TileTBBeamMonitorAlgorithm Class Reference

Class for Tile TB Beam elements based monitoring. More...

#include <TileTBBeamMonitorAlgorithm.h>

Inheritance diagram for TileTBBeamMonitorAlgorithm:

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

Public Member Functions
virtual	~TileTBBeamMonitorAlgorithm ()=default
virtual StatusCode	initialize () override
	initialize
virtual StatusCode	fillHistograms (const EventContext &ctx) const override
	adds event to the monitoring histograms
	AthMonitorAlgorithm (const std::string &name, ISvcLocator *pSvcLocator)
	Constructor.
virtual StatusCode	execute (const EventContext &ctx) const override
	Applies filters and trigger requirements.
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.
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.
template<typename... T>
void	fill (const ToolHandle< GenericMonitoringTool > &groupHandle, T &&... variables) const
	Fills a variadic list of variables to a group by reference.
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.
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.
template<typename... T>
void	fill (const std::string &groupName, T &&... variables) const
	Fills a variadic list of variables to a group by name.
Environment_t	environment () const
	Accessor functions for the environment.
Environment_t	envStringToEnum (const std::string &str) const
	Convert the environment string from the python configuration to an enum object.
DataType_t	dataType () const
	Accessor functions for the data type.
DataType_t	dataTypeStringToEnum (const std::string &str) const
	Convert the data type string from the python configuration to an enum object.
const ToolHandle< GenericMonitoringTool > &	getGroup (const std::string &name) const
	Get a specific monitoring tool from the tool handle array.
const ToolHandle< Trig::TrigDecisionTool > &	getTrigDecisionTool () const
	Get the trigger decision tool member.
bool	trigChainsArePassed (const std::vector< std::string > &vTrigNames) const
	Check whether triggers are passed.
SG::ReadHandle< xAOD::EventInfo >	GetEventInfo (const EventContext &) const
	Return a ReadHandle for an EventInfo object (get run/event numbers, etc.)
virtual float	lbAverageInteractionsPerCrossing (const EventContext &ctx=Gaudi::Hive::currentContext()) const
	Calculate the average mu, i.e.
virtual float	lbInteractionsPerCrossing (const EventContext &ctx=Gaudi::Hive::currentContext()) const
	Calculate instantaneous number of interactions, i.e.
virtual float	lbAverageLuminosity (const EventContext &ctx=Gaudi::Hive::currentContext()) const
	Calculate average luminosity (in ub-1 s-1 => 10^30 cm-2 s-1).
virtual float	lbLuminosityPerBCID (const EventContext &ctx=Gaudi::Hive::currentContext()) const
	Calculate the instantaneous luminosity per bunch crossing.
virtual double	lbDuration (const EventContext &ctx=Gaudi::Hive::currentContext()) const
	Calculate the duration of the luminosity block (in seconds)
virtual float	lbAverageLivefraction (const EventContext &ctx=Gaudi::Hive::currentContext()) const
	Calculate the average luminosity livefraction.
virtual float	livefractionPerBCID (const EventContext &ctx=Gaudi::Hive::currentContext()) const
	Calculate the live fraction per bunch crossing ID.
virtual double	lbLumiWeight (const EventContext &ctx=Gaudi::Hive::currentContext()) const
	Calculate the average integrated luminosity multiplied by the live fraction.
virtual StatusCode	parseList (const std::string &line, std::vector< std::string > &result) const
	Parse a string into a vector.
virtual StatusCode	sysInitialize () override
	Override sysInitialize.
virtual bool	isClonable () const override
	Specify if the algorithm is clonable.
virtual unsigned int	cardinality () const override
	Cardinality (Maximum number of clones that can exist) special value 0 means that algorithm is reentrant.
virtual StatusCode	sysExecute (const EventContext &ctx) override
	Execute an algorithm.
virtual const DataObjIDColl &	extraOutputDeps () const override
	Return the list of extra output dependencies.
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.
const ServiceHandle< StoreGateSvc > &	detStore () const
	The standard StoreGateSvc/DetectorStore Returns (kind of) a pointer to the StoreGateSvc.
virtual StatusCode	sysStart () override
	Handle START transition.
virtual std::vector< Gaudi::DataHandle * >	inputHandles () const override
	Return this algorithm's input handles.
virtual std::vector< Gaudi::DataHandle * >	outputHandles () const override
	Return this algorithm's output handles.
Gaudi::Details::PropertyBase &	declareProperty (Gaudi::Property< T, V, H > &t)
void	updateVHKA (Gaudi::Details::PropertyBase &)
MsgStream &	msg () const
bool	msgLvl (const MSG::Level lvl) const

