LArOFCSubsetCnv_p1 Class Reference

#include <LArOFCSubsetCnv_p1.h>

Inheritance diagram for LArOFCSubsetCnv_p1:

Collaboration diagram for LArOFCSubsetCnv_p1:

Public Types
using	base_class = TPConverterConstBase
typedef TRANS	Trans_t
typedef PERS	Pers_t
typedef PERS	PersBase_t
typedef TRANS	TransBase_t
typedef ITPConverterFor< TRANS >	PolyCnvBase_t
typedef Gaudi::PluginService::Factory< ITPCnvBase *()>	Factory

Public Member Functions
	LArOFCSubsetCnv_p1 ()
virtual void	persToTrans (const LArOFCPersType *persObj, LArOFCTransType *transObj, MsgStream &log) const override
virtual void	transToPers (const LArOFCTransType *transObj, LArOFCPersType *persObj, MsgStream &log) const override
virtual void	transToPers (const TRANS *transObj, PERS *persObj, MsgStream &log) const=0
	Convert transient representation to persistent one.
virtual void	transToPers (const TRANS *transObj, PERS *persObj, MsgStream &log) override final
	Convert transient representation to persistent one.
virtual void	persToTrans (const PERS *persObj, TRANS *transObj, MsgStream &log) const=0
	Convert persistent representation to transient one.
virtual void	persToTrans (const PERS *persObj, TRANS *transObj, MsgStream &log) override final
	Convert persistent representation to transient one.
virtual TRANS *	createTransientConst (const PERS *persObj, MsgStream &log) const
virtual PERS *	createPersistentConst (const TRANS *transObj, MsgStream &log) const
virtual TPObjRef	virt_toPersistent (const TRANS *trans, MsgStream &log)
	Internal interface method that is used to invoke the real conversion method (toPersistent_impl) in the derived converter.
virtual TPObjRef	virt_toPersistentWithKey (const TRANS *trans, const std::string &key, MsgStream &log)
	Internal interface method that is used to invoke the real conversion method (toPersistent_impl) in the derived converter.
virtual void	pstoreToTrans (unsigned index, TRANS *trans, MsgStream &log)
	Convert persistent representation stored in the storage vector of the top-level object to transient.
virtual TRANS *	createTransient (const PERS *persObj, MsgStream &log)
	Create transient representation of a persistent object.
virtual TRANS *	createTransientWithKey (const PERS *persObj, const std::string &key, MsgStream &log)
	Create transient representation of a persistent object, with SG key.
virtual TRANS *	virt_createTransFromPStore (unsigned index, MsgStream &log)
	Internal interface method that is used to invoke the real conversion method (createTransient)
virtual TRANS *	virt_createTransFromPStoreWithKey (unsigned index, const std::string &key, MsgStream &log)
	Internal interface method that is used to invoke the real conversion method (createTransient)
virtual void	persToTransWithKey (const PERS *persObj, TRANS *transObj, const std::string &, MsgStream &log)
	Convert persistent representation to transient one.
virtual void	transToPersWithKey (const TRANS *transObj, PERS *persObj, const std::string &, MsgStream &log)
	Convert transient representation to persistent one.
virtual void	persToTransUntyped (const void *pers, void *trans, MsgStream &log)
	Convert persistent object representation to transient.
virtual void	transToPersUntyped (const void *trans, void *pers, MsgStream &log)
	Convert transient object representation to persistent.
virtual void	persToTransWithKeyUntyped (const void *pers, void *trans, const std::string &key, MsgStream &log)
	Convert persistent object representation to transient.
virtual void	transToPersWithKeyUntyped (const void *trans, void *pers, const std::string &key, MsgStream &log)
	Convert transient object representation to persistent.
virtual PERS *	createPersistent (const TRANS *transObj, MsgStream &log)
	Create persistent representation of a transient object.
virtual PERS *	createPersistentWithKey (const TRANS *transObj, const std::string &key, MsgStream &log)
	Create persistent representation of a transient object, with SG key.
TPObjRef	toPersistentWithKey_impl (const TRANS *trans, const std::string &key, MsgStream &log)
	Convert transient object to persistent representation.
virtual const std::type_info &	transientTInfo () const
	return C++ type id of the transient class this converter is for
virtual const std::type_info &	persistentTInfo () const
	return C++ type id of the persistent class this converter is for
void	setPStorage (std::vector< PERS > *storage)
	Tell this converter which storage vector it should use to store or retrieve persistent representations.
void	setRecursive (bool flag=true)
	Tell the converter if it should work in recursive mode slower but it can safely handle recursion.
void	ignoreRecursion (bool flag=false)
	Tell the converter to ignore recursion (do not throw errors) even when recurion is detected.
virtual void	reservePStorage (size_t size)
	Reserve 'size' elements for persistent storage.
template<class CNV>
CNV *	converterForType (CNV *cnv, const std::type_info &t_info, MsgStream &log) const
	Find converter for a given C++ type ID, that is or ihnerits from CNV type.
template<class CNV>
CNV *	converterForRef (CNV *cnv, const TPObjRef &ref, MsgStream &log) const
	Find converter for a TP type ID (passed in a TP Ref), that is or ihnerits from CNV type.
template<class CNV>
TPObjRef	baseToPersistent (CNV **cnv, const typename CNV::Trans_t *transObj, MsgStream &log) const
	Persistify bass class of a given object and store the persistent represenation in the storage vector of the top-level persistent object.
template<class CNV>
TPObjRef	toPersistent (CNV **cnv, const typename CNV::TransBase_t *transObj, MsgStream &log) const
	Persistify an object and store the persistent represenation in the storage vector of the top-level persistent object.
template<class CNV, class TRANS_T>
void	fillTransFromPStore (CNV **cnv, const TPObjRef &ref, TRANS_T *trans, MsgStream &log) const
	Convert persistent object, stored in the the top-level persistent object and referenced by the TP Ref, to transient representation.
template<class CNV>
CNV::Trans_t *	createTransFromPStore (CNV **cnv, const TPObjRef &ref, MsgStream &log) const
	Create transient representation of a persistent object, stored in the the top-level persistent object and referenced by the TP Ref.
virtual void	initPrivateConverters (TopLevelTPCnvBase *)
virtual TopLevelTPCnvBase *	topConverter ()
	return the top-level converter for this elemental TP converter
virtual const TopLevelTPCnvBase *	topConverter () const
	return the top-level converter for this elemental TP converter
const std::type_info &	transBaseTInfo () const
	return C++ type id of the common base transient type for all converters for a group of polymorphic types
virtual const TPObjRef::typeID_t &	typeID () const
	Return TP typeID for persistent objects produced by this converter.
unsigned	typeIDvalue () const
	inlined non-virtual version to get the typeID value fast
virtual void	setRuntimeTopConverter (TopLevelTPCnvBase *topConverter)
	Set runtime top-level converter - usually it is the owning TL converter, but in case of extended objects it will be the TL converter of the extended object.
virtual void	setTopConverter (TopLevelTPCnvBase *topConverter, const TPObjRef::typeID_t &TPtypeID)
	Set which top-level converter owns this elemental converter, and what TPtypeID was assigned to the persistent objects it produces.
void	setReadingFlag ()
void	clearReadingFlag ()
bool	wasUsedForReading ()
virtual void	converterNotFound (const std::type_info &converterType, ITPConverter *c, const std::string &typeName, MsgStream &log) const
	method called when the right TP converter was not found during writing
virtual void	converterNotFound (unsigned typeID, ITPConverter *c, const std::string &typeName, MsgStream &log) const
	method called when the right TP converter was not found during reading

