TileRawChannelMonitorAlgorithm Class Reference

Class for Tile raw channel based monitoring. More...

#include <TileRawChannelMonitorAlgorithm.h>

Inheritance diagram for TileRawChannelMonitorAlgorithm:

Collaboration diagram for TileRawChannelMonitorAlgorithm:

Public Types
enum	Environment_t {   Environment_t::user = 0, Environment_t::online, Environment_t::tier0, Environment_t::tier0Raw,   Environment_t::tier0ESD, Environment_t::AOD, Environment_t::altprod }
	Specifies the processing environment. More...
enum	DataType_t {   DataType_t::userDefined = 0, DataType_t::monteCarlo, DataType_t::collisions, DataType_t::cosmics,   DataType_t::heavyIonCollisions }
	Specifies what type of input data is being monitored. More...

Public Member Functions
virtual	~TileRawChannelMonitorAlgorithm ()=default
virtual StatusCode	initialize () override
	initialize More...
virtual StatusCode	fillHistograms (const EventContext &ctx) const override
	adds event to the monitoring histograms More...
	TileCalibMonitorAlgorithm (const std::string &name, ISvcLocator *svcLocator)
	AthMonitorAlgorithm (const std::string &name, ISvcLocator *pSvcLocator)
	Constructor. More...
virtual StatusCode	execute (const EventContext &ctx) const override
	Applies filters and trigger requirements. More...
void	fill (const ToolHandle< GenericMonitoringTool > &groupHandle, std::vector< std::reference_wrapper< Monitored::IMonitoredVariable >> &&variables) const
	Fills a vector of variables to a group by reference. More...
void	fill (const ToolHandle< GenericMonitoringTool > &groupHandle, const std::vector< std::reference_wrapper< Monitored::IMonitoredVariable >> &variables) const
	Fills a vector of variables to a group by reference. More...
template<typename... T>
void	fill (const ToolHandle< GenericMonitoringTool > &groupHandle, T &&... variables) const
	Fills a variadic list of variables to a group by reference. More...
void	fill (const std::string &groupName, std::vector< std::reference_wrapper< Monitored::IMonitoredVariable >> &&variables) const
	Fills a vector of variables to a group by name. More...
void	fill (const std::string &groupName, const std::vector< std::reference_wrapper< Monitored::IMonitoredVariable >> &variables) const
	Fills a vector of variables to a group by name. More...
template<typename... T>
void	fill (const std::string &groupName, T &&... variables) const
	Fills a variadic list of variables to a group by name. More...
Environment_t	environment () const
	Accessor functions for the environment. More...
Environment_t	envStringToEnum (const std::string &str) const
	Convert the environment string from the python configuration to an enum object. More...
DataType_t	dataType () const
	Accessor functions for the data type. More...
DataType_t	dataTypeStringToEnum (const std::string &str) const
	Convert the data type string from the python configuration to an enum object. More...
const ToolHandle< GenericMonitoringTool > &	getGroup (const std::string &name) const
	Get a specific monitoring tool from the tool handle array. More...
const ToolHandle< Trig::TrigDecisionTool > &	getTrigDecisionTool () const
	Get the trigger decision tool member. More...
bool	trigChainsArePassed (const std::vector< std::string > &vTrigNames) const
	Check whether triggers are passed. More...
SG::ReadHandle< xAOD::EventInfo >	GetEventInfo (const EventContext &) const
	Return a ReadHandle for an EventInfo object (get run/event numbers, etc.) More...
virtual float	lbAverageInteractionsPerCrossing (const EventContext &ctx=Gaudi::Hive::currentContext()) const
	Calculate the average mu, i.e. More...
virtual float	lbInteractionsPerCrossing (const EventContext &ctx=Gaudi::Hive::currentContext()) const
	Calculate instantaneous number of interactions, i.e. More...
virtual float	lbAverageLuminosity (const EventContext &ctx=Gaudi::Hive::currentContext()) const
	Calculate average luminosity (in ub-1 s-1 => 10^30 cm-2 s-1). More...
virtual float	lbLuminosityPerBCID (const EventContext &ctx=Gaudi::Hive::currentContext()) const
	Calculate the instantaneous luminosity per bunch crossing. More...
virtual double	lbDuration (const EventContext &ctx=Gaudi::Hive::currentContext()) const
	Calculate the duration of the luminosity block (in seconds) More...
virtual float	lbAverageLivefraction (const EventContext &ctx=Gaudi::Hive::currentContext()) const
	Calculate the average luminosity livefraction. More...
virtual float	livefractionPerBCID (const EventContext &ctx=Gaudi::Hive::currentContext()) const
	Calculate the live fraction per bunch crossing ID. More...
virtual double	lbLumiWeight (const EventContext &ctx=Gaudi::Hive::currentContext()) const
	Calculate the average integrated luminosity multiplied by the live fraction. More...
virtual StatusCode	parseList (const std::string &line, std::vector< std::string > &result) const
	Parse a string into a vector. More...
virtual StatusCode	sysInitialize () override
	Override sysInitialize. More...
virtual bool	isClonable () const override
	Specify if the algorithm is clonable. More...
virtual unsigned int	cardinality () const override
	Cardinality (Maximum number of clones that can exist) special value 0 means that algorithm is reentrant. More...
virtual StatusCode	sysExecute (const EventContext &ctx) override
	Execute an algorithm. More...
virtual const DataObjIDColl &	extraOutputDeps () const override
	Return the list of extra output dependencies. More...
virtual bool	filterPassed (const EventContext &ctx) const
virtual void	setFilterPassed (bool state, const EventContext &ctx) const
ServiceHandle< StoreGateSvc > &	evtStore ()
	The standard StoreGateSvc (event store) Returns (kind of) a pointer to the StoreGateSvc. More...
const ServiceHandle< StoreGateSvc > &	evtStore () const
	The standard StoreGateSvc (event store) Returns (kind of) a pointer to the StoreGateSvc. More...
const ServiceHandle< StoreGateSvc > &	detStore () const
	The standard StoreGateSvc/DetectorStore Returns (kind of) a pointer to the StoreGateSvc. More...
virtual StatusCode	sysStart () override
	Handle START transition. More...
virtual std::vector< Gaudi::DataHandle * >	inputHandles () const override
	Return this algorithm's input handles. More...
virtual std::vector< Gaudi::DataHandle * >	outputHandles () const override
	Return this algorithm's output handles. More...
Gaudi::Details::PropertyBase &	declareProperty (Gaudi::Property< T, V, H > &t)
Gaudi::Details::PropertyBase *	declareProperty (const std::string &name, SG::VarHandleKey &hndl, const std::string &doc, const SG::VarHandleKeyType &)
	Declare a new Gaudi property. More...
Gaudi::Details::PropertyBase *	declareProperty (const std::string &name, SG::VarHandleBase &hndl, const std::string &doc, const SG::VarHandleType &)
	Declare a new Gaudi property. More...
Gaudi::Details::PropertyBase *	declareProperty (const std::string &name, SG::VarHandleKeyArray &hndArr, const std::string &doc, const SG::VarHandleKeyArrayType &)
Gaudi::Details::PropertyBase *	declareProperty (const std::string &name, T &property, const std::string &doc, const SG::NotHandleType &)
	Declare a new Gaudi property. More...
Gaudi::Details::PropertyBase *	declareProperty (const std::string &name, T &property, const std::string &doc="none")
	Declare a new Gaudi property. More...
void	updateVHKA (Gaudi::Details::PropertyBase &)
MsgStream &	msg () const
MsgStream &	msg (const MSG::Level lvl) const
bool	msgLvl (const MSG::Level lvl) const

Public Attributes
	flags
	Files
	HISTFileName
	useTrigger
	enableLumiAccess
	MaxEvents
	cfg
	readMuRcv
	False
	readBeamElem
	TileRawChannelContainer
	fillHistogramsForDSP
	sc

Protected Types
enum	RunType {   UNKNOWN_RUN = 0, PHYS_RUN = 1, LAS_RUN = 2, LED_RUN = 3,   PED_RUN = 4, CIS_RUN = 8, MONO_RUN = 9, CIS_RAMP_RUN = 10 }
	Describes Tile Run Type. More...

Protected Member Functions
bool	isHeaderFormatError (uint32_t header) const
bool	isHeaderParityError (uint32_t header) const
void	renounceArray (SG::VarHandleKeyArray &handlesArray)
	remove all handles from I/O resolution More...
std::enable_if_t< std::is_void_v< std::result_of_t< decltype(&T::renounce)(T)> > &&!std::is_base_of_v< SG::VarHandleKeyArray, T > &&std::is_base_of_v< Gaudi::DataHandle, T >, void >	renounce (T &h)
void	extraDeps_update_handler (Gaudi::Details::PropertyBase &ExtraDeps)
	Add StoreName to extra input/output deps as needed. More...

Protected Attributes
Gaudi::Property< std::string >	m_tileInfoName
Gaudi::Property< std::vector< int > >	m_fragIDsToIgnoreDMUerrors
Gaudi::Property< std::vector< int > >	m_fragIDsDemonstrators
Gaudi::Property< int >	m_runType
SG::ReadHandleKey< TileDQstatus >	m_dqStatusKey
ServiceHandle< TileCablingSvc >	m_cablingSvc
	Name of Tile cabling service. More...
const TileCablingService *	m_cabling {nullptr}
const TileHWID *	m_tileHWID {nullptr}
const TileInfo *	m_tileInfo {nullptr}
ToolHandleArray< GenericMonitoringTool >	m_tools {this,"GMTools",{}}
	Array of Generic Monitoring Tools. More...
PublicToolHandle< Trig::TrigDecisionTool >	m_trigDecTool {this, "TrigDecisionTool",""}
	Tool to tell whether a specific trigger is passed. More...
ToolHandleArray< IDQFilterTool >	m_DQFilterTools {this,"FilterTools",{}}
	Array of Data Quality filter tools. More...
SG::ReadCondHandleKey< LuminosityCondData >	m_lumiDataKey {this,"LuminosityCondDataKey","LuminosityCondData","SG Key of LuminosityCondData object"}
SG::ReadCondHandleKey< LBDurationCondData >	m_lbDurationDataKey {this,"LBDurationCondDataKey","LBDurationCondData","SG Key of LBDurationCondData object"}
SG::ReadCondHandleKey< TrigLiveFractionCondData >	m_trigLiveFractionDataKey {this,"TrigLiveFractionCondDataKey","TrigLiveFractionCondData", "SG Key of TrigLiveFractionCondData object"}
AthMonitorAlgorithm::Environment_t	m_environment
	Instance of the Environment_t enum. More...
AthMonitorAlgorithm::DataType_t	m_dataType
	Instance of the DataType_t enum. More...
Gaudi::Property< std::string >	m_environmentStr {this,"Environment","user"}
	Environment string pulled from the job option and converted to enum. More...
Gaudi::Property< std::string >	m_dataTypeStr {this,"DataType","userDefined"}
	DataType string pulled from the job option and converted to enum. More...
Gaudi::Property< std::string >	m_triggerChainString {this,"TriggerChain",""}
	Trigger chain string pulled from the job option and parsed into a vector. More...
std::vector< std::string >	m_vTrigChainNames
	Vector of trigger chain names parsed from trigger chain string. More...
Gaudi::Property< std::string >	m_fileKey {this,"FileKey",""}
	Internal Athena name for file. More...
Gaudi::Property< bool >	m_useLumi {this,"EnableLumi",false}
	Allows use of various luminosity functions. More...
Gaudi::Property< float >	m_defaultLBDuration {this,"DefaultLBDuration",60.}
	Default duration of one lumi block. More...
Gaudi::Property< int >	m_detailLevel {this,"DetailLevel",0}
	Sets the level of detail used in the monitoring. More...
SG::ReadHandleKey< xAOD::EventInfo >	m_EventInfoKey {this,"EventInfoKey","EventInfo"}
	Key for retrieving EventInfo from StoreGate. More...

