) { 00218 if(isSet) brN++; 00219 int branchNumber; 00220 for (int nb=0;nb<raddr->getNrBranches();nb++) { 00221 sc=m_rootInterface->setBranchAddress(raddr->getTreename().c_str(),raddr->getBranchname(nb).c_str(),m_adresses[nb],branchNumber); 00222 if (!sc.isSuccess()) 00223 { 00224 if(isSet) brN--; //liangyt: if fail to retrieve this branch, this will be not a effective branch. 00225 //entryN++; //liangyt: this is the second method 00226 if(temp>0) temp--; //temp > 0 means recording effective branch number. 00227 return sc; 00228 } 00229 m_branchNumbers->Set(nb+1); 00230 m_branchNumbers->AddAt(branchNumber,nb); 00231 00232 } 00233 } 00234 00236 if(addEntryEachFile&&(m_evtsel->getRecId()>entryBefore)){ // for a new file, add entry for ONLY one time. 00237 entryBefore += m_rootInterface->getEntries(); 00238 addEntryEachFile = false; 00239 } 00240 00241 if(lastBrn == brN && isSet ){ 00242 branchN = brN; 00243 isSet=false; 00244 } 00245 00246 if(isSet==false) log << MSG::INFO <<" 1st method set event as : "<<int(entryN/branchN)<<endreq; 00247 if(isSet==false) raddr->setEntryNr(int(entryN/branchN));//former method, keep it to be backup. 00248 if(m_evtsel) log << MSG::INFO <<" event id = "<<m_evtsel->getRecId()<<endreq; 00249 00250 int eventID = 0; 00251 if(entryBefore > m_evtsel->getRecId()) 00252 eventID = m_evtsel->getRecId() + m_rootInterface->getEntries() - entryBefore; 00253 else if(entryBefore == m_evtsel->getRecId()) eventID = 0; 00254 else log << MSG::ERROR <<"eventId error!!!"<<endreq; 00255 00256 log << MSG::INFO <<" 2nd method set event as : "<<eventID<<endreq; 00257 if(m_evtsel) raddr->setEntryNr(eventID); 00258 // read branch 00259 00260 if (m_branchNumbers->GetSize()>0) { 00261 int nbtot=0,nb; 00262 for (int ib=0;ib<m_branchNumbers->GetSize();ib++) { 00263 //sc=m_rootInterface->getBranchEntry(m_branchNumbers->At(ib),raddr->getEntryNr(),nb); 00264 //change to get branch entry with addr(set address for each entry) liangyt 00265 sc=m_rootInterface->getBranchEntry(m_branchNumbers->At(ib),raddr->getEntryNr(),m_adresses[ib],nb); 00266 if (sc.isFailure()) { 00267 log << MSG::ERROR << "Could not read branch " << raddr->getBranchname(nb) << endreq; 00268 return sc; 00269 } 00270 nbtot+=nb; 00271 } 00272 } 00273 00274 else { // get ROOT object 00275 if (CLID_top) { 00276 IConverter *p=conversionSvc()->converter(CLID_top); 00277 RootEventBaseCnv *cnv=dynamic_cast<RootEventBaseCnv *>(p); 00278 if (!cnv) { 00279 log << MSG::ERROR << "Could not downcast to RootEventBaseCnv " << endreq; 00280 return StatusCode::FAILURE; 00281 } 00282 m_objRead=cnv->getReadObject(); 00283 } 00284 } 00285 00286 //do concrete transformation in derived converter 00287 sc = TObjectToDataObject(refpObject); 00288 if (sc.isFailure()) { 00289 log << MSG::ERROR << "Could not transform object" << endreq; 00290 return sc; 00291 } 00292 00293 // verify if we have to register 00294 IRegistry* ent = addr->registry(); 00295 if ( ent == 0) { 00296 sc=m_eds->registerObject(raddr->getPath(),refpObject); 00297 if (sc.isFailure()) { 00298 log << MSG::ERROR << "Could not register object " << raddr->getPath()<<" status "<<sc.getCode()<<endreq; 00299 } 00300 // } 00301 } 00302 00303 entryN++; 00304 return StatusCode::SUCCESS; 00305 }
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Convert the transient object to the requested representation.
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Convert the transient object to the requested representation.