Protected Attributes
std::vector< PERS > *	m_pStorage
	the address of the storage vector for persistent representations
int	m_curRecLevel
	count recursive invocations, to detect recursion
bool	m_recursive
	if true, work in recursion-safe way (slower)
bool	m_ignoreRecursion
	if true, do not throw errors in case of recursion.
TPObjRef::typeID_t	m_pStorageTID
	TP Ref typeID for the persistent objects this converter is creating.
unsigned	m_pStorageTIDvalue
	m_pStorageTID converted to integer value
TopLevelTPCnvBase *	m_topConverter
	top level converter that owns this elemental TP converter it also holds the storage object
TopLevelTPCnvBase *	m_topConverterRuntime
	top level converter "owning" this TP converter at runtime (different from m_topConverter in case the top-level converter and object have extensions)
bool	m_wasUsedForReading
	flag set when using this converter for reading triggers search for a new converter before writing, to prevent possible use of old version

Detailed Description

Definition at line 18 of file LArOFCSubsetCnv_p1.h.

Member Typedef Documentation

base_class

template<class TRANS, class PERS>

using TPConverterConstBase< TRANS, PERS >::base_class = TPConverterConstBase

inherited

Definition at line 779 of file TPConverter.h.

Factory

typedef Gaudi::PluginService::Factory<ITPCnvBase*()> ITPCnvBase::Factory

inherited

Definition at line 26 of file ITPCnvBase.h.

Pers_t

typedef PERS TPAbstractPolyCnvBase< TRANS, TRANS, PERS >::Pers_t

inherited

Definition at line 335 of file TPConverter.h.

PersBase_t

typedef PERS TPAbstractPolyCnvBase< TRANS, TRANS, PERS >::PersBase_t

inherited

Definition at line 336 of file TPConverter.h.

PolyCnvBase_t

template<class TRANS>

typedef ITPConverterFor< TRANS > ITPConverterFor< TRANS >::PolyCnvBase_t

inherited

Definition at line 41 of file TPConverter.h.

Trans_t

typedef TRANS TPAbstractPolyCnvBase< TRANS, TRANS, PERS >::Trans_t

inherited

Definition at line 334 of file TPConverter.h.

TransBase_t

template<class TRANS>

typedef TRANS ITPConverterFor< TRANS >::TransBase_t

inherited

Definition at line 39 of file TPConverter.h.

Constructor & Destructor Documentation

LArOFCSubsetCnv_p1()

LArOFCSubsetCnv_p1::LArOFCSubsetCnv_p1 ( )

inline

Definition at line 25 of file LArOFCSubsetCnv_p1.h.

{}

Member Function Documentation

baseToPersistent()

template<class TRANS>

template<class CNV>

TPObjRef ITPConverterFor< TRANS >::baseToPersistent ( CNV ** cnv, const typename CNV::Trans_t * transObj, MsgStream & log ) const

inlineinherited

Persistify bass class of a given object and store the persistent represenation in the storage vector of the top-level persistent object.

The converter is located using the transient type from the CNV parameter, not from the object itself (because we need the base type, not the actual type)

Parameters

cnv	[IN/OUT] type of this parameter decides which converter will be used. Once the converter is found, this pointer will be set so the search is done only once
transObj	[IN] transient object
log	[IN] output message stream

Returns

TPObjRef TP reference to the persistent representation stored in the storage vector of the top-level persistent object

Definition at line 97 of file TPConverter.h.

                                                                                           {
     if( !*cnv || (*cnv)->wasUsedForReading() ) {
        // don't trust the converter if it was used for reading, find again
    *cnv = converterForType( *cnv, typeid(typename CNV::Trans_t), log );
    if( !*cnv )  return TPObjRef();
        (*cnv)->clearReadingFlag();
     }
//     return (**cnv).toPersistent_impl(transObj, log); 
     return (**cnv).virt_toPersistent(transObj, log); 
  }

clearReadingFlag()

template<class TRANS>

void ITPConverterFor< TRANS >::clearReadingFlag ( )

inlineinherited

Definition at line 235 of file TPConverter.h.

{ m_wasUsedForReading = false; }

converterForRef()

template<class TRANS>

template<class CNV>

CNV * ITPConverterFor< TRANS >::converterForRef ( CNV * cnv, const TPObjRef & ref, MsgStream & log ) const

inlineinherited

Find converter for a TP type ID (passed in a TP Ref), that is or ihnerits from CNV type.

Parameters

cnv	[IN] parameter specifying the converter type
ref	[IN] TP Ref to an object for which a converter is sought
log	[IN] output message stream

Returns

CNV* pointer to the converter, if found

Definition at line 74 of file TPConverter.h.

                                                                         {
     ITPConverter *c = m_topConverterRuntime->converterForRef( ref );
     cnv = dynamic_cast<CNV*>(c);
     if( !cnv )
        this->converterNotFound( ref.typeID(), c, typeid(CNV).name(), log );
     return cnv;
  }

converterForType()

template<class TRANS>

template<class CNV>

CNV * ITPConverterFor< TRANS >::converterForType ( CNV * cnv, const std::type_info & t_info, MsgStream & log ) const

inlineinherited

Find converter for a given C++ type ID, that is or ihnerits from CNV type.

Parameters

cnv	[IN] parameter specifying the converter type
t_info	[IN] C++ type id for which a converter is sought
log	[IN] output message stream

Returns

CNV* pointer to the converter, if found

Definition at line 58 of file TPConverter.h.

                                                                                 {
     ITPConverter *c = m_topConverterRuntime->converterForType( t_info );
     cnv = dynamic_cast< CNV* >( c );
     if( !cnv )
    this->converterNotFound( typeid(CNV), c, t_info.name(), log );
     return cnv;
  }

converterNotFound() [1/2]

void ITPConverter::converterNotFound ( const std::type_info & converterType, ITPConverter * c, const std::string & typeName, MsgStream & log ) const

virtualinherited

method called when the right TP converter was not found during writing

• useful as a debugging hook, prints a detailed error message

Parameters

converterType	[IN] converterType that was requested
c	[IN] converter that was actually found (0 if not)
typeName	[IN] the C++ type name of the type for which converter was searched for
log	[IN] output message stream

Definition at line 22 of file ITPConverter.cxx.

{
   log << MSG::ERROR << ">>>>>> in parent TP converter " << typeid(*this).name()
       << ": could not find matching TP converter for type " << typeName << endmsg;
   if( c ) {
      log << MSG::ERROR << " - found incompatible converter of type "
      << typeid(*c).name() << endmsg;
   }
   log << MSG::ERROR << "  Converter handle type was " << converterType.name() << endmsg;
   errorHandler();
}

converterNotFound() [2/2]

void ITPConverter::converterNotFound ( unsigned typeID, ITPConverter * c, const std::string & typeName, MsgStream & log ) const

virtualinherited

method called when the right TP converter was not found during reading

• useful as a debugging hook, prints a detailed error message

Parameters

typeID	[IN] converter ID that was requested
c	[IN] converter that was actually found (0 if not)
typeName	[IN] the C++ type name of the type for which converter was searched for
log	[IN] output message stream

Definition at line 40 of file ITPConverter.cxx.