Private Types
typedef std::vector< std::reference_wrapper< Monitored::IMonitoredVariable > >	MonVarVec_t
typedef ServiceHandle< StoreGateSvc >	StoreGateSvc_t

Private Member Functions
bool	isDmuHeaderError (uint32_t header) const
Gaudi::Details::PropertyBase &	declareGaudiProperty (Gaudi::Property< T, V, H > &hndl, const SG::VarHandleKeyType &)
	specialization for handling Gaudi::Property<SG::VarHandleKey> More...
Gaudi::Details::PropertyBase &	declareGaudiProperty (Gaudi::Property< T, V, H > &hndl, const SG::VarHandleKeyArrayType &)
	specialization for handling Gaudi::Property<SG::VarHandleKeyArray> More...
Gaudi::Details::PropertyBase &	declareGaudiProperty (Gaudi::Property< T, V, H > &hndl, const SG::VarHandleType &)
	specialization for handling Gaudi::Property<SG::VarHandleBase> More...
Gaudi::Details::PropertyBase &	declareGaudiProperty (Gaudi::Property< T, V, H > &t, const SG::NotHandleType &)
	specialization for handling everything that's not a Gaudi::Property<SG::VarHandleKey> or a <SG::VarHandleKeyArray> More...

Private Attributes
Gaudi::Property< float >	m_minAmpForCorrectedTime
Gaudi::Property< float >	m_minOfflineAmp
Gaudi::Property< int >	m_calibUnit
Gaudi::Property< bool >	m_fillHistogramsForDSP
Gaudi::Property< bool >	m_fill2DHistograms
SG::ReadHandleKey< TileDigitsContainer >	m_digitsContainerKey
SG::ReadHandleKey< TileRawChannelContainer >	m_rawChannelContainerKey
SG::ReadHandleKey< TileRawChannelContainer >	m_dspRawChannelContainerKey
SG::ReadCondHandleKey< TileEMScale >	m_emScaleKey
	Name of TileEMScale in condition store. More...
std::vector< std::vector< int > >	m_ampGroups
std::vector< std::vector< int > >	m_timeGroups
std::vector< std::vector< int > >	m_timeCorrGroups
std::vector< std::vector< int > >	m_ampOverQ5Groups
std::vector< std::vector< int > >	m_ampVsQ5Groups
std::vector< std::vector< int > >	m_time5Groups
std::vector< std::vector< int > >	m_timeVsTime5Groups
std::vector< std::vector< int > >	m_ampOverQ100Groups
std::vector< std::vector< int > >	m_ampVsQ100Groups
std::vector< std::vector< int > >	m_time100Groups
std::vector< std::vector< int > >	m_timeVsTime100Groups
std::vector< std::vector< int > >	m_dspAmpGroups
std::vector< std::vector< int > >	m_dspTimeGroups
std::vector< std::vector< int > >	m_dspChi2Groups
std::vector< std::vector< int > >	m_dspChi2VsAmpGroups
std::vector< std::vector< int > >	m_ampDiffGroups
std::vector< std::vector< int > >	m_timeDiffGroups
TileRawChannelUnit::UNIT	m_finalRawChannelUnit {TileRawChannelUnit::Invalid}
double	m_dac2Charge [2] = {}
bool	m_runTypeIsNotCIS {true}
std::string	m_name
std::unordered_map< std::string, size_t >	m_toolLookupMap
const ToolHandle< GenericMonitoringTool >	m_dummy
Gaudi::Property< bool >	m_enforceExpressTriggers
DataObjIDColl	m_extendedExtraObjects
	Extra output dependency collection, extended by AthAlgorithmDHUpdate to add symlinks. More...
StoreGateSvc_t	m_evtStore
	Pointer to StoreGate (event store by default) More...
StoreGateSvc_t	m_detStore
	Pointer to StoreGate (detector store by default) More...
std::vector< SG::VarHandleKeyArray * >	m_vhka
bool	m_varHandleArraysDeclared

Static Private Attributes
static const int	MAX_DMU {16}

Detailed Description

Class for Tile raw channel based monitoring.

Definition at line 22 of file TileRawChannelMonitorAlgorithm.h.

Member Typedef Documentation

MonVarVec_t

typedef std::vector<std::reference_wrapper<Monitored::IMonitoredVariable> > AthMonitorAlgorithm::MonVarVec_t

privateinherited

Definition at line 365 of file AthMonitorAlgorithm.h.

StoreGateSvc_t

typedef ServiceHandle<StoreGateSvc> AthCommonDataStore< AthCommonMsg< Gaudi::Algorithm > >::StoreGateSvc_t

privateinherited

Definition at line 388 of file AthCommonDataStore.h.

Member Enumeration Documentation

DataType_t

enum AthMonitorAlgorithm::DataType_t

stronginherited

Specifies what type of input data is being monitored.

An enumeration of the different types of data the monitoring application may be running over. This can be used to select which histograms to produce, e.g. to prevent the production of colliding-beam histograms when running on cosmic-ray data. Strings of the same names may be given as jobOptions.

Enumerator
userDefined
monteCarlo
collisions
cosmics
heavyIonCollisions

Definition at line 191 of file AthMonitorAlgorithm.h.

                          {
        userDefined = 0, 
        monteCarlo, 
        collisions, 
        cosmics, 
        heavyIonCollisions, 
    };

Environment_t

enum AthMonitorAlgorithm::Environment_t

stronginherited

Specifies the processing environment.

The running environment may be used to select which histograms are produced, and where they are located in the output. For example, the output paths of the histograms are different for the "user", "online" and the various offline flags. Strings of the same names may be given as jobOptions.

Enumerator
user
online
tier0
tier0Raw
tier0ESD
AOD
altprod

Definition at line 172 of file AthMonitorAlgorithm.h.

                             {
        user = 0, 
        online, 
        tier0, 
        tier0Raw, 
        tier0ESD, 
        AOD, 
        altprod, 
    };

RunType

enum TileCalibMonitorAlgorithm::RunType

protectedinherited

Describes Tile Run Type.

Enumerator
UNKNOWN_RUN
PHYS_RUN
LAS_RUN
LED_RUN
PED_RUN
CIS_RUN
MONO_RUN
CIS_RAMP_RUN

Definition at line 64 of file TileCalibMonitorAlgorithm.h.

                 {
       UNKNOWN_RUN  = 0, // expect monogain
       PHYS_RUN = 1, // expect monogain
       LAS_RUN  = 2, // expect monogain
       LED_RUN  = 3, // expect monogain
       PED_RUN  = 4, // expect bigain
       CIS_RUN  = 8, // expect bigain
       MONO_RUN = 9, // expect monogain
       CIS_RAMP_RUN = 10 // expect monogain
    };

Constructor & Destructor Documentation

~TileRawChannelMonitorAlgorithm()

virtual TileRawChannelMonitorAlgorithm::~TileRawChannelMonitorAlgorithm ( )

virtualdefault

Member Function Documentation

AthMonitorAlgorithm()

AthMonitorAlgorithm::AthMonitorAlgorithm

inherited

Constructor.

Definition at line 42 of file AthMonitorAlgorithm.cxx.

:AthReentrantAlgorithm(name,pSvcLocator)
,m_environment(Environment_t::user)
,m_dataType(DataType_t::userDefined)
,m_vTrigChainNames({})
{}

cardinality()

unsigned int AthCommonReentrantAlgorithm< Gaudi::Algorithm >::cardinality

overridevirtualinherited

Cardinality (Maximum number of clones that can exist) special value 0 means that algorithm is reentrant.

Override this to return 0 for reentrant algorithms.

Override this to return 0 for reentrant algorithms.

Definition at line 75 of file AthCommonReentrantAlgorithm.cxx.

{
  return 0;
}

dataType()

DataType_t AthMonitorAlgorithm::dataType ( ) const

inlineinherited

Accessor functions for the data type.

Returns

the current value of the class's DataType_t instance.

Definition at line 221 of file AthMonitorAlgorithm.h.

{ return m_dataType; }

dataTypeStringToEnum()

AthMonitorAlgorithm::DataType_t AthMonitorAlgorithm::dataTypeStringToEnum ( const std::string &  str ) const

inherited

Convert the data type string from the python configuration to an enum object.

Returns

a value in the DataType_t enumeration which matches the input string.

Definition at line 140 of file AthMonitorAlgorithm.cxx.

                                                                                                    {
    // convert the string to all lowercase
    std::string lowerCaseStr = str;
    std::transform(lowerCaseStr.begin(), lowerCaseStr.end(), lowerCaseStr.begin(), ::tolower);
 
    // check if it matches one of the enum choices
    if( lowerCaseStr == "userdefined" ) {
        return DataType_t::userDefined;
    } else if( lowerCaseStr == "montecarlo" ) {
        return DataType_t::monteCarlo;
    } else if( lowerCaseStr == "collisions" ) {
        return DataType_t::collisions;
    } else if( lowerCaseStr == "cosmics" ) {
        return DataType_t::cosmics;
    } else if( lowerCaseStr == "heavyioncollisions" ) {
        return DataType_t::heavyIonCollisions;
    } else { // otherwise, warn the user and return "userDefined"
        ATH_MSG_WARNING("AthMonitorAlgorithm::dataTypeStringToEnum(): Unknown data type "
            <<str<<", returning userDefined.");
        return DataType_t::userDefined;
    }
}

declareGaudiProperty() [1/4]

Gaudi::Details::PropertyBase& AthCommonDataStore< AthCommonMsg< Gaudi::Algorithm > >::declareGaudiProperty ( Gaudi::Property< T, V, H > &  hndl, const SG::VarHandleKeyArrayType &    )

inlineprivateinherited

specialization for handling Gaudi::Property<SG::VarHandleKeyArray>

Definition at line 170 of file AthCommonDataStore.h.