00078 { 00079 // Purpose and Method: Convert the transient object to ROOT 00080 00081 MsgStream log(msgSvc(), "RootEventBaseCnv"); 00082 00083 StatusCode sc= StatusCode::SUCCESS; 00084 // get the corresponding address 00085 RootAddress *rootaddr; 00086 sc=m_cnvSvc->createAddress(obj,addr); 00087 00088 rootaddr = dynamic_cast<RootAddress *>(addr); 00089 00090 if (sc.isFailure() || !rootaddr ) { 00091 log << MSG::ERROR << "Could not create address for clid " <<obj->clID()<<", objname "<<obj->name()<<endreq; 00092 return StatusCode::FAILURE; 00093 } 00094 00095 // do the real conversion in the derived converter 00096 sc = DataObjectToTObject(obj,rootaddr); 00097 00098 delete addr; 00099 addr = NULL; 00100 00101 if (sc.isFailure()) { 00102 log << MSG::ERROR << "Could not transform object" << endreq; 00103 return sc; 00104 } 00105 00106 return StatusCode::SUCCESS; 00107 }
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transformation to root
Implements RootEventBaseCnv. |
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transformation to root
Implements RootEventBaseCnv. 00132 { 00133 00134 MsgStream log(msgSvc(), "EmcMcHitCnv"); 00135 log << MSG::DEBUG << "EmcMcHitCnv::DataObjectToTObject" << endreq; 00136 StatusCode sc=StatusCode::SUCCESS; 00137 00138 EmcMcHitCol * emcMcHitCnvTds=dynamic_cast<EmcMcHitCol *> (obj); 00139 if (!emcMcHitCnvTds) { 00140 log << MSG::ERROR << "Could not downcast to EmcMcHitCol" << endreq; 00141 return StatusCode::FAILURE; 00142 } 00143 00144 DataObject *evt; 00145 m_eds->findObject(EventModel::MC::Event,evt); 00146 if (evt==NULL) { 00147 log << MSG::ERROR << "Could not get McEvent in TDS " << endreq; 00148 return StatusCode::FAILURE; 00149 } 00150 McEvent * devtTds=dynamic_cast<McEvent *> (evt); 00151 if (!devtTds) { 00152 log << MSG::ERROR << "EmcMcHitCnv:Could not downcast to TDS McEvent" << endreq; 00153 } 00154 IOpaqueAddress *addr; 00155 00156 m_cnvSvc->getMcCnv()->createRep(evt,addr); 00157 TMcEvent *McEvt=m_cnvSvc->getMcCnv()->getWriteObject(); 00158 00159 const TObjArray *m_emcMcHitCol = McEvt->getEmcMcHitCol(); 00160 if (!m_emcMcHitCol) return sc; 00161 McEvt->clearEmcMcHitCol(); //necessary in case there is I/O at the same time since array is static 00162 EmcMcHitCol::const_iterator emcMcTds; 00163 00164 for (emcMcTds = emcMcHitCnvTds->begin(); emcMcTds != emcMcHitCnvTds->end(); emcMcTds++) { 00165 UInt_t id = ((*emcMcTds)->identify()).get_value() ; 00166 UInt_t trackIndex = (*emcMcTds) ->getTrackIndex(); 00167 00168 int hitEmc = (*emcMcTds) ->getHitEmc(); 00169 int PDGCode = (*emcMcTds) ->getPDGCode(); 00170 double PDGCharge = (*emcMcTds) ->getPDGCharge(); 00171 double time = (*emcMcTds) ->getTime(); 00172 std::map<Identifier, Double_t> TdshitMap = (*emcMcTds)->getHitMap(); 00173 00174 map<Int_t, Double_t> HitMap; 00175 map<Identifier, Double_t>::iterator iHitMap; 00176 for(iHitMap=TdshitMap.begin(); 00177 iHitMap!=TdshitMap.end(); 00178 iHitMap++) { 00179 00180 Int_t id(iHitMap->first.get_value()); 00181 pair<Int_t, Double_t> Hit(id, iHitMap->second); 00182 HitMap.insert(Hit); 00183 00184 //RecEmcHitCol::iterator iHit; 00185 //for(iHit=emcRecHitCol->begin(); 00186 // iHit!=emcRecHitCol->end(); 00187 // iHit++) { 00188 00189 // RecEmcID idHit((*iHit)->getCellId()); 00190 00191 // if(id==idHit) { 00192 // RecEmcFraction frac(*(*iHit)); 00193 // frac.Fraction(iHitMap->second); 00194 // emcShowerTds->Insert(frac); 00195 // break; 00196 // } 00197 //} //RecEmcHitCol 00198 } //CellIdMap 00199 00200 Double_t xPosition = (*emcMcTds) ->getPositionX() ; 00201 Double_t yPosition = (*emcMcTds) ->getPositionY() ; 00202 Double_t zPosition = (*emcMcTds) ->getPositionZ() ; 00203 Double_t px= (*emcMcTds) ->getPx() ; 00204 Double_t py = (*emcMcTds) ->getPy() ; 00205 Double_t pz = (*emcMcTds) ->getPz() ; 00206 Double_t depositEnergy = (*emcMcTds) ->getDepositEnergy() ; 00207 00208 TEmcMc *emcMcRoot = new TEmcMc(); 00209 //m_common.m_emcMcHitMap[(*emcMcTds)] = emcMcRoot; 00210 00211 emcMcRoot->setId(id); 00212 emcMcRoot->setHitMap(HitMap); 00213 00214 emcMcRoot->setHitEmc(hitEmc); 00215 emcMcRoot->setPDGCode(PDGCode); 00216 emcMcRoot->setPDGCharge(PDGCharge); 00217 emcMcRoot->setTime(time); 00218 //emcMcRoot->setHitMap(hitMap); 00219 00220 emcMcRoot->setTrackIndex(trackIndex); 00221 emcMcRoot->setPositionX(xPosition); 00222 emcMcRoot->setPositionY(yPosition); 00223 emcMcRoot->setPositionZ(zPosition); 00224 emcMcRoot->setPx(px); 00225 emcMcRoot->setPy(py); 00226 emcMcRoot->setPz(pz); 00227 emcMcRoot->setDepositEnergy(depositEnergy); 00228 00229 McEvt->addEmcMc(emcMcRoot); 00230 } 00231 00232 return StatusCode::SUCCESS; 00233 }
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Store TDS path to link a particular converter to an object on the TDS.
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Store TDS path to link a particular converter to an object on the TDS.
00150 { 00151 // Purpose and Method: Save the path on the TDS, treename, pathname in the m_leaves vector, 00152 // corresponding to the DataObject that the converter handles. 00153 m_leaves.push_back(RootCnvSvc::Leaf(path, cl,treename,branchname)); 00154 }
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Resolve the references of the converted object.
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Resolve the references of the converted object.
00117 { 00118 // Purpose and Method: Resolve the references of the converted object. 00119 // It is expected that derived classes will override this method. 00120 MsgStream log(msgSvc(), "RootEventBaseCnv"); 00121 return StatusCode::SUCCESS; 00122 }
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Resolve the references of the converted object.
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Resolve the references of the converted object.
00109 { 00110 // Purpose and Method: Resolve the references of the converted object. 00111 // It is expected that derived classes will override this method. 00112 MsgStream log(msgSvc(), "RootEventBaseCnv"); 00113 return StatusCode::SUCCESS; 00114 }
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00141 { 00142 if ( m_cnvSvc ) { 00143 m_cnvSvc->release(); 00144 m_cnvSvc=0; 00145 } 00146 return Converter::finalize(); 00147 }
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get the object to be read
00124 { return m_objRead;}
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get the object to be read
00124 { return m_objRead;}
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Reimplemented in DigiCnv, DstCnv, EvtHeaderCnv, EvtRecCnv, HltCnv, McCnv, RecTrackCnv, TrigCnv, DigiCnv, DstCnv, EvtHeaderCnv, EvtRecCnv, HltCnv, McCnv, RecTrackCnv, and TrigCnv. |
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Reimplemented in DigiCnv, DstCnv, EvtHeaderCnv, EvtRecCnv, HltCnv, McCnv, RecTrackCnv, TrigCnv, DigiCnv, DstCnv, EvtHeaderCnv, EvtRecCnv, HltCnv, McCnv, RecTrackCnv, and TrigCnv. 00125 { 00126 00127 StatusCode status = Converter::initialize(); 00128 00129 if ( status.isSuccess() ) { 00130 IService* isvc = 0; 00131 status = serviceLocator()->service("RootCnvSvc", isvc, false); 00132 if ( !status.isSuccess() ) status = serviceLocator()->service("EventCnvSvc", isvc, true); 00133 if ( status.isSuccess() ) { 00134 status = isvc->queryInterface(IID_IRootCnvSvc, (void**)&m_cnvSvc); 00135 } 00136 } 00137 00138 return status; 00139 }
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00087 {
00088 return ROOT_StorageType;
00089 }
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00087 {
00088 return ROOT_StorageType;
00089 }
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Storage type and class ID.
00083 {
00084 return ROOT_StorageType;
00085 }
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Storage type and class ID.