Public Attributes
	flags = initConfigFlags()
	parser = flags.getArgumentParser()
	help
	default
	dest
	nargs
	type
	int
	args
list	fragIDs = [int(fragID, base=16) for fragID in args.fragIDs]
	Files
	AtlasVersion
	HISTFileName
	useTrigger
	enableLumiAccess
	MaxEvents
	isOnline
	doFit
	useDCS
	NoiseFilter
	correctTime
	correctTimeJumps
	BestPhaseFromCOOL
	doOverflowFit
	RawChannelContainer
	pattern
	evaluate
	cfg = MainServicesCfg(flags)
	rawChannels = args.channels
	cells = args.cells
str	readDigitsFlx = 'Flx' in args.digits
	rawChMaker = cfg.getEventAlgo('TileRChMaker')
	Cardinality
str	cells = 'AllCalo'
	tileInfoLoader = cfg.getService('TileInfoLoader')
	NSamples
	TrigSample
	withDetails
	True
	summariseProps
	sc = cfg.run()

Protected Member Functions
void	renounceArray (SG::VarHandleKeyArray &handlesArray)
	remove all handles from I/O resolution
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.

Protected Attributes
	_
ToolHandleArray< GenericMonitoringTool >	m_tools {this,"GMTools",{}}
	Array of Generic Monitoring Tools.
PublicToolHandle< Trig::TrigDecisionTool >	m_trigDecTool
	Tool to tell whether a specific trigger is passed.
ToolHandleArray< IDQFilterTool >	m_DQFilterTools {this,"FilterTools",{}}
	Array of Data Quality filter tools.
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.
AthMonitorAlgorithm::DataType_t	m_dataType
	Instance of the DataType_t enum.
Gaudi::Property< std::string >	m_environmentStr {this,"Environment","user"}
	Environment string pulled from the job option and converted to enum.
Gaudi::Property< std::string >	m_dataTypeStr {this,"DataType","userDefined"}
	DataType string pulled from the job option and converted to enum.
Gaudi::Property< std::string >	m_triggerChainString {this,"TriggerChain",""}
	Trigger chain string pulled from the job option and parsed into a vector.
std::vector< std::string >	m_vTrigChainNames
	Vector of trigger chain names parsed from trigger chain string.
Gaudi::Property< std::string >	m_fileKey {this,"FileKey",""}
	Internal Athena name for file.
Gaudi::Property< bool >	m_useLumi {this,"EnableLumi",false}
	Allows use of various luminosity functions.
Gaudi::Property< float >	m_defaultLBDuration {this,"DefaultLBDuration",60.}
	Default duration of one lumi block.
Gaudi::Property< int >	m_detailLevel {this,"DetailLevel",0}
	Sets the level of detail used in the monitoring.
SG::ReadHandleKey< xAOD::EventInfo >	m_EventInfoKey {this,"EventInfoKey","EventInfo"}
	Key for retrieving EventInfo from StoreGate.