  {
    return *AthCommonDataStore<PBASE>::declareProperty(hndl.name(),
                                                       hndl.value(), 
                                                       hndl.documentation());
 
  }

declareGaudiProperty() [2/4]

Gaudi::Details::PropertyBase& AthCommonDataStore< AthCommonMsg< Gaudi::Algorithm > >::declareGaudiProperty ( Gaudi::Property< T, V, H > &  hndl, const SG::VarHandleKeyType &    )

inlineprivateinherited

specialization for handling Gaudi::Property<SG::VarHandleKey>

Definition at line 156 of file AthCommonDataStore.h.

  {
    return *AthCommonDataStore<PBASE>::declareProperty(hndl.name(),
                                                       hndl.value(), 
                                                       hndl.documentation());
 
  }

declareGaudiProperty() [3/4]

Gaudi::Details::PropertyBase& AthCommonDataStore< AthCommonMsg< Gaudi::Algorithm > >::declareGaudiProperty ( Gaudi::Property< T, V, H > &  hndl, const SG::VarHandleType &    )

inlineprivateinherited

specialization for handling Gaudi::Property<SG::VarHandleBase>

Definition at line 184 of file AthCommonDataStore.h.

  {
    return *AthCommonDataStore<PBASE>::declareProperty(hndl.name(),
                                                       hndl.value(), 
                                                       hndl.documentation());
  }

declareGaudiProperty() [4/4]

Gaudi::Details::PropertyBase& AthCommonDataStore< AthCommonMsg< Gaudi::Algorithm > >::declareGaudiProperty ( Gaudi::Property< T, V, H > &  t, const SG::NotHandleType &    )

inlineprivateinherited

specialization for handling everything that's not a Gaudi::Property<SG::VarHandleKey> or a <SG::VarHandleKeyArray>

Definition at line 199 of file AthCommonDataStore.h.

  {
    return PBASE::declareProperty(t);
  }

declareProperty() [1/6]

Gaudi::Details::PropertyBase* AthCommonDataStore< AthCommonMsg< Gaudi::Algorithm > >::declareProperty ( const std::string &  name, SG::VarHandleBase &  hndl, const std::string &  doc, const SG::VarHandleType &    )

inlineinherited

Declare a new Gaudi property.

Parameters

name	Name of the property.
hndl	Object holding the property value.
doc	Documentation string for the property.

This is the version for types that derive from SG::VarHandleBase. The property value object is put on the input and output lists as appropriate; then we forward to the base class.

Definition at line 245 of file AthCommonDataStore.h.

  {
    this->declare(hndl.vhKey());
    hndl.vhKey().setOwner(this);
 
    return PBASE::declareProperty(name,hndl,doc);
  }

declareProperty() [2/6]

Gaudi::Details::PropertyBase* AthCommonDataStore< AthCommonMsg< Gaudi::Algorithm > >::declareProperty ( const std::string &  name, SG::VarHandleKey &  hndl, const std::string &  doc, const SG::VarHandleKeyType &    )

inlineinherited

Declare a new Gaudi property.

Parameters

name	Name of the property.
hndl	Object holding the property value.
doc	Documentation string for the property.

This is the version for types that derive from SG::VarHandleKey. The property value object is put on the input and output lists as appropriate; then we forward to the base class.

Definition at line 221 of file AthCommonDataStore.h.

  {
    this->declare(hndl);
    hndl.setOwner(this);
 
    return PBASE::declareProperty(name,hndl,doc);
  }

declareProperty() [3/6]

Gaudi::Details::PropertyBase* AthCommonDataStore< AthCommonMsg< Gaudi::Algorithm > >::declareProperty ( const std::string &  name, SG::VarHandleKeyArray &  hndArr, const std::string &  doc, const SG::VarHandleKeyArrayType &    )

inlineinherited

Definition at line 259 of file AthCommonDataStore.h.

  {
 
    // std::ostringstream ost;
    // ost << Algorithm::name() << " VHKA declareProp: " << name 
    //     << " size: " << hndArr.keys().size() 
    //     << " mode: " << hndArr.mode() 
    //     << "  vhka size: " << m_vhka.size()
    //     << "\n";
    // debug() << ost.str() << endmsg;
 
    hndArr.setOwner(this);
    m_vhka.push_back(&hndArr);
 
    Gaudi::Details::PropertyBase* p =  PBASE::declareProperty(name, hndArr, doc);
    if (p != 0) {
      p->declareUpdateHandler(&AthCommonDataStore<PBASE>::updateVHKA, this);
    } else {
      ATH_MSG_ERROR("unable to call declareProperty on VarHandleKeyArray " 
                    << name);
    }
 
    return p;
 
  }

declareProperty() [4/6]

Gaudi::Details::PropertyBase* AthCommonDataStore< AthCommonMsg< Gaudi::Algorithm > >::declareProperty ( const std::string &  name, T &  property, const std::string &  doc, const SG::NotHandleType &    )

inlineinherited

Declare a new Gaudi property.

Parameters

name	Name of the property.
property	Object holding the property value.
doc	Documentation string for the property.

This is the generic version, for types that do not derive from SG::VarHandleKey. It just forwards to the base class version of declareProperty.

Definition at line 333 of file AthCommonDataStore.h.

  {
    return PBASE::declareProperty(name, property, doc);
  }

declareProperty() [5/6]

Gaudi::Details::PropertyBase* AthCommonDataStore< AthCommonMsg< Gaudi::Algorithm > >::declareProperty ( const std::string &  name, T &  property, const std::string &  doc = "none"  )

inlineinherited

Declare a new Gaudi property.

Parameters

name	Name of the property.
property	Object holding the property value.
doc	Documentation string for the property.

This dispatches to either the generic declareProperty or the one for VarHandle/Key/KeyArray.

Definition at line 352 of file AthCommonDataStore.h.

  {
    typedef typename SG::HandleClassifier<T>::type htype;
    return declareProperty (name, property, doc, htype());
  }

declareProperty() [6/6]

Gaudi::Details::PropertyBase& AthCommonDataStore< AthCommonMsg< Gaudi::Algorithm > >::declareProperty ( Gaudi::Property< T, V, H > &  t )

inlineinherited

Definition at line 145 of file AthCommonDataStore.h.

                                                                     {
    typedef typename SG::HandleClassifier<T>::type htype;
    return AthCommonDataStore<PBASE>::declareGaudiProperty(t, htype());
  }

detStore()

const ServiceHandle<StoreGateSvc>& AthCommonDataStore< AthCommonMsg< Gaudi::Algorithm > >::detStore ( ) const

inlineinherited

The standard StoreGateSvc/DetectorStore Returns (kind of) a pointer to the StoreGateSvc.

Definition at line 95 of file AthCommonDataStore.h.

{ return m_detStore; }

environment()

Environment_t AthMonitorAlgorithm::environment ( ) const

inlineinherited

Accessor functions for the environment.

Returns

the current value of the class's Environment_t instance.

Definition at line 205 of file AthMonitorAlgorithm.h.

{ return m_environment; }

envStringToEnum()

AthMonitorAlgorithm::Environment_t AthMonitorAlgorithm::envStringToEnum ( const std::string &  str ) const

inherited

Convert the environment string from the python configuration to an enum object.

Returns

a value in the Environment_t enumeration which matches the input string.

Definition at line 112 of file AthMonitorAlgorithm.cxx.

                                                                                                  {
    // convert the string to all lowercase
    std::string lowerCaseStr = str;
    std::transform(lowerCaseStr.begin(), lowerCaseStr.end(), lowerCaseStr.begin(), ::tolower);
 
    // check if it matches one of the enum choices
    if( lowerCaseStr == "user" ) {
        return Environment_t::user;
    } else if( lowerCaseStr == "online" ) {
        return Environment_t::online;
    } else if( lowerCaseStr == "tier0" ) {
        return Environment_t::tier0;
    } else if( lowerCaseStr == "tier0raw" ) {
        return Environment_t::tier0Raw;
    } else if( lowerCaseStr == "tier0esd" ) {
        return Environment_t::tier0ESD;
    } else if( lowerCaseStr == "aod" ) {
        return Environment_t::AOD;
    } else if( lowerCaseStr == "altprod" ) {
        return Environment_t::altprod;
    } else { // otherwise, warn the user and return "user"
        ATH_MSG_WARNING("AthMonitorAlgorithm::envStringToEnum(): Unknown environment "
            <<str<<", returning user.");
        return Environment_t::user;
    }
}

evtStore() [1/2]

ServiceHandle<StoreGateSvc>& AthCommonDataStore< AthCommonMsg< Gaudi::Algorithm > >::evtStore ( )

inlineinherited

The standard StoreGateSvc (event store) Returns (kind of) a pointer to the StoreGateSvc.

Definition at line 85 of file AthCommonDataStore.h.

{ return m_evtStore; }

evtStore() [2/2]

const ServiceHandle<StoreGateSvc>& AthCommonDataStore< AthCommonMsg< Gaudi::Algorithm > >::evtStore ( ) const

inlineinherited

The standard StoreGateSvc (event store) Returns (kind of) a pointer to the StoreGateSvc.

Definition at line 90 of file AthCommonDataStore.h.

{ return m_evtStore; }

execute()

StatusCode AthMonitorAlgorithm::execute ( const EventContext &  ctx ) const

overridevirtualinherited

Applies filters and trigger requirements.

Then, calls fillHistograms().

Parameters

ctx	event context for reentrant Athena call

Returns

StatusCode

Definition at line 73 of file AthMonitorAlgorithm.cxx.

                                                                       {
 
    // Checks that all of the  DQ filters are passed. If any one of the filters
    // fails, return SUCCESS code and do not fill the histograms with the event.
    for ( const auto& filterItr : m_DQFilterTools ) {
        if (!filterItr->accept()) {
            ATH_MSG_DEBUG("Event rejected due to filter tool.");
            return StatusCode::SUCCESS;
        }
    }
 
    // Trigger: If there is a decision tool and the chains fail, skip the event.
    if ( !m_trigDecTool.empty() && !trigChainsArePassed(m_vTrigChainNames) ) {
        ATH_MSG_DEBUG("Event rejected due to trigger filter.");
        return StatusCode::SUCCESS;
    }
 
    ATH_MSG_DEBUG("Event accepted!");
    return fillHistograms(ctx);
}

extraDeps_update_handler()

void AthCommonDataStore< AthCommonMsg< Gaudi::Algorithm > >::extraDeps_update_handler ( Gaudi::Details::PropertyBase &  ExtraDeps )

protectedinherited

Add StoreName to extra input/output deps as needed.

use the logic of the VarHandleKey to parse the DataObjID keys supplied via the ExtraInputs and ExtraOuputs Properties to add the StoreName if it's not explicitly given

extraOutputDeps()

const DataObjIDColl & AthCommonReentrantAlgorithm< Gaudi::Algorithm >::extraOutputDeps

overridevirtualinherited

Return the list of extra output dependencies.