00083 {
00084 return ROOT_StorageType;
00085 }
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transformation from root
Implements RootEventBaseCnv. |
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transformation from root
Implements RootEventBaseCnv. 00040 { 00041 // creation of TDS object from root object 00042 00043 MsgStream log(msgSvc(), "EmcMcHitCnv"); 00044 log << MSG::DEBUG << "EmcMcHitCnv::TObjectToDataObject" << endreq; 00045 StatusCode sc=StatusCode::SUCCESS; 00046 00047 // create the TDS location for the MdcMc Collection 00048 EmcMcHitCol* emcMcTdsCol = new EmcMcHitCol; 00049 refpObject=emcMcTdsCol; 00050 00051 00052 // now convert 00053 if (!m_emcMcHitCol) return sc; 00054 TIter emcMcIter(m_emcMcHitCol); 00055 TEmcMc *emcMcRoot = 0; 00056 while ((emcMcRoot = (TEmcMc*)emcMcIter.Next())) { 00057 // unsigned int id = emcMcRoot ->getId(); 00058 Identifier id ; 00059 unsigned int id_root = emcMcRoot ->getId(); 00060 id = id_root; 00061 unsigned int trackIndex = emcMcRoot ->getTrackIndex(); 00062 00063 int hitEmc = emcMcRoot ->getHitEmc(); 00064 int PDGCode = emcMcRoot ->getPDGCode(); 00065 double PDGCharge = emcMcRoot ->getPDGCharge(); 00066 double time = emcMcRoot ->getTime(); 00067 00068 double xPosition = emcMcRoot ->getPositionX() ; 00069 double yPosition = emcMcRoot ->getPositionY() ; 00070 double zPosition = emcMcRoot ->getPositionZ() ; 00071 double px= emcMcRoot ->getPx() ; 00072 double py = emcMcRoot ->getPy() ; 00073 double pz = emcMcRoot ->getPz() ; 00074 double depositEnergy = emcMcRoot ->getDepositEnergy() ; 00075 00076 EmcMcHit *emcMcTds = new EmcMcHit(); 00077 m_common.m_rootEmcMcHitMap[emcMcRoot] = emcMcTds; 00078 00079 emcMcTds->setIdentifier(id); 00080 00081 map<Int_t, Double_t> hitMap = emcMcRoot ->getHitMap(); 00082 map<Identifier, Double_t> TdshitMap; 00083 map<Int_t, Double_t> HitMap = emcMcRoot->getHitMap(); 00084 map<Int_t, Double_t>::iterator iHitMap; 00085 for(iHitMap=HitMap.begin(); 00086 iHitMap!=HitMap.end(); 00087 iHitMap++) { 00088 00089 Identifier id(iHitMap->first); 00090 pair<Identifier, Double_t> TdsHit(id, iHitMap->second); 00091 TdshitMap.insert(TdsHit); 00092 00093 //RecEmcHitCol::iterator iHit; 00094 //for(iHit=emcRecHitCol->begin(); 00095 // iHit!=emcRecHitCol->end(); 00096 // iHit++) { 00097 00098 // RecEmcID idHit((*iHit)->getCellId()); 00099 00100 // if(id==idHit) { 00101 // RecEmcFraction frac(*(*iHit)); 00102 // frac.Fraction(iHitMap->second); 00103 // emcShowerTds->Insert(frac); 00104 // break; 00105 // } 00106 //} //RecEmcHitCol 00107 } //CellIdMap 00108 emcMcTds->setHitMap(TdshitMap); 00109 00110 emcMcTds->setHitEmc(hitEmc); 00111 emcMcTds->setPDGCode(PDGCode); 00112 emcMcTds->setPDGCharge(PDGCharge); 00113 emcMcTds->setTime(time); 00114 00115 emcMcTds->setTrackIndex(trackIndex); 00116 emcMcTds->setPositionX(xPosition); 00117 emcMcTds->setPositionY(yPosition); 00118 emcMcTds->setPositionZ(zPosition); 00119 emcMcTds->setPx(px); 00120 emcMcTds->setPy(py); 00121 emcMcTds->setPz(pz); 00122 emcMcTds->setDepositEnergy(depositEnergy); 00123 00124 emcMcTdsCol->push_back(emcMcTds); 00125 } 00126 //m_emcMcHitCol->Delete(); // wensp add 2005/12/30 00127 delete m_emcMcHitCol; 00128 m_emcMcHitCol = 0; 00129 return StatusCode::SUCCESS; 00130 }
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the CLID of the upper converter if any
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each converter knows the corresponding adresses
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each converter knows the corresponding adresses
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the branchNr of this converter for writing
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array with number of branches for reading
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array with number of branches for reading
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relational maps
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pointer to eventdataservice
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pointer to eventdataservice
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root object to be read
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root object to be read
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the object that was read
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the object that was read
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root branchname (may be concatenated of severals)
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pointer to the RootInterface
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pointer to the RootInterface
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each converter knows it's treename
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