Private Types
enum	BEAM_ELEMENTS_NUMBER {   N_S_COUNTER = 3 , N_CHERENKOV = 3 , N_TOF = 3 , N_SCALER = 3 ,   N_MUON_WALL_PMT = 12 , N_TDC_CHANNELS = 16 }
typedef std::vector< std::reference_wrapper< Monitored::IMonitoredVariable > >	MonVarVec_t
typedef ServiceHandle< StoreGateSvc >	StoreGateSvc_t

Private Member Functions
void	errorWrongChannel (int frag, int channel) const
Gaudi::Details::PropertyBase &	declareGaudiProperty (Gaudi::Property< T, V, H > &hndl, const SG::VarHandleKeyType &)
	specialization for handling Gaudi::Property<SG::VarHandleKey>

Private Attributes
SG::ReadHandleKey< TileBeamElemContainer >	m_beamElemContainerKey
ServiceHandle< TileCablingSvc >	m_cablingSvc
	Name of Tile cabling service.
Gaudi::Property< std::vector< int > >	m_fragIDs
Gaudi::Property< int >	m_TBperiod
Gaudi::Property< double >	m_bc1HorizontalSlope
Gaudi::Property< double >	m_bc1HorizontalOffset
Gaudi::Property< double >	m_bc1VerticalSlope
Gaudi::Property< double >	m_bc1VerticalOffset
Gaudi::Property< double >	m_bc2HorizontalSlope
Gaudi::Property< double >	m_bc2HorizontalOffset
Gaudi::Property< double >	m_bc2VerticalSlope
Gaudi::Property< double >	m_bc2VerticalOffset
Gaudi::Property< double >	m_beamBC1Z
Gaudi::Property< double >	m_beamBC2Z
SG::ReadHandleKey< CaloCellContainer >	m_caloCellContainerKey
Gaudi::Property< std::vector< std::string > >	m_masked
Gaudi::Property< std::vector< unsigned int > >	m_maskMuonPMTs
Gaudi::Property< std::vector< std::pair< int, int > > >	m_tofPairs
std::vector< int >	m_tofGroups
std::vector< int >	m_tofDiffGroups
std::vector< int >	m_sCounterGroups
std::vector< int >	m_cherenkovGroups
std::vector< int >	m_scalerGroups
std::vector< int >	m_muonWallGroups
std::vector< int >	m_cherenkovVsEnergyGroups
std::map< std::string, int >	m_beamChamberGroups
std::vector< std::vector< int > >	m_cherenkovVsTOFGroups
const TileHWID *	m_tileID {nullptr}
const TileHWID *	m_tileHWID {nullptr}
std::array< bool, TileCalibUtils::MAX_DRAWERIDX >	m_monitoredDrawerIdx {}
std::array< bool, N_MUON_WALL_PMT >	m_maskedMuPMTs = {}
std::array< std::array< unsigned char, TileCalibUtils::MAX_CHAN >, TileCalibUtils::MAX_DRAWERIDX >	m_maskedChannels = {{}}
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.
StoreGateSvc_t	m_evtStore
	Pointer to StoreGate (event store by default)
StoreGateSvc_t	m_detStore
	Pointer to StoreGate (detector store by default)
std::vector< SG::VarHandleKeyArray * >	m_vhka
bool	m_varHandleArraysDeclared

Detailed Description

Class for Tile TB Beam elements based monitoring.

Definition at line 25 of file TileTBBeamMonitorAlgorithm.h.

Member Typedef Documentation

MonVarVec_t

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

privateinherited

Definition at line 370 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

BEAM_ELEMENTS_NUMBER

enum TileTBBeamMonitorAlgorithm::BEAM_ELEMENTS_NUMBER

private

Enumerator
N_S_COUNTER
N_CHERENKOV
N_TOF
N_SCALER
N_MUON_WALL_PMT
N_TDC_CHANNELS

Definition at line 106 of file TileTBBeamMonitorAlgorithm.h.