This list is extended to include symlinks implied by inheritance relations.

Definition at line 94 of file AthCommonReentrantAlgorithm.cxx.

{
  // If we didn't find any symlinks to add, just return the collection
  // from the base class.  Otherwise, return the extended collection.
  if (!m_extendedExtraObjects.empty()) {
    return m_extendedExtraObjects;
  }
  return BaseAlg::extraOutputDeps();
}

fillHistograms()

StatusCode TileRawChannelMonitorAlgorithm::fillHistograms ( const EventContext &  ctx ) const

overridevirtual

adds event to the monitoring histograms

User will overwrite this function. Histogram booking is no longer done in C++. This function is called in execute once the filters are all passed.

Parameters

ctx	forwarded from execute

Returns

StatusCode

Implements TileCalibMonitorAlgorithm.

Definition at line 111 of file TileRawChannelMonitorAlgorithm.cxx.

                                                                                         {
 
  using Tile = TileCalibUtils;
 
  // In case you want to measure the execution time
  auto timer = Monitored::Timer("TIME_execute");
 
  if (ctx.evt() % 1000 == 0) {
    ATH_MSG_ALWAYS(ctx.evt() << " events processed so far");
  }
 
  SG::ReadCondHandle<TileEMScale> emScale(m_emScaleKey, ctx);
  ATH_CHECK( emScale.isValid() );
 
  SG::ReadHandle<TileDQstatus> dqStatusHandle(m_dqStatusKey, ctx);
  ATH_CHECK( dqStatusHandle.isValid() );
  const TileDQstatus* dqStatus = dqStatusHandle.get();
 
  // array of CIS parameters
  const uint32_t* cispar = dqStatus->cispar();
 
  if (cispar[8] != 0) return StatusCode::SUCCESS;
 
  int cap = (cispar[7] > 10) ? 0 : 1; // 100 pF or 5 pF
  double injectionTime = cispar[5] * 0.104;
  double chargeForNormalModule = (cispar[6] < 1024) ? cispar[6] * m_dac2Charge[cap] : 0.;
  // Effective value of small capacitor is twice smaller for demonstrator
  double chargeForDemonstrator = cap ? chargeForNormalModule * 0.5 : chargeForNormalModule;
  double invChargeForNormalModule = (chargeForNormalModule != 0) ? 1.0 / chargeForNormalModule : 0.;
  double invChargeForDemonstrator = (chargeForDemonstrator != 0) ? 1.0 / chargeForDemonstrator : 0.;
 
  // Ignore charges below 1 pC in HG
  // Ignore charges below 10 pC for small capacitor and below 15 pC for big capacitor in LG
  std::array<double, 2> minChargeForNormalModule = {(cap ? 10. : 15.), 1.};
  std::array<double, 2> minChargeForDemonstrator = {(cap ? 10. : 15.), 2.};
 
  // Ignore charges above 11.5 pC in HG (full range is 12.5 pC)
  // Ignore charges above 750. pC in LG (full range is 800. pC)
  std::array<double, 2> maxChargeForNormalModule = {750., 11.5};
  std::array<double, 2> maxChargeForDemonstrator = {750., 23.0};
 
  const std::vector<std::vector<int>>& ampOverQCapGroups = cap ? m_ampOverQ5Groups : m_ampOverQ100Groups;
  const std::vector<std::vector<int>>& ampVsQCapGroups = cap ? m_ampVsQ5Groups : m_ampVsQ100Groups;
  const std::vector<std::vector<int>>& timeCapGroups = cap ? m_time5Groups : m_time100Groups;
  const std::vector<std::vector<int>>& timeVsTimeCapGroups = cap ? m_timeVsTime5Groups : m_timeVsTime100Groups;
 
  bool corruptedData[Tile::MAX_ROS - 1][Tile::MAX_DRAWER][Tile::MAX_GAIN][MAX_DMU]={{{{false}}}};
 
  SG::ReadHandle<TileDigitsContainer> digitsContainer(m_digitsContainerKey, ctx);
  ATH_CHECK( digitsContainer.isValid() );
 
  for (const TileDigitsCollection* digitsCollection : *digitsContainer) {
    if (digitsCollection->empty() ) continue;
 
    HWIdentifier adc_id = digitsCollection->front()->adc_HWID();
    int ros = m_tileHWID->ros(adc_id);
    int drawer = m_tileHWID->drawer(adc_id);
    int partition = ros - 1;
 
    std::vector<uint32_t> headers = digitsCollection->getFragChipHeaderWords();
    int nDMU = headers.size();
    if (nDMU > MAX_DMU) nDMU = MAX_DMU;
 
    int fragId = digitsCollection->identify();
    if (!std::binary_search(m_fragIDsToIgnoreDMUerrors.begin(), m_fragIDsToIgnoreDMUerrors.end(), fragId)) {
      for (int dmu = 0; dmu < nDMU; ++dmu) {
        bool isDataCorrupted = isDmuHeaderError(headers[dmu]);
        corruptedData[partition][drawer][0][dmu] = isDataCorrupted;
        corruptedData[partition][drawer][1][dmu] = isDataCorrupted;
      }
    }
  }
 
  int nChannels[Tile::MAX_ROS-1] = {0};
  float partitionTimeSum[Tile::MAX_ROS-1] = {0};
 
  float offlineTime[Tile::MAX_ROS-1][Tile::MAX_DRAWER][Tile::MAX_CHAN][Tile::MAX_GAIN] = {{{{0}}}};
  float offlineAmplitude[Tile::MAX_ROS-1][Tile::MAX_DRAWER][Tile::MAX_CHAN][Tile::MAX_GAIN] = {{{{0}}}};
 
 
  SG::ReadHandle<TileRawChannelContainer> rawChannelContainer(m_rawChannelContainerKey, ctx);
  ATH_CHECK( rawChannelContainer.isValid() );
 
  TileRawChannelUnit::UNIT rawChannelUnit = rawChannelContainer->get_unit();
 
  for (const TileRawChannelCollection* rawChannelCollection : *rawChannelContainer) {
    if (rawChannelCollection->empty()) continue;
 
    HWIdentifier adc_id = rawChannelCollection->front()->adc_HWID();
    int ros = m_tileHWID->ros(adc_id);
    int drawer = m_tileHWID->drawer(adc_id);
    unsigned int drawerIdx = TileCalibUtils::getDrawerIdx(ros, drawer);
    int partition = ros - 1;
 
    int fragId = rawChannelCollection->identify();
    bool demonstrator = (std::binary_search(m_fragIDsDemonstrators.begin(), m_fragIDsDemonstrators.end(), fragId));
 
    std::array<double, 2>& minCharge = demonstrator ? minChargeForDemonstrator : minChargeForNormalModule;
    std::array<double, 2>& maxCharge = demonstrator ? maxChargeForDemonstrator : maxChargeForNormalModule;
    double charge = demonstrator ? chargeForDemonstrator : chargeForNormalModule;
    double invCharge = demonstrator ? invChargeForDemonstrator : invChargeForNormalModule;
 
    for (const TileRawChannel* rawChannel : *rawChannelCollection) {
      adc_id = rawChannel->adc_HWID();
      int channel = m_tileHWID->channel(adc_id);
      int adc = m_tileHWID->adc(adc_id);
 
      if (corruptedData[partition][drawer][adc][channel / 3]) continue;
 
      std::string channelGainSuffix = "_" + std::to_string(channel) + "_" + std::to_string(adc);
 
      float amplitude = rawChannel->amplitude();
      if (rawChannelUnit != m_finalRawChannelUnit) {
        // Put everything in PicoCoulomb by default for all run types
        // For Laser and Physcs calibrate in CesiumPicoCoulomb for all channels, but the MBTS channels,
        // for which we keep the calibration in PicoCoulombCesium pC for consistency (no Cs calibration is possible)
        if ((m_finalRawChannelUnit == TileRawChannelUnit::CesiumPicoCoulombs) && (ros > 3)) {
          // if EB then check that they are not MBTS channel
          int index, pmt;
          rawChannel->cell_ID_index(index, pmt);
          if (index < -1) { // MBTS channel
            amplitude = emScale->calibrateChannel(drawerIdx, channel, adc, amplitude, rawChannelUnit, TileRawChannelUnit::PicoCoulombs);
          }
        }
        amplitude = emScale->calibrateChannel(drawerIdx, channel, adc, amplitude, rawChannelUnit, m_finalRawChannelUnit);
      } // no need to calibrate
 
      offlineAmplitude[partition][drawer][channel][adc] = amplitude;
 
      float time = rawChannel->time();
      offlineTime[partition][drawer][channel][adc] = time;
 
      if (m_runTypeIsNotCIS) {
        auto monAmplitude = Monitored::Scalar<float>("amp" + channelGainSuffix, amplitude);
        fill(m_tools[m_ampGroups[partition][drawer]], monAmplitude);
 
        if (time != 0) {
          // Don't fill the time when it is exactly 0, which is a conventional value to say that it is not
          // calculated when the difference between the max(samples) - min(samples) < threshold
          auto monTime = Monitored::Scalar<float>("time" + channelGainSuffix, time);
          fill(m_tools[m_timeGroups[partition][drawer]], monTime);
        }
 
        if (m_cabling->isDisconnected(ros, drawer, channel)
            || amplitude < m_minAmpForCorrectedTime
            // In EB exclude some channels (most likely single PMT) from calculating average time
            || ((ros > 2) && (channel < 6 || channel == 12 || channel == 13 || channel == 18 || channel == 19))) {
          continue;
        } else {
          partitionTimeSum[partition] += time;
          nChannels[partition] += 1;
        }
 