{
   log << MSG::ERROR << ">>>>>> in parent TP converter " <<  typeid(*this).name()
       << "   requested TP converter for TP type ID " << typeID << " not found " << endmsg;
   if( c ) {
      log << MSG::ERROR << " - found converter " <<  typeid(*c).name()
          << " for " << c->transientTInfo().name()
          << " with an incompatible base type " << c->transBaseTInfo().name()
          << endmsg;
   }
   log << MSG::ERROR << "  Converter handle type was " << reqCnvTypeName <<  endmsg;
   errorHandler();
}

createPersistent()

virtual PERS * TPAbstractPolyCnvBase< TRANS, TRANS, PERS >::createPersistent ( const TRANS * transObj, MsgStream & log )

virtualinherited

Create persistent representation of a transient object.

Simply creates a new persistent object and calls transToPers()

Parameters

transObj	[IN] transient object
log	[IN] output message stream

Returns

the created persistent representation

createPersistentConst()

template<class TRANS, class PERS>

virtual PERS * TPConverterConstBase< TRANS, PERS >::createPersistentConst ( const TRANS * transObj, MsgStream & log ) const

virtualinherited

createPersistentWithKey()

virtual PERS * TPAbstractPolyCnvBase< TRANS, TRANS, PERS >::createPersistentWithKey ( const TRANS * transObj, const std::string & key, MsgStream & log )

virtualinherited

Create persistent representation of a transient object, with SG key.

Simply creates a new persistent object and calls transToPersWithKey()

Parameters

transObj	[IN] transient object
key	[IN] SG key of object being written
log	[IN] output message stream

Returns

the created persistent representation

createTransFromPStore()

template<class TRANS>

template<class CNV>

CNV::Trans_t * ITPConverterFor< TRANS >::createTransFromPStore ( CNV ** cnv, const TPObjRef & ref, MsgStream & log ) const

inlineinherited

Create transient representation of a persistent object, stored in the the top-level persistent object and referenced by the TP Ref.

If a TP converter is not specified, it will be found based on the Ref type.

Parameters

cnv	[IN][OUT] pointer to the converter, usually 0 at the start. Once the right converter is found, this pointer will be set so the search is done only once
ref	[IN] TP Ref to the persistent object to be converted
log	[IN] output message stream

Returns

pointer to the created transient represention

Definition at line 172 of file TPConverter.h.

                                                                               {
     if( ref.isNull() )  return 0;
     CNV *temp_cnv_p = 0;
     if( !cnv ) cnv = &temp_cnv_p;
     // see if we already have a converter and if it is the right one
     if( !*cnv || (*cnv)->typeID().value() != ref.typeID() ) {
        // we don't - find the right converter for ref.typeID()
    *cnv = converterForRef( *cnv, ref, log );
    if( !*cnv ) return 0;
        (*cnv)->setReadingFlag();
     }
     return (**cnv).virt_createTransFromPStore( ref.index(), log );
  }

createTransient()

virtual TRANS * TPPolyCnvBase< TRANS, TRANS, PERS >::createTransient ( const PERS * persObj, MsgStream & log )

virtualinherited

Create transient representation of a persistent object.

Simply creates a new transient object and calls persToTrans()

Parameters

persObj	[IN] persistent object
log	[IN] output message stream

Returns

the created transient object

createTransientConst()

template<class TRANS, class PERS>

virtual TRANS * TPConverterConstBase< TRANS, PERS >::createTransientConst ( const PERS * persObj, MsgStream & log ) const

virtualinherited

createTransientWithKey()

virtual TRANS * TPPolyCnvBase< TRANS, TRANS, PERS >::createTransientWithKey ( const PERS * persObj, const std::string & key, MsgStream & log )

virtualinherited

Create transient representation of a persistent object, with SG key.

Simply creates a new transient object and calls persToTransWithKey()

Parameters

persObj	[IN] persistent object
key	[IN] SG key of object being read
log	[IN] output message stream

Returns

the created transient object

fillTransFromPStore()

template<class TRANS>

template<class CNV, class TRANS_T>

void ITPConverterFor< TRANS >::fillTransFromPStore ( CNV ** cnv, const TPObjRef & ref, TRANS_T * trans, MsgStream & log ) const

inlineinherited

Convert persistent object, stored in the the top-level persistent object and referenced by the TP Ref, to transient representation.

An empty transient object to be filled in is provided. If converter is not given, it will be found based on the Ref type.

Parameters

cnv	[IN][OUT] pointer to the converter, usually 0 at the start. Once the right converter is found, this pointer will be set so the search is done only once
ref	[IN] TP Ref to the persistent object to be converted
trans	[IN] pointer to the empty transient object
log	[IN] output message stream

Definition at line 145 of file TPConverter.h.

                                                                                                    {
    if( ref.isNull() )  return;
    CNV *temp_cnv_p = 0;
    if( !cnv ) cnv = &temp_cnv_p;
    // see if we already have a converter and if it is the right one
    if( !*cnv || (*cnv)->typeID().value() != ref.typeID() ) {
       // we don't - find the right converter for ref.typeID()
       *cnv = converterForRef( *cnv, ref, log );
       if( !*cnv ) return;
       (*cnv)->setReadingFlag();
     }
    (**cnv).pstoreToTrans( ref.index(), trans, log );
  }

ignoreRecursion()

void TPAbstractPolyCnvBase< TRANS, TRANS, PERS >::ignoreRecursion ( bool flag = false )

inlineinherited

Tell the converter to ignore recursion (do not throw errors) even when recurion is detected.

UNSAFE! use only if you are sure you preallocated enough persistent storage

Definition at line 568 of file TPConverter.h.

                                           {
     m_ignoreRecursion = flag;
  }

initPrivateConverters()

template<class TRANS>

virtual void ITPConverterFor< TRANS >::initPrivateConverters ( TopLevelTPCnvBase * )

inlinevirtualinherited

Reimplemented in JetCnv_p4, MeasuredAtaSurfaceCnv_p1< SURFACE_CNV, ATA_SURFACE >, MeasuredAtaSurfaceCnv_p1< AtaCylinderCnv_p1, Trk::AtaCylinder >, MeasuredAtaSurfaceCnv_p1< AtaDiscCnv_p1, Trk::AtaDisc >, MeasuredAtaSurfaceCnv_p1< AtaPlaneCnv_p1, Trk::AtaPlane >, MeasuredAtaSurfaceCnv_p1< AtaStraightLineCnv_p1, Trk::AtaStraightLine >, MeasuredAtaSurfaceCnv_p1< CurvilinearParametersCnv_p1, Trk::CurvilinearParameters >, MeasuredNeutralAtaSurfaceCnv_p1< SURFACE_CNV, ATA_SURFACE >, MeasuredNeutralAtaSurfaceCnv_p1< NeutralAtaCylinderCnv_p1, Trk::NeutralAtaCylinder >, MeasuredNeutralAtaSurfaceCnv_p1< NeutralAtaDiscCnv_p1, Trk::NeutralAtaDisc >, MeasuredNeutralAtaSurfaceCnv_p1< NeutralAtaPlaneCnv_p1, Trk::NeutralAtaPlane >, MeasuredNeutralAtaSurfaceCnv_p1< NeutralAtaStraightLineCnv_p1, Trk::NeutralAtaStraightLine >, SegmentCnv_p1, TauPi0CandidateCnv_p1, TauPi0ClusterCnv_p1, TauPi0DetailsCnv_p1, TauPi0DetailsCnv_p2, TrackCnv_p12, TrackCnv_p1, TrackCnv_p2, TrackCnv_p3, TrackCnv_p4, TrackParticleBaseCnv_p1, TrackParticleCnv_p2, TrackParticleCnv_p3, TrigInDetTrackCollectionCnv_p1, TrigVertexCnv_p1, TrigVertexCnv_p2, V0CandidateCnv_p1, VxCandidateCnv_p1, and VxCandidateCnv_p2.