{N_S_COUNTER = 3, N_CHERENKOV = 3, N_TOF = 3, N_SCALER = 3, N_MUON_WALL_PMT = 12, N_TDC_CHANNELS = 16};

DataType_t

enum class 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 194 of file AthMonitorAlgorithm.h.

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

Environment_t

enum class 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 175 of file AthMonitorAlgorithm.h.

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

Constructor & Destructor Documentation

~TileTBBeamMonitorAlgorithm()

virtual TileTBBeamMonitorAlgorithm::~TileTBBeamMonitorAlgorithm ( )

virtualdefault

Member Function Documentation

AthMonitorAlgorithm()

AthMonitorAlgorithm::AthMonitorAlgorithm	(	const std::string &	name,
		ISvcLocator *	pSvcLocator )

Constructor.

Definition at line 45 of file AthMonitorAlgorithm.cxx.

:AthReentrantAlgorithm(name,pSvcLocator)
 // Put this here rather than in the header to allow forward-declaring
 // TrigDecisionTool.
,m_trigDecTool{this, "TrigDecisionTool",""}
,m_environment(Environment_t::user)
,m_dataType(DataType_t::userDefined)
,m_vTrigChainNames({})
{}

cardinality()

unsigned int AthCommonReentrantAlgorithm< Gaudi::Algorithm >::cardinality ( ) const

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.

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 224 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 144 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()

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());
 
  }

declareProperty()

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 208 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 116 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;
    }
}

errorWrongChannel()

void TileTBBeamMonitorAlgorithm::errorWrongChannel ( int frag, int channel ) const

private

Definition at line 557 of file TileTBBeamMonitorAlgorithm.cxx.

                                                                              {
  ATH_MSG_ERROR("Wrong channel " << channel
                << " in frag 0x" << MSG::hex << frag << MSG::dec
                << " - " << BeamFragName[frag & 0x1F]);
}

evtStore()

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; }

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 77 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 ( ) const

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 TileTBBeamMonitorAlgorithm::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 AthMonitorAlgorithm.

Definition at line 127 of file TileTBBeamMonitorAlgorithm.cxx.

                                                                                     {
 
  // In case you want to measure the execution time
  auto timer = Monitored::Timer("TIME_execute");
 
  uint32_t run = GetEventInfo(ctx)->runNumber();
 
  // TDC/BEAM Items
  int muTag = 0;
  int muHalo = 0;
  int muVeto = 0;
 
  std::vector<std::reference_wrapper<int>> mu{muTag, muHalo, muVeto};
 
  int sCounter[N_S_COUNTER] = {0};
  int cherenkov[N_CHERENKOV] = {0};
  int scaler[N_SCALER] = {0};
  int scaler12 = 0;
 
  // MUON/MuWall
  float muonWall[N_MUON_WALL_PMT] = {0};
 
  int tof[N_TDC_CHANNELS] = {0};
  int btdc[N_TDC_CHANNELS] = {0};
  for (int i = 0; i < N_TDC_CHANNELS; i += 2) {
    btdc[i] = +0xFFFF;
    btdc[i+1] = -0xFFFF;
  }
  int btdcHitsN[N_TDC_CHANNELS] = {0};
 
  double totalMuonWallEnergy = 0;
 
  SG::ReadHandle<TileBeamElemContainer> beamElemContainer(m_beamElemContainerKey, ctx);
  ATH_CHECK( beamElemContainer.isValid() );
 
  ATH_MSG_VERBOSE("TileRawDataContainer of TileRawDataCollection of TileBeamElem size = " << beamElemContainer->size());
 
  for (const TileBeamElemCollection* beamElemCollection : *beamElemContainer) {
 
    // Retreive frag identifiers
    int frag = beamElemCollection->identify();
    ATH_MSG_VERBOSE("TileRawDataCollection of TileBeamElem Id = 0x" << MSG::hex << frag << MSG::dec
                    << " size = " << beamElemCollection->size());
 
    for (const TileBeamElem* beamElement : *beamElemCollection) {
 
      ATH_MSG_VERBOSE((std::string) *beamElement);
 