      } else { // It's CIS run
 
        if (m_fill2DHistograms) {
          auto monAmplitude = Monitored::Scalar<float>("amp" + channelGainSuffix, amplitude);
          auto monCharge = Monitored::Scalar<float>("charge" + channelGainSuffix, charge);
          fill(m_tools[ampVsQCapGroups[partition][drawer]], monCharge, monAmplitude);
        }
 
        if ((minCharge[adc] < charge) && (charge < maxCharge[adc])) {
          double ratio = amplitude * invCharge;
          auto monRatio = Monitored::Scalar<float>("amp_ratio" + channelGainSuffix, ratio);
          fill(m_tools[ampOverQCapGroups[partition][drawer]], monRatio);
 
          auto monTime = Monitored::Scalar<float>("time" + channelGainSuffix, time);
          fill(m_tools[timeCapGroups[partition][drawer]], monTime);
 
          if (m_fill2DHistograms) {
            auto monInjTime = Monitored::Scalar<float>("inj_time" + channelGainSuffix, injectionTime);
            fill(m_tools[timeVsTimeCapGroups[partition][drawer]], monInjTime, monTime);
          }
        }
      }
    }
  }
 
  if (m_runTypeIsNotCIS) {
    for (unsigned int partition = 0; partition < Tile::MAX_ROS - 1; ++partition) {
      if (nChannels[partition] > 0) {
        float averagePartitionTime = partitionTimeSum[partition] / nChannels[partition];
        for (unsigned int drawer = 0; drawer < Tile::MAX_DRAWER; ++drawer) {
          for (unsigned int channel = 0; channel < Tile::MAX_CHAN; ++channel) {
            for (unsigned int gain = 0; gain < Tile::MAX_GAIN; ++gain) {
              float time = offlineTime[partition][drawer][channel][gain];
              if (time != 0) {
                std::string channelGainSuffix = "_" + std::to_string(channel) + "_" + std::to_string(gain);
                float timeCorrected = time - averagePartitionTime;
                auto monTimeCorr = Monitored::Scalar<float>("time_corr" + channelGainSuffix, timeCorrected);
                fill(m_tools[m_timeCorrGroups[partition][drawer]], monTimeCorr);
              }
            }
          }
        }
      }
    }
  }
 
 
  if (m_fillHistogramsForDSP) {
 
    SG::ReadHandle<TileRawChannelContainer> dspRawChannelContainer(m_dspRawChannelContainerKey, ctx);
    ATH_CHECK( dspRawChannelContainer.isValid() );
 
    TileRawChannelUnit::UNIT dspRawChannelUnit = dspRawChannelContainer->get_unit();
 
    for (const TileRawChannelCollection* rawChannelCollection : *dspRawChannelContainer) {
      if (rawChannelCollection->empty() ) continue;
 
      HWIdentifier adc_id = rawChannelCollection->front()->adc_HWID();
      int ros = m_tileHWID->ros(adc_id);
      int drawer = m_tileHWID->drawer(adc_id);
      unsigned int drawerIdx = TileCalibUtils::getDrawerIdx(ros, drawer);
      int partition = ros - 1;
 
      for (const TileRawChannel* rawChannel : *rawChannelCollection) {
        adc_id = rawChannel->adc_HWID();
        int channel = m_tileHWID->channel(adc_id);
        int adc = m_tileHWID->adc(adc_id);
 
        if (corruptedData[partition][drawer][adc][channel / 3]) continue;
 
        std::string channelGainSuffix = "_" + std::to_string(channel) + "_" + std::to_string(adc);
 
        float amplitude = rawChannel->amplitude();
        if (dspRawChannelUnit != m_finalRawChannelUnit) {
          // Put everything in PicoCoulomb by default for all run types
          // For Laser and Physcs calibrate in CesiumPicoCoulomb for all channels, but the MBTS channels,
          // for which we keep the calibration in PicoCoulombCesium pC for consistency (no Cs calibration is possible)
          if ((m_finalRawChannelUnit == TileRawChannelUnit::CesiumPicoCoulombs) && (ros > 3)) {
            // if EB then check that they are not MBTS channel
            int index, pmt;
            rawChannel->cell_ID_index(index, pmt);
            if (index < -1) { // MBTS channel
              amplitude = emScale->calibrateChannel(drawerIdx, channel, adc, amplitude, dspRawChannelUnit, TileRawChannelUnit::PicoCoulombs);
            }
          }
          amplitude = emScale->calibrateChannel(drawerIdx, channel, adc, amplitude, dspRawChannelUnit, m_finalRawChannelUnit);
        } // no need to calibrate
 
        auto monAmplitude = Monitored::Scalar<float>("dsp_amp" + channelGainSuffix, amplitude);
        fill(m_tools[m_dspAmpGroups[partition][drawer]], monAmplitude);
 
        float offline_amplitude = offlineAmplitude[partition][drawer][channel][adc];
        if (offline_amplitude > m_minOfflineAmp) {
          float amplitudeDiff = (amplitude - offline_amplitude) / offline_amplitude;
          auto monAmplitudeDiff = Monitored::Scalar<float>("dsp-fit_amp_diff" + channelGainSuffix, amplitudeDiff);
          fill(m_tools[m_ampDiffGroups[partition][drawer]], monAmplitudeDiff);
        }
 
        float time = rawChannel->time();
        auto monTime = Monitored::Scalar<float>("dsp_time" + channelGainSuffix, time);
        fill(m_tools[m_dspTimeGroups[partition][drawer]], monTime);
 
        float offline_time = offlineTime[partition][drawer][channel][adc];
        if (offline_time != 0.) {
          float timeDiff = time - offline_time;
          auto monTimeDiff = Monitored::Scalar<float>("dsp-fit_time_diff" + channelGainSuffix, timeDiff);
          fill(m_tools[m_timeDiffGroups[partition][drawer]], monTimeDiff);
        }
 
        float chi2 = rawChannel->quality();
        auto monChi2 = Monitored::Scalar<float>("dsp_chi2" + channelGainSuffix, chi2);
        fill(m_tools[m_dspChi2Groups[partition][drawer]], monChi2);
 
        fill(m_tools[m_dspChi2VsAmpGroups[partition][drawer]], monAmplitude, monChi2);
      }
    }
  }
 
  fill("TileRawChannelMonExecuteTime", timer);
 
  return StatusCode::SUCCESS;
}

filterPassed()

virtual bool AthCommonReentrantAlgorithm< Gaudi::Algorithm >::filterPassed ( const EventContext &  ctx ) const

inlinevirtualinherited

Definition at line 96 of file AthCommonReentrantAlgorithm.h.

                                                           {
    return execState( ctx ).filterPassed();
  }

GetEventInfo()

SG::ReadHandle< xAOD::EventInfo > AthMonitorAlgorithm::GetEventInfo ( const EventContext &  ctx ) const

inherited

Return a ReadHandle for an EventInfo object (get run/event numbers, etc.)

Parameters

ctx	EventContext for the event

Returns

a SG::ReadHandle<xAOD::EventInfo>

Definition at line 107 of file AthMonitorAlgorithm.cxx.

                                                                                             {
    return SG::ReadHandle<xAOD::EventInfo>(m_EventInfoKey, ctx);
}

getGroup()

const ToolHandle< GenericMonitoringTool > & AthMonitorAlgorithm::getGroup ( const std::string &  name ) const

inherited

Get a specific monitoring tool from the tool handle array.

Finds a specific GenericMonitoringTool instance from the list of monitoring tools (a ToolHandleArray). Throws a FATAL warning if the object found is empty.

Parameters

name	string name of the desired tool

Returns

reference to the desired monitoring tool

Definition at line 164 of file AthMonitorAlgorithm.cxx.

                                                                                                    {
    // get the pointer to the tool, and check that it exists
    auto idx = m_toolLookupMap.find(name);
    if (ATH_LIKELY(idx != m_toolLookupMap.end())) {
        return m_tools[idx->second];
    }
    else {
      // treat empty tool handle case as in Monitored::Group
      if (m_toolLookupMap.empty()) {
    return m_dummy;
      }
 
      if (!isInitialized()) {
        ATH_MSG_FATAL(
            "It seems that the AthMonitorAlgorithm::initialize was not called "
            "in derived class initialize method");
      } else {
        std::string available = std::accumulate(
            m_toolLookupMap.begin(), m_toolLookupMap.end(), std::string(""),
            [](const std::string& s, auto h) { return s + "," + h.first; });
        ATH_MSG_FATAL("The tool " << name << " could not be found in the tool array of the "
                      << "monitoring algorithm " << m_name << ". This probably reflects a discrepancy between "
                      << "your python configuration and c++ filling code. Note: your available groups are {"
                      << available << "}.");
        }
    }
    return m_dummy;
}

getTrigDecisionTool()

const ToolHandle< Trig::TrigDecisionTool > & AthMonitorAlgorithm::getTrigDecisionTool ( ) const

inherited

Get the trigger decision tool member.

The trigger decision tool is used to check whether a specific trigger is passed by an event.

Returns

m_trigDecTool

Definition at line 194 of file AthMonitorAlgorithm.cxx.

                                                                                       {
    return m_trigDecTool;
}

initialize()

StatusCode TileRawChannelMonitorAlgorithm::initialize ( )

overridevirtual

initialize

Returns

StatusCode

Reimplemented from TileCalibMonitorAlgorithm.

Definition at line 12 of file TileRawChannelMonitorAlgorithm.cxx.

                                                      {
 
  ATH_MSG_DEBUG("in initialize()");
 
  // initialize superclass
  ATH_CHECK( TileCalibMonitorAlgorithm::initialize() );
 
  ATH_CHECK( m_digitsContainerKey.initialize() );
  ATH_CHECK( m_rawChannelContainerKey.initialize(SG::AllowEmpty) );
  ATH_CHECK( m_dspRawChannelContainerKey.initialize(m_fillHistogramsForDSP) );
  ATH_CHECK( m_emScaleKey.initialize() );
 
  m_dac2Charge[0] = 100.* 2.0 * 4.096 / m_tileInfo->ADCmax(); // 100 pF * 2 for legacy or 200 pF for demonstrator
  m_dac2Charge[1] = 5.2 * 2.0 * 4.096 / m_tileInfo->ADCmax(); // use the same number 5.2 pF as in TileCisDefaultCalibTool
 
  if ((m_calibUnit >= 0) && (m_calibUnit <= 3)) {
    m_finalRawChannelUnit = static_cast<TileRawChannelUnit::UNIT>(m_calibUnit.value());
  }
 
  if (m_calibUnit == TileRawChannelUnit::Invalid) {
    m_finalRawChannelUnit = (m_runType == PHYS_RUN) ? TileRawChannelUnit::CesiumPicoCoulombs
                                                    : TileRawChannelUnit::PicoCoulombs;
  }
 
  ATH_MSG_INFO("Final Units: " << m_finalRawChannelUnit);
 
  using Tile = TileCalibUtils;
  using namespace Monitored;
 
  m_runTypeIsNotCIS = !((m_runType == CIS_RUN) || (m_runType == CIS_RAMP_RUN));
 
  if (m_runTypeIsNotCIS) {
    m_ampGroups = buildToolMap<std::vector<int>>(m_tools, "TileRawChannelAmp",
                                                 Tile::MAX_ROS - 1, Tile::MAX_DRAWER);
 
    m_timeGroups = buildToolMap<std::vector<int>>(m_tools, "TileRawChannelTime",
                                                  Tile::MAX_ROS - 1, Tile::MAX_DRAWER);
 
    m_timeCorrGroups = buildToolMap<std::vector<int>>(m_tools, "TileRawChannelTimeCorr",
                                                      Tile::MAX_ROS - 1, Tile::MAX_DRAWER);
  } else { // CIS run
    // For 5 pF capacitor
    m_ampOverQ5Groups = buildToolMap<std::vector<int>>(m_tools, "TileRawChannelAmpOverQ5",
                                                       Tile::MAX_ROS - 1, Tile::MAX_DRAWER);
 
    m_time5Groups = buildToolMap<std::vector<int>>(m_tools, "TileRawChannelTime5",
                                                   Tile::MAX_ROS - 1, Tile::MAX_DRAWER);
 