Definition at line 187 of file TPConverter.h.

{}

persistentTInfo()

virtual const std::type_info & TPAbstractPolyCnvBase< TRANS, TRANS, PERS >::persistentTInfo ( ) const

inlinevirtualinherited

return C++ type id of the persistent class this converter is for

Returns

std::type_info&

Implements ITPCnvBase.

Definition at line 482 of file TPConverter.h.

{ return typeid(PERS); }

persToTrans() [1/3]

void LArOFCSubsetCnv_p1::persToTrans ( const LArOFCPersType * persObj, LArOFCTransType * transObj, MsgStream & log ) const

overridevirtual

Definition at line 9 of file LArOFCSubsetCnv_p1.cxx.

{
    // Copy basic metadata
    transObj->setChannel       (persObj->m_subset.m_channel);
    transObj->setGroupingType  (persObj->m_subset.m_groupingType);
 
    transObj->initialize (persObj->m_subset.m_febIds, persObj->m_subset.m_gain);
 
    // Copy conditions
    unsigned int nfebids    = persObj->m_subset.m_febIds.size();
    const unsigned int nChannelsPerFeb  = persObj->m_subset.subsetSize();
    unsigned int nPhases    = persObj->m_nPhases;
    unsigned int nSamples   = persObj->m_nSamples;
    unsigned int dataIndex  = 0;
    unsigned int timeIndex  = 0;
 
    // Loop over febs
    unsigned int ifebWithData = 0; // counter for febs with data
 
    auto subsetIt = transObj->subsetBegin();
    for (unsigned int i = 0; i < nfebids; ++i, ++subsetIt){
        // Set febid
        unsigned int febid = (*subsetIt).first;
 
        bool hasSparseData       = false;
        unsigned int chansSet    = 0;
        unsigned int chansOffset = 0;
        if (ifebWithData+1 < persObj->m_subset.m_febsWithSparseData.size() &&
            febid == persObj->m_subset.m_febsWithSparseData[ifebWithData]) {
            // Found feb with sparse data
            hasSparseData = true;
            ifebWithData++;
            chansSet    = persObj->m_subset.m_febsWithSparseData[ifebWithData];
            chansOffset = 0;
            ifebWithData++;
        }
            
        // Loop over channels in feb - only some channels are filled
        for (unsigned int j = 0; j < nChannelsPerFeb; ++j){
 
            bool copyChannel = true;
            if (hasSparseData) {
                // coverity[bad_shift]
                // coverity[integer_overflow]
                if (!(chansSet & (1 << (j - chansOffset)))) {
                    // Channel is missing data - skip
                    copyChannel = false;
                            }
                if (j%32 == 31 && j < nChannelsPerFeb-2) {
                    chansSet     = persObj->m_subset.m_febsWithSparseData[ifebWithData];
                    chansOffset += 32;
                    ifebWithData++;
                }
            }
            if (copyChannel) {
                        
                // Channel has ofcs - loop over ofcs per channel and
                // copy to the persistent object
 
                // check indexes
                if (dataIndex  >= persObj->m_vOFC_a.size()    ||
                    dataIndex  >= persObj->m_vOFC_b.size()    ||
                    timeIndex >= persObj->m_timeOffset.size() ||
                    timeIndex >= persObj->m_timeBinWidth.size()) {
                    log << MSG::ERROR 
                        << "LArOFCSubsetCnv_p1::persToTrans - ofc index too large: dataIndex size ofc_a, size ofc_b, timeIndex timeOffset size, timeBinWidth size " 
                        << dataIndex  << " " << persObj->m_vOFC_a.size() << " " 
                        << persObj->m_vOFC_b.size() << " " << timeIndex << " "
                        << persObj->m_timeOffset.size() << " " 
                        << persObj->m_timeBinWidth.size()
                        << endmsg;
                    return;
                }
 
                LArOFCTransType::Reference ofcs =
                  (*subsetIt).second[j];
                LArOFCP1 tmp (persObj->m_timeOffset[timeIndex],
                              persObj->m_timeBinWidth[timeIndex],
                              nPhases,
                              nSamples,
                              persObj->m_vOFC_a,
                              persObj->m_vOFC_b,
                              dataIndex);
                ofcs.assign (tmp);
                ++timeIndex;
                dataIndex += nPhases * nSamples;
            }
        }
    }
 
    // Copy corrections
    unsigned int ncorrs     = persObj->m_subset.m_corrChannels.size();
    LArOFCTransType::CorrectionVec corrs;
 
    if (ncorrs) {
        // corrs exist - resize vector
        std::vector<float>               vSamples(nSamples, 0.0);
        std::vector<std::vector<float> > vOFC(nPhases, vSamples);
        LArOFCP1  larOFCP1(0.0, 0.0, vOFC, vOFC);
 
        corrs.resize(ncorrs, LArOFCTransType::CorrectionPair(0, larOFCP1));
    }
 
    // Loop over corrections
    for (unsigned int i = 0; i < ncorrs; ++i){
        // check indexes
        if (dataIndex  >= persObj->m_vOFC_a.size()    ||
            dataIndex  >= persObj->m_vOFC_b.size()    ||
            timeIndex >= persObj->m_timeOffset.size() ||
            timeIndex >= persObj->m_timeBinWidth.size()) {
            log << MSG::ERROR 
                << "LArOFCSubsetCnv_p1::persToTrans - ofc index too large: dataIndex size ofc_a, size ofc_b, timeIndex timeOffset size, timeBinWidth size " 
                << dataIndex  << " " << persObj->m_vOFC_a.size() << " " 
                << persObj->m_vOFC_b.size() << " " << timeIndex << " "
                << persObj->m_timeOffset.size() << " " 
                << persObj->m_timeBinWidth.size()
            << endmsg;
            return;
        }
 
        // copy channel id
        corrs[i].first = persObj->m_subset.m_corrChannels[i];
 
        LArOFCP1& ofcs = corrs[i].second;
        LArOFCP1 tmp (persObj->m_timeOffset[timeIndex],
                      persObj->m_timeBinWidth[timeIndex],
                      nPhases,
                      nSamples,
                      persObj->m_vOFC_a,
                      persObj->m_vOFC_b,
                      dataIndex);
        ofcs.setFrom (tmp);
        ++timeIndex;
        dataIndex += nPhases * nSamples;
    }
    transObj->insertCorrections (std::move (corrs));
 
    transObj->shrink_to_fit();
}

persToTrans() [2/3]

virtual void TPConverterConstBase< TRANS, PERS >::persToTrans ( const PERS * persObj, TRANS * transObj, MsgStream & log ) const

virtual

Convert persistent representation to transient one.

Copies data members from persistent object to an existing transient one. Needs to be implemented by the developer on the actual converter.