      HWIdentifier id = beamElement->adc_HWID();
      std::vector<uint32_t> digits = beamElement->get_digits();
      int channel = m_tileHWID->channel(id);
      int nDigits = digits.size();
 
      if ( nDigits <= 0 ) {
        ATH_MSG_ERROR("Wrong no. of samples (" << nDigits
                      << ") for channel " << channel
                      << " in frag 0x"<< MSG::hex << frag << MSG::dec
                      << " - " << BeamFragName[frag & 0x1F]);
      } else {
 
        int amplitude = digits[0];
 
        ATH_MSG_DEBUG("Found channel " << channel
                      << " in frag 0x" << MSG::hex << frag << MSG::dec
                      << " - " << BeamFragName[frag & 0x1F]
                      << " with amp=" << amplitude);
 
        switch (frag) {
 
        case MUON_ADC_FRAG:
 
          if(channel >= 0 && channel < 8) {
            muonWall[channel] = amplitude;
            if (!m_maskedMuPMTs[channel]) {
              totalMuonWallEnergy += amplitude;
            }
          } else {
            errorWrongChannel(frag, channel);
          }
 
          break;
 
        case ADDR_ADC_FRAG:
 
          if(channel >= 0 && channel < 6) {
            if (8 + channel < N_MUON_WALL_PMT) {
              muonWall[8 + channel] = amplitude;
              if (!m_maskedMuPMTs[8 + channel]) {
                totalMuonWallEnergy += amplitude;
              }
            }
          } else {
            errorWrongChannel(frag, channel);
          }
 
          break;
 
        case COMMON_TOF_FRAG:
          if (m_TBperiod >= 2022) {
            // The first channels are connected to BC1 and BC2, the last 4 channels are supposed to be TOF
            if (channel > 11) {
              if(channel < 16) {
                tof[channel] = amplitude;
                ATH_MSG_VERBOSE( "TOF: " << channel << " amp: " << amplitude);
              } else {
                errorWrongChannel(frag, channel);
              }
              break;
            }
            // Fall through to case COMMON_TDC1_FRAG to unpack the first channels of BC1 and BC2
            [[fallthrough]]; // silent the warning on fall through
          } else {
            break;
          }
        case COMMON_TDC1_FRAG:
 
          if ((channel > 11) && (channel < 16) && (run > 2211136)) {
            tof[channel] = amplitude;
            ATH_MSG_VERBOSE( "TOF: " << channel << " amp: " << amplitude);
          } else if (channel < 16) {
            if (m_TBperiod >= 2021) {
              if (btdcHitsN[channel] == 0) {
                btdc[channel] = amplitude;
                ++(btdcHitsN[channel]);
              }
            } else {
              btdc[channel] = amplitude;
            }
          } else errorWrongChannel(frag, channel);
          break;
 
        case BEAM_ADC_FRAG:
 
          if (channel >= 0 && channel < 8) {
            if (channel < 3) {
              sCounter[channel] = amplitude;
            } else if (channel < 5) {
              cherenkov[channel - 3] = amplitude;
            } else {
              mu[channel - 5] = amplitude;
            }
          } else {
            errorWrongChannel(frag, channel);
          }
          break;
 
 
        case COMMON_ADC1_FRAG:
 
          if (run > 2211444) {
 
            if (channel >= 0 && channel < 16) {
              if (channel < 2) {
                sCounter[channel] = amplitude;
              } else if (channel == 2) {
                // Before run #2310000 channel 2 was connected to PMT11 of muon wall.
                // After this run this channel was connected to S3 scintillator.
                if (run < 2310000) {
                  muonWall[10] = amplitude;
                  if (!m_maskedMuPMTs[10]) {
                    totalMuonWallEnergy += amplitude;
                  }
                } else {
                  sCounter[2] = amplitude;
                }
              } else if (channel < 6) {
                cherenkov[channel - 3] = amplitude;
              } else {
                muonWall[channel - 6] = amplitude;
                if (!m_maskedMuPMTs[channel - 6]) {
                  totalMuonWallEnergy += amplitude;
                }
              }
            } else {
              errorWrongChannel(frag, channel);
            }
 
            break;
 