    // For 100 pF capacitor
    m_ampOverQ100Groups = buildToolMap<std::vector<int>>(m_tools, "TileRawChannelAmpOverQ100",
                                                         Tile::MAX_ROS - 1, Tile::MAX_DRAWER);
 
    m_time100Groups = buildToolMap<std::vector<int>>(m_tools, "TileRawChannelTime100",
                                                     Tile::MAX_ROS - 1, Tile::MAX_DRAWER);
 
    if (m_fill2DHistograms) {
      // For 5 pF capacitor
      m_ampVsQ5Groups = buildToolMap<std::vector<int>>(m_tools, "TileRawChannelAmpVsQ5",
                                                       Tile::MAX_ROS - 1, Tile::MAX_DRAWER);
 
      m_timeVsTime5Groups = buildToolMap<std::vector<int>>(m_tools, "TileRawChannelTimeVsTime5",
                                                           Tile::MAX_ROS - 1, Tile::MAX_DRAWER);
 
      // For 100 pF capacitor
      m_ampVsQ100Groups = buildToolMap<std::vector<int>>(m_tools, "TileRawChannelAmpVsQ100",
                                                         Tile::MAX_ROS - 1, Tile::MAX_DRAWER);
 
      m_timeVsTime100Groups = buildToolMap<std::vector<int>>(m_tools, "TileRawChannelTimeVsTime100",
                                                             Tile::MAX_ROS - 1, Tile::MAX_DRAWER);
 
    }
  }
 
 
  if (m_fillHistogramsForDSP) {
    m_dspAmpGroups = buildToolMap<std::vector<int>>(m_tools, "TileRawChannelDspAmp",
                                                  Tile::MAX_ROS - 1, Tile::MAX_DRAWER);
 
    m_dspTimeGroups = buildToolMap<std::vector<int>>(m_tools, "TileRawChannelDspTime",
                                                     Tile::MAX_ROS - 1, Tile::MAX_DRAWER);
 
    m_dspChi2Groups = buildToolMap<std::vector<int>>(m_tools, "TileRawChannelDspChi2",
                                                     Tile::MAX_ROS - 1, Tile::MAX_DRAWER);
 
    m_dspChi2VsAmpGroups = buildToolMap<std::vector<int>>(m_tools, "TileRawChannelDspChi2VsAmp",
                                                          Tile::MAX_ROS - 1, Tile::MAX_DRAWER);
 
    m_ampDiffGroups = buildToolMap<std::vector<int>>(m_tools, "TileRawChannelAmpDiff",
                                                     Tile::MAX_ROS - 1, Tile::MAX_DRAWER);
 
    m_timeDiffGroups = buildToolMap<std::vector<int>>(m_tools, "TileRawChannelTimeDiff",
                                                      Tile::MAX_ROS - 1, Tile::MAX_DRAWER);
  }
 
 
  return StatusCode::SUCCESS;
}

inputHandles()

virtual std::vector<Gaudi::DataHandle*> AthCommonDataStore< AthCommonMsg< Gaudi::Algorithm > >::inputHandles ( ) const

overridevirtualinherited

Return this algorithm's input handles.

We override this to include handle instances from key arrays if they have not yet been declared. See comments on updateVHKA.

isClonable()

bool AthCommonReentrantAlgorithm< Gaudi::Algorithm >::isClonable

overridevirtualinherited

Specify if the algorithm is clonable.

Reentrant algorithms are clonable.

Definition at line 68 of file AthCommonReentrantAlgorithm.cxx.

{
  // Reentrant algorithms are clonable.
  return true;
}

isDmuHeaderError()

bool TileRawChannelMonitorAlgorithm::isDmuHeaderError ( uint32_t  header ) const

private

Definition at line 387 of file TileRawChannelMonitorAlgorithm.cxx.

                                                                           {
 
  bool error = false;
  if (isHeaderFormatError(header)) {
    error = true;
  } else if (isHeaderParityError(header)) {
    error = true;
  } else if ((header >> 25) & 0x1) {
    // Memory Parity Error
    error = true;
  } else if ((header >> 24) & 0x1) {
    // Single Strobe Error
    error = true;
  } else if ((header >> 23) & 0x1) {
    // Double Strobe Error
    error = true;
  }
 
  return error;
}

isHeaderFormatError()

bool TileCalibMonitorAlgorithm::isHeaderFormatError ( uint32_t  header ) const

inlineprotectedinherited

Definition at line 42 of file TileCalibMonitorAlgorithm.h.

                                                    {
      return (((header >> 31 & 0x1) == 1) && ((header >> 17 & 0x1) == 0)) ? false : true;
    };

isHeaderParityError()

bool TileCalibMonitorAlgorithm::isHeaderParityError ( uint32_t  header ) const

inlineprotectedinherited

Definition at line 51 of file TileCalibMonitorAlgorithm.h.

                                                    {
      uint32_t parity(0);
      for (int i = 0; i < 32; ++i) {
        parity += ((header >> i) & 0x1);
      }
      return ((parity % 2) == 1) ? false : true;
    };

msg() [1/2]

MsgStream& AthCommonMsg< Gaudi::Algorithm >::msg ( ) const

inlineinherited

Definition at line 24 of file AthCommonMsg.h.

                                {
    return this->msgStream();
  }

msg() [2/2]

MsgStream& AthCommonMsg< Gaudi::Algorithm >::msg ( const MSG::Level  lvl ) const

inlineinherited

Definition at line 27 of file AthCommonMsg.h.

                                                  {
    return this->msgStream(lvl);
  }

msgLvl()

bool AthCommonMsg< Gaudi::Algorithm >::msgLvl ( const MSG::Level  lvl ) const

inlineinherited

Definition at line 30 of file AthCommonMsg.h.

                                               {
    return this->msgLevel(lvl);
  }

outputHandles()

virtual std::vector<Gaudi::DataHandle*> AthCommonDataStore< AthCommonMsg< Gaudi::Algorithm > >::outputHandles ( ) const

overridevirtualinherited

Return this algorithm's output handles.

We override this to include handle instances from key arrays if they have not yet been declared. See comments on updateVHKA.

parseList()

StatusCode AthMonitorAlgorithm::parseList ( const std::string &  line, std::vector< std::string > &  result  ) const

virtualinherited

Parse a string into a vector.

The input string is a single long string of all of the trigger names. It parses this string and turns it into a vector, where each element is one trigger or trigger category.

Parameters

line	The input string.
result	The parsed output vector of strings.

Returns

StatusCode

Definition at line 341 of file AthMonitorAlgorithm.cxx.

                                                                                                   {
    std::string item;
    std::stringstream ss(line);
 
    ATH_MSG_DEBUG( "AthMonitorAlgorithm::parseList()" );
 
    while ( std::getline(ss, item, ',') ) {
        std::stringstream iss(item); // remove whitespace
        iss >> item;
        result.push_back(item);
    }
 
    return StatusCode::SUCCESS;
}

renounce()

std::enable_if_t<std::is_void_v<std::result_of_t<decltype(&T::renounce)(T)> > && !std::is_base_of_v<SG::VarHandleKeyArray, T> && std::is_base_of_v<Gaudi::DataHandle, T>, void> AthCommonDataStore< AthCommonMsg< Gaudi::Algorithm > >::renounce ( T &  h )

inlineprotectedinherited

Definition at line 380 of file AthCommonDataStore.h.

  {
    h.renounce();
    PBASE::renounce (h);
  }

renounceArray()

void AthCommonDataStore< AthCommonMsg< Gaudi::Algorithm > >::renounceArray ( SG::VarHandleKeyArray &  handlesArray )

inlineprotectedinherited

remove all handles from I/O resolution

Definition at line 364 of file AthCommonDataStore.h.

                                                          {
    handlesArray.renounce();
  }

setFilterPassed()

virtual void AthCommonReentrantAlgorithm< Gaudi::Algorithm >::setFilterPassed ( bool  state, const EventContext &  ctx  ) const

inlinevirtualinherited

Definition at line 100 of file AthCommonReentrantAlgorithm.h.

                                                                            {
    execState( ctx ).setFilterPassed( state );
  }

sysExecute()

StatusCode AthCommonReentrantAlgorithm< Gaudi::Algorithm >::sysExecute ( const EventContext &  ctx )

overridevirtualinherited

Execute an algorithm.

We override this in order to work around an issue with the Algorithm base class storing the event context in a member variable that can cause crashes in MT jobs.

Definition at line 85 of file AthCommonReentrantAlgorithm.cxx.

{
  return BaseAlg::sysExecute (ctx);
}

sysInitialize()

StatusCode AthCommonReentrantAlgorithm< Gaudi::Algorithm >::sysInitialize

overridevirtualinherited

Override sysInitialize.

Override sysInitialize from the base class.

Loop through all output handles, and if they're WriteCondHandles, automatically register them and this Algorithm with the CondSvc

Scan through all outputHandles, and if they're WriteCondHandles, register them with the CondSvc

Reimplemented from AthCommonDataStore< AthCommonMsg< Gaudi::Algorithm > >.

Reimplemented in InputMakerBase, and HypoBase.

Definition at line 61 of file AthCommonReentrantAlgorithm.cxx.

                                                               {
  StatusCode sc=AthCommonDataStore<AthCommonMsg<BaseAlg>>::sysInitialize();
 
  if (sc.isFailure()) {
    return sc;
  }
  
  ServiceHandle<ICondSvc> cs("CondSvc",name());
  for (auto h : outputHandles()) {
    if (h->isCondition() && h->mode() == Gaudi::DataHandle::Writer) {
      // do this inside the loop so we don't create the CondSvc until needed
      if ( cs.retrieve().isFailure() ) {
        ATH_MSG_WARNING("no CondSvc found: won't autoreg WriteCondHandles");
        return StatusCode::SUCCESS;
      }      
      if (cs->regHandle(this,*h).isFailure()) {
        sc = StatusCode::FAILURE;
        ATH_MSG_ERROR("unable to register WriteCondHandle " << h->fullKey()
                      << " with CondSvc");
      }
    }
  }
  return sc;  
}

sysStart()

virtual StatusCode AthCommonDataStore< AthCommonMsg< Gaudi::Algorithm > >::sysStart ( )

overridevirtualinherited

Handle START transition.