Parameters

persObj	[IN] persistent object
transObj	[IN] transient object
log	[IN] output message stream

Implements TPConverterConstBase< TRANS, PERS >.

persToTrans() [3/3]

virtual void TPConverterConstBase< TRANS, PERS >::persToTrans ( const PERS * persObj, TRANS * transObj, MsgStream & log )

inlinefinaloverridevirtual

Convert persistent representation to transient one.

Copies data members from persistent object to an existing transient one. Needs to be implemented by the developer on the actual converter.

Parameters

persObj	[IN] persistent object
transObj	[IN] transient object
log	[IN] output message stream

Reimplemented from TPConverterConstBase< TRANS, PERS >.

Definition at line 807 of file TPConverter.h.

  {
    return const_cast<const TPConverterConstBase*>(this)->persToTrans (persObj, transObj, log);
  }

persToTransUntyped()

virtual void TPAbstractPolyCnvBase< TRANS, TRANS, PERS >::persToTransUntyped ( const void * pers, void * trans, MsgStream & log )

inlinevirtualinherited

Convert persistent object representation to transient.

Parameters

pers	[IN] void* pointer to the persistent object
trans	[OUT] void* pointer to the empty transient object
log	[IN] output message stream

Implements ITPCnvBase.

Definition at line 400 of file TPConverter.h.

  {
    persToTrans (reinterpret_cast<const PERS*> (pers),
                 reinterpret_cast<TRANS*> (trans),
                 log);
  }

persToTransWithKey()

virtual void TPAbstractPolyCnvBase< TRANS, TRANS, PERS >::persToTransWithKey ( const PERS * persObj, TRANS * transObj, const std::string & , MsgStream & log )

inlinevirtualinherited

Convert persistent representation to transient one.

Copies data members from persistent object to an existing transient one. Needs to be implemented by the developer on the actual converter.

Parameters

persObj	[IN] persistent object
transObj	[IN] transient object
log	[IN] output message stream

Reimplemented in AthExParticlesCnv_p1, CaloCellContainerCnv_p1, CaloCellLinkContainerCnv_p1, CaloCellLinkContainerCnv_p2, CaloClusterCellLinkContainerCnv_p1, TPConverterWithKeyBase< TRANS, PERS >, and xAODTauJetAuxContainerCnv_v2.

Definition at line 376 of file TPConverter.h.

  {
    return persToTrans (persObj, transObj, log);
  }

persToTransWithKeyUntyped()

virtual void TPAbstractPolyCnvBase< TRANS, TRANS, PERS >::persToTransWithKeyUntyped ( const void * pers, void * trans, const std::string & key, MsgStream & log )

inlinevirtualinherited

Convert persistent object representation to transient.

Parameters

pers	[IN] void* pointer to the persistent object
trans	[OUT] void* pointer to the empty transient object
key	[IN] SG key of object being read.
log	[IN] output message stream

Reimplemented from ITPCnvBase.

Definition at line 420 of file TPConverter.h.

  {
    persToTransWithKey (reinterpret_cast<const PERS*> (pers),
                        reinterpret_cast<TRANS*> (trans),
                        key,
                        log);
  }

pstoreToTrans()

template<class TRANS, class PERS>

virtual void TPConverterBase< TRANS, PERS >::pstoreToTrans ( unsigned index, TRANS * trans, MsgStream & log )

inlinevirtualinherited

Convert persistent representation stored in the storage vector of the top-level object to transient.

Internal.

Parameters

index	[IN] index of the persistent representation in the storage vector
trans	[IN] empty transient object
log	[IN] output message stream

Reimplemented from TPAbstractPolyCnvBase< TRANS, TRANS, PERS >.

Definition at line 760 of file TPConverter.h.

                                                                              {
     assert (index < this->m_pStorage->size());
     this->persToTrans( &(*this->m_pStorage)[index], trans, log );
  }

reservePStorage()

virtual void TPAbstractPolyCnvBase< TRANS, TRANS, PERS >::reservePStorage ( size_t size )

inlinevirtualinherited

Reserve 'size' elements for persistent storage.

Implements ITPConverter.

Definition at line 573 of file TPConverter.h.

                                               {
     m_pStorage->reserve( size );
  }

setPStorage()

void TPAbstractPolyCnvBase< TRANS, TRANS, PERS >::setPStorage ( std::vector< PERS > * storage )

inlineinherited

Tell this converter which storage vector it should use to store or retrieve persistent representations.

Parameters

storage

[IN] the address of the storage vector

Definition at line 551 of file TPConverter.h.

                                                  {
     m_pStorage = storage;
     m_curRecLevel = 0;
  }

setReadingFlag()

template<class TRANS>

void ITPConverterFor< TRANS >::setReadingFlag ( )

inlineinherited

Definition at line 234 of file TPConverter.h.

{ m_wasUsedForReading = true; }

setRecursive()

void TPAbstractPolyCnvBase< TRANS, TRANS, PERS >::setRecursive ( bool flag = true )

inlineinherited

Tell the converter if it should work in recursive mode slower but it can safely handle recursion.

Definition at line 559 of file TPConverter.h.

                                       {
     m_recursive = flag;
  }

setRuntimeTopConverter()

template<class TRANS>

virtual void ITPConverterFor< TRANS >::setRuntimeTopConverter ( TopLevelTPCnvBase * topConverter )

inlinevirtualinherited

Set runtime top-level converter - usually it is the owning TL converter, but in case of extended objects it will be the TL converter of the extended object.

Parameters

topConverter

[IN] runtime top-level converter for this converter

Implements ITPConverter.

Definition at line 215 of file TPConverter.h.

                                                                          {
     m_topConverterRuntime = topConverter;
     initPrivateConverters( topConverter );
  }

setTopConverter()

template<class TRANS>

virtual void ITPConverterFor< TRANS >::setTopConverter ( TopLevelTPCnvBase * topConverter, const TPObjRef::typeID_t & TPtypeID )

inlinevirtualinherited

Set which top-level converter owns this elemental converter, and what TPtypeID was assigned to the persistent objects it produces.

Parameters

topConverter	[IN] the top-level converter owning this converter
TPtypeID	[IN] TP type id for persistent objects (used in TP refs)

Implements ITPConverter.

Definition at line 221 of file TPConverter.h.

  {
     m_topConverter = m_topConverterRuntime = topConverter;
     m_pStorageTID = TPtypeID;
     m_pStorageTIDvalue = TPtypeID.value();
     initPrivateConverters( topConverter );
  }

topConverter() [1/2]

template<class TRANS>

virtual TopLevelTPCnvBase * ITPConverterFor< TRANS >::topConverter ( )

inlinevirtualinherited

return the top-level converter for this elemental TP converter

Returns

TopLevelTPCnvBas

Reimplemented from ITPConverter.

Definition at line 191 of file TPConverter.h.

                                               {
     return m_topConverter;
  }

topConverter() [2/2]

template<class TRANS>

virtual const TopLevelTPCnvBase * ITPConverterFor< TRANS >::topConverter ( ) const

inlinevirtualinherited

return the top-level converter for this elemental TP converter

Returns

TopLevelTPCnvBas

Reimplemented from ITPConverter.

Definition at line 196 of file TPConverter.h.

                                                         {
     return m_topConverter;
  }

toPersistent()

template<class TRANS>

template<class CNV>

TPObjRef ITPConverterFor< TRANS >::toPersistent ( CNV ** cnv, const typename CNV::TransBase_t * transObj, MsgStream & log ) const

inlineinherited

Persistify an object and store the persistent represenation in the storage vector of the top-level persistent object.

The correct converter is located using the actual object type.

Parameters

cnv	[IN/OUT] pointer to the converter, usually 0 at the start. Once the right converter is found, this pointer will be set so the search is done only once
transObj	[IN] transient object
log	[IN] output message stream

Returns

TPObjRef TP reference to the persistent representation stored in the storage vector of the top-level persistent object

Definition at line 119 of file TPConverter.h.

                                                                                                   {
     if( !transObj ) return TPObjRef();
     CNV *temp_cnv_p = 0;
     if( !cnv ) cnv = &temp_cnv_p;
     if( !*cnv || (*cnv)->wasUsedForReading() ) {
        // don't trust the converter if it was used for reading, find again
    *cnv = converterForType( *cnv, typeid(*transObj), log );
    if( !*cnv )  return TPObjRef();
        (*cnv)->clearReadingFlag();
     }
     return (**cnv).virt_toPersistent(transObj, log);
  }

toPersistentWithKey_impl()

TPObjRef TPAbstractPolyCnvBase< TRANS, TRANS, PERS >::toPersistentWithKey_impl ( const TRANS * trans, const std::string & key, MsgStream & log )

inherited

Convert transient object to persistent representation.

Stores the result in the storage vector of the top-level object and returns a TP Ref to it.

Parameters

trans	[IN] transient object
key	[IN] SG key of object being converted
log	[IN] output message stream

Returns

TP reference to the persistent representation

transBaseTInfo()

template<class TRANS>

const std::type_info & ITPConverterFor< TRANS >::transBaseTInfo ( ) const

inlinevirtualinherited

return C++ type id of the common base transient type for all converters for a group of polymorphic types

Returns

std::type_info& this method is not overwritten in the subclasses like transientTInfo()

Implements ITPConverter.

Definition at line 205 of file TPConverter.h.

{ return typeid(TRANS); }

transientTInfo()

virtual const std::type_info & TPAbstractPolyCnvBase< TRANS, TRANS, PERS >::transientTInfo ( ) const

inlinevirtualinherited

return C++ type id of the transient class this converter is for

Returns

std::type_info&

Reimplemented from ITPConverterFor< TRANS >.

Definition at line 479 of file TPConverter.h.

{ return typeid(TRANS); }

transToPers() [1/3]

void LArOFCSubsetCnv_p1::transToPers ( const LArOFCTransType * transObj, LArOFCPersType * persObj, MsgStream & log ) const

overridevirtual

Definition at line 153 of file LArOFCSubsetCnv_p1.cxx.

{
    // Copy conditions
 
    // We copy all ofcs into a few simple vectors. 
    // For the conditions, there are two situations to treat: 
    //   1) dense data: normal conditions where each feb has 128
    //      channels and all channels have data,
    //   2) sparse data: conditions data where some channels are
    //      missing data. This is true for MC conditions (only some
    //      channels have data, and symmetry is used to obtain
    //      conditions for the rest of the channels), as well for
    //      'normal' conditions it may happen that some channels may
    //      be missing data.
    //
    // Treating 1) is straight-forward. For 2) we need to keep track
    // of which channels are present. We do so with
    // m_subset.m_febsWithSparseData where we store the febid followed by
    // four unsigned ints which contain the full bit pattern of the
    // channels set (i.e. bits 0-127).
    //
    // Note that one may also have a subset with all channels missing
    // data. In this case, we do not write out the empty subset.
    //
    // Finally, for corrections, we save the channel ids in
    // m_subset.m_corrChannels and the ofcs in the same vectors as the
    // rest of the conditions data.
    //
    // For each channel with data, the number of ofcs is assumed
    // constant. This is calculated at the beginning, along with
    // whether a feb is sparse or not.
    //
 
    // Get the number of channels, corrections and the size of ofc vectors
    unsigned int nsubsetsNotEmpty = 0;
    unsigned int ncorrs           = transObj->correctionVecSize();
    const unsigned int nChannelsPerFeb  = transObj->channelVectorSize();
    unsigned int nchans           = 0;
    unsigned int nPhases          = 0;
    unsigned int nSamples         = 0;
    bool foundOFCs                = false;
    std::vector<unsigned int> febsWithSparseData;
 
    // Find the number of ofcs and check for sparse conditions,
    // e.g. MC conditions
    const auto subsetEnd = transObj->subsetEnd();
    for (auto subsetIt = transObj->subsetBegin();
         subsetIt != subsetEnd;
         ++subsetIt)
    {
        unsigned int nfebChans = (*subsetIt).second.size();
 
        if (nfebChans != 0 && nfebChans != nChannelsPerFeb) {
            log << MSG::ERROR 
                << "LArOFCSubsetCnv_p1::transToPers - found incorrect number of channels per feb: " << nfebChans
                << endmsg;
            return;
        }
        if (nfebChans) ++nsubsetsNotEmpty; // count number of non-empty subsets
 
        // Loop over channels and check if this subset has sparse data
        bool subsetIsSparse = false;
        for (unsigned int j = 0; j < nfebChans; ++j) {
            LArOFCTransType::ConstReference ofc = 
              (*subsetIt).second[j];
            if (ofc.OFC_aSize() == 0) {
                if (!subsetIsSparse) {
                    // save febids for sparse subsets
                    subsetIsSparse = true;
                    febsWithSparseData.push_back((*subsetIt).first);
                }
            }
            else {
                nchans++; // count number of channels
                if (!foundOFCs) {
                    // Save the number of phases and samples for each
                    // ofc from first channels present
                    nPhases       = ofc.OFC_aSize();
                    nSamples      = ofc.OFC_a(0).size();
                    foundOFCs     = true;
                }
            }
        }
    }
    if (!foundOFCs && ncorrs>0) {
        // Save the number of phases and samples for each ofc from
        // first correction - couldn't find it from channels
        const LArOFCP1& ofc = transObj->correctionVecBegin()->second;
        nPhases             = ofc.OFC_aSize();
        nSamples            = ofc.OFC_a(0).size();
    }
 
    // Save sizes
    persObj->m_nPhases    = nPhases;
    persObj->m_nSamples   = nSamples;
 
    // Reserve space in vectors
    persObj->m_subset.m_febIds.reserve(nsubsetsNotEmpty);
    persObj->m_subset.m_corrChannels.reserve(ncorrs);
    unsigned int ndataTot  = (nchans + ncorrs)*nPhases*nSamples;
    unsigned int nTime     = (nchans + ncorrs);
    persObj->m_vOFC_a.reserve(ndataTot);
    persObj->m_vOFC_b.reserve(ndataTot);
    persObj->m_timeOffset.reserve(nTime);
    persObj->m_timeBinWidth.reserve(nTime);
 
    // For subsets with sparse data, reserve space for identifying
    // channels written out:
    //   1 - febid
    //   4 - for 128 bits (4*32)
    if (febsWithSparseData.size())
        persObj->m_subset.m_febsWithSparseData.reserve(febsWithSparseData.size()*5);
 
    // Copy conditions in subset
    unsigned int isparse = 0;
    for (auto subsetIt = transObj->subsetBegin();
         subsetIt != subsetEnd;
         ++subsetIt)
    {
        unsigned int nfebChans = (*subsetIt).second.size();
 