We override this in order to make sure that conditions handle keys can cache a pointer to the conditions container.

TileCalibMonitorAlgorithm()

TileCalibMonitorAlgorithm::TileCalibMonitorAlgorithm

inline

Definition at line 25 of file TileCalibMonitorAlgorithm.h.

      :AthMonitorAlgorithm(name, svcLocator) {}

trigChainsArePassed()

bool AthMonitorAlgorithm::trigChainsArePassed ( const std::vector< std::string > &  vTrigNames ) const

inherited

Check whether triggers are passed.

For the event, use the trigger decision tool to check that at least one of the triggers listed in the supplied vector is passed.

Parameters

vTrigNames

List of trigger names.

Returns

If empty input, default to true. If at least one trigger is specified, returns whether at least one trigger was passed.

Definition at line 199 of file AthMonitorAlgorithm.cxx.

                                                                                            {
 
  
  // If no triggers were given, return true.
  if (vTrigNames.empty()) return true;
  
  
  // Trigger: Check if this Algorithm is being run as an Express Stream job.
  // Events are entering the express stream are chosen randomly, and by chain,
  // Hence an additional check should be aplied to see if the chain(s)
  // monitored here are responsible for the event being selected for
  // the express stream.
 
  const auto group =  m_trigDecTool->getChainGroup(vTrigNames);
  if (m_enforceExpressTriggers){  
    const auto passedBits = m_trigDecTool->isPassedBits(group);
    bool expressPass = passedBits & TrigDefs::Express_passed; //bitwise AND
    if(!expressPass) {
      return false;
    }
  }
  
  // monitor the event if any of the chains in the chain group passes the event.
  return group->isPassed();
  
}

updateVHKA()

void AthCommonDataStore< AthCommonMsg< Gaudi::Algorithm > >::updateVHKA ( Gaudi::Details::PropertyBase &  )

inlineinherited

Definition at line 308 of file AthCommonDataStore.h.

                                               {
    // debug() << "updateVHKA for property " << p.name() << " " << p.toString() 
    //         << "  size: " << m_vhka.size() << endmsg;
    for (auto &a : m_vhka) {
      std::vector<SG::VarHandleKey*> keys = a->keys();
      for (auto k : keys) {
        k->setOwner(this);
      }
    }
  }

Member Data Documentation

cfg

TileRawChannelMonitorAlgorithm.cfg

Definition at line 242 of file TileRawChannelMonitorAlgorithm.py.

enableLumiAccess

TileRawChannelMonitorAlgorithm.enableLumiAccess

Definition at line 235 of file TileRawChannelMonitorAlgorithm.py.

False

TileRawChannelMonitorAlgorithm.False

Definition at line 245 of file TileRawChannelMonitorAlgorithm.py.

Files

TileRawChannelMonitorAlgorithm.Files

Definition at line 232 of file TileRawChannelMonitorAlgorithm.py.

fillHistogramsForDSP

TileRawChannelMonitorAlgorithm.fillHistogramsForDSP

Definition at line 249 of file TileRawChannelMonitorAlgorithm.py.

flags

TileRawChannelMonitorAlgorithm.flags

Definition at line 231 of file TileRawChannelMonitorAlgorithm.py.

HISTFileName

TileRawChannelMonitorAlgorithm.HISTFileName

Definition at line 233 of file TileRawChannelMonitorAlgorithm.py.

m_ampDiffGroups

std::vector<std::vector<int> > TileRawChannelMonitorAlgorithm::m_ampDiffGroups

private

Definition at line 86 of file TileRawChannelMonitorAlgorithm.h.

m_ampGroups

std::vector<std::vector<int> > TileRawChannelMonitorAlgorithm::m_ampGroups

private

Definition at line 65 of file TileRawChannelMonitorAlgorithm.h.

m_ampOverQ100Groups

std::vector<std::vector<int> > TileRawChannelMonitorAlgorithm::m_ampOverQ100Groups

private

Definition at line 76 of file TileRawChannelMonitorAlgorithm.h.

m_ampOverQ5Groups

std::vector<std::vector<int> > TileRawChannelMonitorAlgorithm::m_ampOverQ5Groups

private

Definition at line 70 of file TileRawChannelMonitorAlgorithm.h.

m_ampVsQ100Groups

std::vector<std::vector<int> > TileRawChannelMonitorAlgorithm::m_ampVsQ100Groups

private

Definition at line 77 of file TileRawChannelMonitorAlgorithm.h.

m_ampVsQ5Groups

std::vector<std::vector<int> > TileRawChannelMonitorAlgorithm::m_ampVsQ5Groups

private

Definition at line 71 of file TileRawChannelMonitorAlgorithm.h.

m_cabling

const TileCablingService* TileCalibMonitorAlgorithm::m_cabling {nullptr}

protectedinherited

Definition at line 96 of file TileCalibMonitorAlgorithm.h.

m_cablingSvc

ServiceHandle<TileCablingSvc> TileCalibMonitorAlgorithm::m_cablingSvc

protectedinherited

Initial value:

{ this,
        "TileCablingSvc", "TileCablingSvc", "The Tile cabling service"}

Name of Tile cabling service.

Definition at line 93 of file TileCalibMonitorAlgorithm.h.

m_calibUnit

Gaudi::Property<int> TileRawChannelMonitorAlgorithm::m_calibUnit

private

Initial value:

{this,
        "CalibUnit", TileRawChannelUnit::Invalid, ""}

Definition at line 41 of file TileRawChannelMonitorAlgorithm.h.

m_dac2Charge

double TileRawChannelMonitorAlgorithm::m_dac2Charge[2] = {}

private

Definition at line 92 of file TileRawChannelMonitorAlgorithm.h.

m_dataType

AthMonitorAlgorithm::DataType_t AthMonitorAlgorithm::m_dataType

protectedinherited

Instance of the DataType_t enum.

Definition at line 351 of file AthMonitorAlgorithm.h.

m_dataTypeStr

Gaudi::Property<std::string> AthMonitorAlgorithm::m_dataTypeStr {this,"DataType","userDefined"}

protectedinherited

DataType string pulled from the job option and converted to enum.

Definition at line 353 of file AthMonitorAlgorithm.h.

m_defaultLBDuration

Gaudi::Property<float> AthMonitorAlgorithm::m_defaultLBDuration {this,"DefaultLBDuration",60.}

protectedinherited

Default duration of one lumi block.

Definition at line 360 of file AthMonitorAlgorithm.h.

m_detailLevel

Gaudi::Property<int> AthMonitorAlgorithm::m_detailLevel {this,"DetailLevel",0}

protectedinherited

Sets the level of detail used in the monitoring.

Definition at line 361 of file AthMonitorAlgorithm.h.

m_detStore

StoreGateSvc_t AthCommonDataStore< AthCommonMsg< Gaudi::Algorithm > >::m_detStore

privateinherited

Pointer to StoreGate (detector store by default)

Definition at line 393 of file AthCommonDataStore.h.

m_digitsContainerKey

SG::ReadHandleKey<TileDigitsContainer> TileRawChannelMonitorAlgorithm::m_digitsContainerKey

private

Initial value:

{this,
        "TileDigitsContainer", "TileDigitsCnt", "Input Tile digits container key"}

Definition at line 50 of file TileRawChannelMonitorAlgorithm.h.

m_DQFilterTools

ToolHandleArray<IDQFilterTool> AthMonitorAlgorithm::m_DQFilterTools {this,"FilterTools",{}}

protectedinherited

Array of Data Quality filter tools.

Definition at line 341 of file AthMonitorAlgorithm.h.

m_dqStatusKey

SG::ReadHandleKey<TileDQstatus> TileCalibMonitorAlgorithm::m_dqStatusKey

protectedinherited

Initial value:

{this,
        "TileDQstatus", "TileDQstatus", "Tile DQ status name"}

Definition at line 87 of file TileCalibMonitorAlgorithm.h.

m_dspAmpGroups

std::vector<std::vector<int> > TileRawChannelMonitorAlgorithm::m_dspAmpGroups

private

Definition at line 81 of file TileRawChannelMonitorAlgorithm.h.

m_dspChi2Groups

std::vector<std::vector<int> > TileRawChannelMonitorAlgorithm::m_dspChi2Groups

private

Definition at line 83 of file TileRawChannelMonitorAlgorithm.h.

m_dspChi2VsAmpGroups

std::vector<std::vector<int> > TileRawChannelMonitorAlgorithm::m_dspChi2VsAmpGroups

private

Definition at line 84 of file TileRawChannelMonitorAlgorithm.h.

m_dspRawChannelContainerKey

SG::ReadHandleKey<TileRawChannelContainer> TileRawChannelMonitorAlgorithm::m_dspRawChannelContainerKey

private

Initial value:

{this,
        "TileRawChannelContainerDSP", "TileRawChannelCnt", "Input DSP Tile raw channel container key"}

Definition at line 56 of file TileRawChannelMonitorAlgorithm.h.

m_dspTimeGroups

std::vector<std::vector<int> > TileRawChannelMonitorAlgorithm::m_dspTimeGroups

private

Definition at line 82 of file TileRawChannelMonitorAlgorithm.h.

m_dummy

const ToolHandle<GenericMonitoringTool> AthMonitorAlgorithm::m_dummy

privateinherited

Definition at line 369 of file AthMonitorAlgorithm.h.

m_emScaleKey

SG::ReadCondHandleKey<TileEMScale> TileRawChannelMonitorAlgorithm::m_emScaleKey

private

Initial value:

{this,
         "TileEMScale", "TileEMScale", "Input Tile EMS calibration constants"}

Name of TileEMScale in condition store.

Definition at line 62 of file TileRawChannelMonitorAlgorithm.h.

m_enforceExpressTriggers

Gaudi::Property<bool> AthMonitorAlgorithm::m_enforceExpressTriggers

privateinherited

Initial value:

{this,
                          "EnforceExpressTriggers", false,
                          "Requires that matched triggers made the event enter the express stream"}

Definition at line 372 of file AthMonitorAlgorithm.h.

m_environment

AthMonitorAlgorithm::Environment_t AthMonitorAlgorithm::m_environment

protectedinherited

Instance of the Environment_t enum.

Definition at line 350 of file AthMonitorAlgorithm.h.

m_environmentStr

Gaudi::Property<std::string> AthMonitorAlgorithm::m_environmentStr {this,"Environment","user"}

protectedinherited

Environment string pulled from the job option and converted to enum.

Definition at line 352 of file AthMonitorAlgorithm.h.

m_EventInfoKey

SG::ReadHandleKey<xAOD::EventInfo> AthMonitorAlgorithm::m_EventInfoKey {this,"EventInfoKey","EventInfo"}

protectedinherited

Key for retrieving EventInfo from StoreGate.