        // skip subsets without any channels
        if (nfebChans == 0) continue;
        
        unsigned int febid = (*subsetIt).first;
        persObj->m_subset.m_febIds.push_back(febid);
 
 
        bool isSparse = false;
        if (isparse < febsWithSparseData.size() && 
            febsWithSparseData[isparse] == febid) {
            // sparse subset, save channels with data
            isparse++;
            isSparse = true;
            // save febid
            persObj->m_subset.m_febsWithSparseData.push_back(febid);            
        }
            
        // Now loop over channels and save ofc and times
        unsigned int chansSet    = 0;
        unsigned int chansOffset = 0;
        for (unsigned int j = 0; j < nfebChans; ++j){
 
            bool saveOFCs = true;
            if (isSparse) {
                // subset with sparse data
          if ((*subsetIt).second[j].OFC_aSize() > 0) {
                    // store the channel number in bit map
                    assert (j >= chansOffset && (j - chansOffset) <= 31);
                    // coverity[integer_overflow]
                    chansSet |= (1 << (j - chansOffset));
                }
                else {
          saveOFCs = false;
                }
                // Save chansSet
                if  (j == (chansOffset + 31) || j == nfebChans-1) {
                    persObj->m_subset.m_febsWithSparseData.push_back(chansSet);
                    chansSet    =   0;
                    chansOffset += 32;
                }
            }
            if (saveOFCs) {
            bool tooSmall=false;
        // Loop over phases and samples per channel
                for (unsigned int k = 0; k < nPhases; ++k) {
                    for (unsigned int l = 0; l < nSamples; ++l) {
              //check if data object is big enough
              if (k >= (*subsetIt).second[j].OFC_aSize() ||
                          l >= (*subsetIt).second[j].OFC_a(k).size())
                      {
            tooSmall=true;
            persObj->m_vOFC_a.push_back(0.);
            persObj->m_vOFC_b.push_back(0.);
              }
              else {
                        persObj->m_vOFC_a.push_back((*subsetIt).second[j].OFC_a(k)[l]);
                        persObj->m_vOFC_b.push_back((*subsetIt).second[j].OFC_b(k)[l]);
//                      std::cout << "WL Data: FEB=" << std::hex << febid << std::dec << " [" << i << "] Channel=" 
//                << j << " Phase="<< k<< " Sample " << l << " OFC=" 
//                << (*subsetIt).second[j].m_vOFC_a[k][l] << std::endl;
              }
                    }
                }
                // set time offset and binwidth
                persObj->m_timeOffset.push_back((*subsetIt).second[j].timeOffset());
                persObj->m_timeBinWidth.push_back((*subsetIt).second[j].timeBinWidth());
        if (tooSmall)
          log << MSG::ERROR << "Feb 0x" << std::hex << febid << std::dec << " channel " << j <<": OFC object too small. Expected " 
              << nPhases << " phases and " << nSamples << " samples. Padded with 0.0" << endmsg;
 
            }// end if saveOFC
 
//             static unsigned int nch = 0;
//             ++nch;
//             std::cout << "transToPers - i, j, save " << i << " " << j << " " 
//                       << saveOFCs << " " << nch << " febid " << febid
//                       << " chansSet " << std::hex << chansSet << std::dec
//                       << " chansOffset " << chansOffset
//                       << std::endl;
 
        }
    }
 
    // Copy corrections
    const auto corrEnd = transObj->correctionVecEnd();
    for (auto corrIt = transObj->correctionVecBegin();
         corrIt != corrEnd;
         ++corrIt)
    {
        persObj->m_subset.m_corrChannels.push_back(corrIt->first);
        // OFCs
    bool tooSmall=false;
    // Loop over phases and samples per channel
        for (unsigned int k = 0; k < nPhases; ++k) {
            for (unsigned int l = 0; l < nSamples; ++l) {
           //check if data object is big enough
          if (k >= corrIt->second.OFC_aSize() ||
                  l >= corrIt->second.OFC_a(k).size())
              {
        tooSmall=true;
        persObj->m_vOFC_a.push_back(0.);
        persObj->m_vOFC_b.push_back(0.);
          }
          else {
                persObj->m_vOFC_a.push_back(corrIt->second.OFC_a(k)[l]);
                persObj->m_vOFC_b.push_back(corrIt->second.OFC_b(k)[l]);
          }
        }
        }
        // set time offset and binwidth
        persObj->m_timeOffset.push_back(corrIt->second.timeOffset());
        persObj->m_timeBinWidth.push_back(corrIt->second.timeBinWidth());
    if (tooSmall)
      log << MSG::ERROR << "Correction (channel 0x" << std::hex << corrIt->first << std::dec <<  
        "): OFC object too small. Expected " << nPhases << " phases and " << nSamples << " samples. Padded with 0.0" << endmsg;
    }
 
    // Copy the rest
    persObj->m_subset.m_gain          = transObj->gain(); 
    persObj->m_subset.m_channel       = transObj->channel();
    persObj->m_subset.m_groupingType  = transObj->groupingType();
    
}

transToPers() [2/3]

virtual void TPConverterConstBase< TRANS, PERS >::transToPers ( const TRANS * transObj, PERS * persObj, MsgStream & log ) const

virtual

Convert transient representation to persistent one.

Copies data members from transient object to an existing persistent one. Needs to be implemented by the developer on the actual converter.

Parameters

transObj	[IN] transient object
persObj	[IN] persistent object
log	[IN] output message stream

Implements TPConverterConstBase< TRANS, PERS >.

transToPers() [3/3]

virtual void TPConverterConstBase< TRANS, PERS >::transToPers ( const TRANS * transObj, PERS * persObj, MsgStream & log )

inlinefinaloverridevirtual

Convert transient representation to persistent one.

Copies data members from transient object to an existing persistent one. Needs to be implemented by the developer on the actual converter.

Parameters

transObj	[IN] transient object
persObj	[IN] persistent object
log	[IN] output message stream

Reimplemented from TPConverterConstBase< TRANS, PERS >.

Definition at line 815 of file TPConverter.h.

  {
    return const_cast<const TPConverterConstBase*>(this)->transToPers (transObj, persObj, log);
  }

transToPersUntyped()

virtual void TPAbstractPolyCnvBase< TRANS, TRANS, PERS >::transToPersUntyped ( const void * trans, void * pers, MsgStream & log )

inlinevirtualinherited

Convert transient object representation to persistent.

Parameters

trans	[IN] void* pointer to the transient object
pers	[OUT] void* pointer to the empty persistent object
log	[IN] output message stream

Implements ITPCnvBase.

Definition at line 410 of file TPConverter.h.

  {
    transToPers (reinterpret_cast<const TRANS*> (trans),
                 reinterpret_cast<PERS*> (pers),
                 log);
  }

transToPersWithKey()

virtual void TPAbstractPolyCnvBase< TRANS, TRANS, PERS >::transToPersWithKey ( const TRANS * transObj, PERS * persObj, const std::string & , MsgStream & log )

inlinevirtualinherited

Convert transient representation to persistent one.

Copies data members from transient object to an existing persistent one. Needs to be implemented by the developer on the actual converter.

Parameters

transObj	[IN] transient object
persObj	[IN] persistent object
key	[IN] SG key of object being written.
log	[IN] output message stream

Reimplemented in AthExParticlesCnv_p1, CaloCellContainerCnv_p1, CaloCellLinkContainerCnv_p1, CaloCellLinkContainerCnv_p2, CaloClusterCellLinkContainerCnv_p1, TPConverterWithKeyBase< TRANS, PERS >, and xAODTauJetAuxContainerCnv_v2.