Definition at line 362 of file AthMonitorAlgorithm.h.

m_evtStore

StoreGateSvc_t AthCommonDataStore< AthCommonMsg< Gaudi::Algorithm > >::m_evtStore

privateinherited

Pointer to StoreGate (event store by default)

Definition at line 390 of file AthCommonDataStore.h.

m_extendedExtraObjects

DataObjIDColl AthCommonReentrantAlgorithm< Gaudi::Algorithm >::m_extendedExtraObjects

privateinherited

Extra output dependency collection, extended by AthAlgorithmDHUpdate to add symlinks.

Empty if no symlinks were found.

Definition at line 114 of file AthCommonReentrantAlgorithm.h.

m_fileKey

Gaudi::Property<std::string> AthMonitorAlgorithm::m_fileKey {this,"FileKey",""}

protectedinherited

Internal Athena name for file.

Definition at line 358 of file AthMonitorAlgorithm.h.

m_fill2DHistograms

Gaudi::Property<bool> TileRawChannelMonitorAlgorithm::m_fill2DHistograms

private

Initial value:

{this,
        "fill2DHistograms", true, "Create and fill 2D histograms"}

Definition at line 47 of file TileRawChannelMonitorAlgorithm.h.

m_fillHistogramsForDSP

Gaudi::Property<bool> TileRawChannelMonitorAlgorithm::m_fillHistogramsForDSP

private

Initial value:

{this,
        "fillHistogramsForDSP", false, "Create and fill histograms for raw channels from DSP"}

Definition at line 44 of file TileRawChannelMonitorAlgorithm.h.

m_finalRawChannelUnit

TileRawChannelUnit::UNIT TileRawChannelMonitorAlgorithm::m_finalRawChannelUnit {TileRawChannelUnit::Invalid}

private

Definition at line 90 of file TileRawChannelMonitorAlgorithm.h.

m_fragIDsDemonstrators

Gaudi::Property<std::vector<int> > TileCalibMonitorAlgorithm::m_fragIDsDemonstrators

protectedinherited

Initial value:

{this,
        "FragIDsDemonstrators", {}, "List of Tile frag IDs of Demonstrators"}

Definition at line 81 of file TileCalibMonitorAlgorithm.h.

m_fragIDsToIgnoreDMUerrors

Gaudi::Property<std::vector<int> > TileCalibMonitorAlgorithm::m_fragIDsToIgnoreDMUerrors

protectedinherited

Initial value:

{this,
        "FragIDsToIgnoreDMUErrors", {}, "List of Tile frag IDs for which ignore DMU errors"}

Definition at line 78 of file TileCalibMonitorAlgorithm.h.

m_lbDurationDataKey

SG::ReadCondHandleKey<LBDurationCondData> AthMonitorAlgorithm::m_lbDurationDataKey {this,"LBDurationCondDataKey","LBDurationCondData","SG Key of LBDurationCondData object"}

protectedinherited

Definition at line 345 of file AthMonitorAlgorithm.h.

m_lumiDataKey

SG::ReadCondHandleKey<LuminosityCondData> AthMonitorAlgorithm::m_lumiDataKey {this,"LuminosityCondDataKey","LuminosityCondData","SG Key of LuminosityCondData object"}

protectedinherited

Definition at line 343 of file AthMonitorAlgorithm.h.

m_minAmpForCorrectedTime

Gaudi::Property<float> TileRawChannelMonitorAlgorithm::m_minAmpForCorrectedTime

private

Initial value:

{this,
        "MinAmpForCorrectedTime", 0.5, "Minimum amplitude to use channel for time correction calculation"}

Definition at line 35 of file TileRawChannelMonitorAlgorithm.h.

m_minOfflineAmp

Gaudi::Property<float> TileRawChannelMonitorAlgorithm::m_minOfflineAmp

private

Initial value:

{this,
        "MinOfflineAmp", 0.3, "Minimum offline amplitude for DSP check"}

Definition at line 38 of file TileRawChannelMonitorAlgorithm.h.

m_name

std::string AthMonitorAlgorithm::m_name

privateinherited

Definition at line 366 of file AthMonitorAlgorithm.h.

m_rawChannelContainerKey

SG::ReadHandleKey<TileRawChannelContainer> TileRawChannelMonitorAlgorithm::m_rawChannelContainerKey

private

Initial value:

{this,
        "TileRawChannelContainer", "", "Input Tile raw channel container key"}

Definition at line 53 of file TileRawChannelMonitorAlgorithm.h.

m_runType

Gaudi::Property<int> TileCalibMonitorAlgorithm::m_runType

protectedinherited

Initial value:

{this,
        "RunType", 0, "Run type: 1 - phys, 2 - las, 4 - ped, 8 - cis, 9- mono"}

Definition at line 84 of file TileCalibMonitorAlgorithm.h.

m_runTypeIsNotCIS

bool TileRawChannelMonitorAlgorithm::m_runTypeIsNotCIS {true}

private

Definition at line 93 of file TileRawChannelMonitorAlgorithm.h.

m_tileHWID

const TileHWID* TileCalibMonitorAlgorithm::m_tileHWID {nullptr}

protectedinherited

Definition at line 97 of file TileCalibMonitorAlgorithm.h.

m_tileInfo

const TileInfo* TileCalibMonitorAlgorithm::m_tileInfo {nullptr}

protectedinherited

Definition at line 98 of file TileCalibMonitorAlgorithm.h.

m_tileInfoName

Gaudi::Property<std::string> TileCalibMonitorAlgorithm::m_tileInfoName

protectedinherited

Initial value:

{this,
        "TileInfo", "TileInfo", "Name of TileInfo object in Detector Store"}

Definition at line 75 of file TileCalibMonitorAlgorithm.h.

m_time100Groups

std::vector<std::vector<int> > TileRawChannelMonitorAlgorithm::m_time100Groups

private

Definition at line 78 of file TileRawChannelMonitorAlgorithm.h.

m_time5Groups

std::vector<std::vector<int> > TileRawChannelMonitorAlgorithm::m_time5Groups

private

Definition at line 72 of file TileRawChannelMonitorAlgorithm.h.

m_timeCorrGroups

std::vector<std::vector<int> > TileRawChannelMonitorAlgorithm::m_timeCorrGroups

private

Definition at line 67 of file TileRawChannelMonitorAlgorithm.h.

m_timeDiffGroups

std::vector<std::vector<int> > TileRawChannelMonitorAlgorithm::m_timeDiffGroups

private

Definition at line 87 of file TileRawChannelMonitorAlgorithm.h.

m_timeGroups

std::vector<std::vector<int> > TileRawChannelMonitorAlgorithm::m_timeGroups

private

Definition at line 66 of file TileRawChannelMonitorAlgorithm.h.

m_timeVsTime100Groups

std::vector<std::vector<int> > TileRawChannelMonitorAlgorithm::m_timeVsTime100Groups

private

Definition at line 79 of file TileRawChannelMonitorAlgorithm.h.

m_timeVsTime5Groups

std::vector<std::vector<int> > TileRawChannelMonitorAlgorithm::m_timeVsTime5Groups

private

Definition at line 73 of file TileRawChannelMonitorAlgorithm.h.

m_toolLookupMap

std::unordered_map<std::string, size_t> AthMonitorAlgorithm::m_toolLookupMap

privateinherited

Definition at line 367 of file AthMonitorAlgorithm.h.

m_tools

ToolHandleArray<GenericMonitoringTool> AthMonitorAlgorithm::m_tools {this,"GMTools",{}}

protectedinherited

Array of Generic Monitoring Tools.

Definition at line 338 of file AthMonitorAlgorithm.h.

m_trigDecTool

PublicToolHandle<Trig::TrigDecisionTool> AthMonitorAlgorithm::m_trigDecTool {this, "TrigDecisionTool",""}

protectedinherited

Tool to tell whether a specific trigger is passed.

Definition at line 340 of file AthMonitorAlgorithm.h.

m_triggerChainString

Gaudi::Property<std::string> AthMonitorAlgorithm::m_triggerChainString {this,"TriggerChain",""}

protectedinherited

Trigger chain string pulled from the job option and parsed into a vector.

Definition at line 355 of file AthMonitorAlgorithm.h.

m_trigLiveFractionDataKey

SG::ReadCondHandleKey<TrigLiveFractionCondData> AthMonitorAlgorithm::m_trigLiveFractionDataKey {this,"TrigLiveFractionCondDataKey","TrigLiveFractionCondData", "SG Key of TrigLiveFractionCondData object"}

protectedinherited

Definition at line 347 of file AthMonitorAlgorithm.h.

m_useLumi

Gaudi::Property<bool> AthMonitorAlgorithm::m_useLumi {this,"EnableLumi",false}

protectedinherited

Allows use of various luminosity functions.

Definition at line 359 of file AthMonitorAlgorithm.h.

m_varHandleArraysDeclared

bool AthCommonDataStore< AthCommonMsg< Gaudi::Algorithm > >::m_varHandleArraysDeclared

privateinherited

Definition at line 399 of file AthCommonDataStore.h.

m_vhka

std::vector<SG::VarHandleKeyArray*> AthCommonDataStore< AthCommonMsg< Gaudi::Algorithm > >::m_vhka

privateinherited

Definition at line 398 of file AthCommonDataStore.h.

m_vTrigChainNames

std::vector<std::string> AthMonitorAlgorithm::m_vTrigChainNames

protectedinherited

Vector of trigger chain names parsed from trigger chain string.

Definition at line 356 of file AthMonitorAlgorithm.h.

MAX_DMU

const int TileRawChannelMonitorAlgorithm::MAX_DMU {16}

staticprivate

Definition at line 89 of file TileRawChannelMonitorAlgorithm.h.

MaxEvents

TileRawChannelMonitorAlgorithm.MaxEvents

Definition at line 236 of file TileRawChannelMonitorAlgorithm.py.

readBeamElem

TileRawChannelMonitorAlgorithm.readBeamElem

Definition at line 245 of file TileRawChannelMonitorAlgorithm.py.

readMuRcv

TileRawChannelMonitorAlgorithm.readMuRcv

Definition at line 245 of file TileRawChannelMonitorAlgorithm.py.

sc

TileRawChannelMonitorAlgorithm.sc

Definition at line 255 of file TileRawChannelMonitorAlgorithm.py.

TileRawChannelContainer

TileRawChannelMonitorAlgorithm.TileRawChannelContainer

Definition at line 248 of file TileRawChannelMonitorAlgorithm.py.

useTrigger

TileRawChannelMonitorAlgorithm.useTrigger

Definition at line 234 of file TileRawChannelMonitorAlgorithm.py.

---

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

• TileRawChannelMonitorAlgorithm.h
• TileRawChannelMonitorAlgorithm.py
• TileRawChannelMonitorAlgorithm.cxx