Definition at line 392 of file TPConverter.h.

  {
    return transToPers (transObj, persObj, log);
  }

transToPersWithKeyUntyped()

virtual void TPAbstractPolyCnvBase< TRANS, TRANS, PERS >::transToPersWithKeyUntyped ( const void * trans, void * pers, const std::string & key, MsgStream & log )

inlinevirtualinherited

Convert transient object representation to persistent.

Parameters

trans	[IN] void* pointer to the transient object
pers	[OUT] void* pointer to the empty persistent object
key	[IN] SG key of object being written.
log	[IN] output message stream

Reimplemented from ITPCnvBase.

Definition at line 432 of file TPConverter.h.

  {
    transToPersWithKey (reinterpret_cast<const TRANS*> (trans),
                        reinterpret_cast<PERS*> (pers),
                        key,
                        log);
  }

typeID()

template<class TRANS>

virtual const TPObjRef::typeID_t & ITPConverterFor< TRANS >::typeID ( ) const

inlinevirtualinherited

Return TP typeID for persistent objects produced by this converter.

Returns

TPObjRef::typeID_t&

Implements ITPConverter.

Definition at line 208 of file TPConverter.h.

{ return m_pStorageTID; }

typeIDvalue()

template<class TRANS>

unsigned ITPConverterFor< TRANS >::typeIDvalue ( ) const

inlineinherited

inlined non-virtual version to get the typeID value fast

Definition at line 211 of file TPConverter.h.

{ return m_pStorageTIDvalue; }

virt_createTransFromPStore()

virtual TRANS * TPPolyCnvBase< TRANS, TRANS, PERS >::virt_createTransFromPStore ( unsigned index, MsgStream & log )

inlinevirtualinherited

Internal interface method that is used to invoke the real conversion method (createTransient)

Parameters

index	[IN] index of the persistent object in the storage vector
log	[IN] output message stream

Returns

Created transient object (by pointer)

Reimplemented from TPAbstractPolyCnvBase< TRANS, TRANS, PERS >.

Definition at line 706 of file TPConverter.h.

                                                                               {
     assert (index < this->m_pStorage->size());
     return createTransient( &(*this->m_pStorage)[index], log );
  }

virt_createTransFromPStoreWithKey()

virtual TRANS * TPPolyCnvBase< TRANS, TRANS, PERS >::virt_createTransFromPStoreWithKey ( unsigned index, const std::string & key, MsgStream & log )

inlinevirtualinherited

Internal interface method that is used to invoke the real conversion method (createTransient)

Parameters

index	[IN] index of the persistent object in the storage vector
key	[IN] SG key of the object being converted
log	[IN] output message stream

Returns

Created transient object (by pointer)

Reimplemented from TPAbstractPolyCnvBase< TRANS, TRANS, PERS >.

Definition at line 718 of file TPConverter.h.

  {
     assert (index < this->m_pStorage->size());
     return createTransientWithKey( &(*this->m_pStorage)[index], key, log );
  }

virt_toPersistent()

template<class TRANS, class PERS>

virtual TPObjRef TPConverterBase< TRANS, PERS >::virt_toPersistent ( const TRANS * trans, MsgStream & log )

inlinevirtualinherited

Internal interface method that is used to invoke the real conversion method (toPersistent_impl) in the derived converter.

Parameters

trans	[IN] transient object
log	[IN] output message stream

Returns

TPObjRef TP reference to the persistent representation stored in the storage vector of the top-level persistent object Here toPersistent_impl is invoked with the dynamic cast of the transient type pointer to it's actual type

Reimplemented from TPAbstractPolyCnvBase< TRANS, TRANS, PERS >.

Definition at line 747 of file TPConverter.h.

                                                                           {
    return this->toPersistentWithKey_impl( trans, "", log);
  }

virt_toPersistentWithKey()

template<class TRANS, class PERS>

virtual TPObjRef TPConverterBase< TRANS, PERS >::virt_toPersistentWithKey ( const TRANS * trans, const std::string & key, MsgStream & log )

inlinevirtualinherited

Internal interface method that is used to invoke the real conversion method (toPersistent_impl) in the derived converter.

Parameters

trans	[IN] transient object
key	[IN] SG key of the object being converted.
log	[IN] output message stream

Returns

TPObjRef TP reference to the persistent representation stored in the storage vector of the top-level persistent object Here toPersistentWithKey_impl is invoked with the dynamic cast of the transient type pointer to it's actual type

Reimplemented from TPAbstractPolyCnvBase< TRANS, TRANS, PERS >.

Definition at line 752 of file TPConverter.h.

  {
     return this->toPersistentWithKey_impl( trans, key, log);
  }

wasUsedForReading()

template<class TRANS>

bool ITPConverterFor< TRANS >::wasUsedForReading ( )

inlineinherited

Definition at line 236 of file TPConverter.h.

{ return m_wasUsedForReading; }

Member Data Documentation

m_curRecLevel

int TPAbstractPolyCnvBase< TRANS, TRANS, PERS >::m_curRecLevel

protectedinherited

count recursive invocations, to detect recursion

Definition at line 582 of file TPConverter.h.

m_ignoreRecursion

bool TPAbstractPolyCnvBase< TRANS, TRANS, PERS >::m_ignoreRecursion

protectedinherited

if true, do not throw errors in case of recursion.

Definition at line 588 of file TPConverter.h.

m_pStorage

std::vector< PERS >* TPAbstractPolyCnvBase< TRANS, TRANS, PERS >::m_pStorage

protectedinherited

the address of the storage vector for persistent representations

Definition at line 579 of file TPConverter.h.

m_pStorageTID

template<class TRANS>

TPObjRef::typeID_t ITPConverterFor< TRANS >::m_pStorageTID

protectedinherited

TP Ref typeID for the persistent objects this converter is creating.

Definition at line 292 of file TPConverter.h.

m_pStorageTIDvalue

template<class TRANS>

unsigned ITPConverterFor< TRANS >::m_pStorageTIDvalue

protectedinherited

m_pStorageTID converted to integer value

Definition at line 295 of file TPConverter.h.

m_recursive

bool TPAbstractPolyCnvBase< TRANS, TRANS, PERS >::m_recursive

protectedinherited

if true, work in recursion-safe way (slower)

Definition at line 585 of file TPConverter.h.

m_topConverter

template<class TRANS>

TopLevelTPCnvBase* ITPConverterFor< TRANS >::m_topConverter

protectedinherited

top level converter that owns this elemental TP converter it also holds the storage object

Definition at line 299 of file TPConverter.h.

m_topConverterRuntime

template<class TRANS>

TopLevelTPCnvBase* ITPConverterFor< TRANS >::m_topConverterRuntime

protectedinherited

top level converter "owning" this TP converter at runtime (different from m_topConverter in case the top-level converter and object have extensions)

Definition at line 302 of file TPConverter.h.

m_wasUsedForReading

template<class TRANS>

bool ITPConverterFor< TRANS >::m_wasUsedForReading

protectedinherited

flag set when using this converter for reading triggers search for a new converter before writing, to prevent possible use of old version

Definition at line 306 of file TPConverter.h.

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The documentation for this class was generated from the following files:

• LArOFCSubsetCnv_p1.h
• LArOFCSubsetCnv_p1.cxx