          } else {
 
            if (channel >= 0 && channel < 16) {
              if (channel < 3) {
                sCounter[channel] = amplitude;
              } else if (channel < 6) {
                cherenkov[channel - 3] = amplitude;
              }
            } else {
              errorWrongChannel(frag, channel);
            }
 
            break;
          }
 
 
        case COMMON_ADC2_FRAG:
 
          if (run < 2211445) {
 
            if(channel >= 0 && channel < N_MUON_WALL_PMT) {
              muonWall[channel] = amplitude;
              if (!m_maskedMuPMTs[channel]) {
                totalMuonWallEnergy += amplitude;
              }
            } else if (channel > 31) {
              errorWrongChannel(frag, channel);
            }
          }
          break;
 
        case COMMON_PTN_FRAG:
          if (run > 2310000 && channel < 16) {
            if (channel < N_SCALER) {
              scaler[channel] = amplitude;
            } else if (channel == N_SCALER) {
              scaler12 = amplitude;
            }
          } else {
            errorWrongChannel(frag, channel);
          }
          break;
        }
      }
    }
  }
 
  auto  monTotalMuonEnergy = Monitored::Scalar<double>("TotalMuonEnergy", totalMuonWallEnergy);
  fill("TileTBTotalMuonEnergy", monTotalMuonEnergy);
 
  std::vector<int> counterToTOF{14,15,13};
  for (int counter = 0; counter < N_TOF; ++counter) {
    auto monAmplitude = Monitored::Scalar<double>("amplitude", tof[counterToTOF[counter]]);
    fill(m_tools[m_tofGroups[counter]], monAmplitude);
  }
 
  for (unsigned int pairIdx = 0; pairIdx < m_tofPairs.size(); ++pairIdx) {
    const std::pair<int, int>& tofPair = m_tofPairs[pairIdx];
    int tof1 = tof[counterToTOF[tofPair.first - 1]];
    int tof2 = tof[counterToTOF[tofPair.second - 1]];
    if (tof1 != 0 && tof2 != 0) {
      auto monTOFDiff = Monitored::Scalar<double>("TOFDiff", tof1 - tof2);
      fill(m_tools[m_tofDiffGroups[pairIdx]], monTOFDiff);
    }
  }
 
  for (int counter = 0; counter < N_S_COUNTER; ++counter) {
    auto monAmplitude = Monitored::Scalar<double>("amplitude", sCounter[counter]);
    fill(m_tools[m_sCounterGroups[counter]], monAmplitude);
  }
 
  for (int counter = 0; counter < N_CHERENKOV; ++counter) {
    auto monAmplitude = Monitored::Scalar<double>("amplitude", cherenkov[counter]);
    fill(m_tools[m_cherenkovGroups[counter]], monAmplitude);
  }
 
  auto monCherenkovAmplitude1 = Monitored::Scalar<double>("amplitude1", cherenkov[0]);
  auto monCherenkovAmplitude2 = Monitored::Scalar<double>("amplitude2", cherenkov[1]);
  fill("CherCompare", monCherenkovAmplitude1, monCherenkovAmplitude2);
 
  for (int tofCounter = 0; tofCounter < N_TOF; ++tofCounter) {
    auto monAmplitudeTOF = Monitored::Scalar<double>("amplitudeTOF", tof[counterToTOF[tofCounter]]);
    for (int cherenkovCounter = 0; cherenkovCounter < N_CHERENKOV; ++cherenkovCounter) {
      auto monAmplitudeCherenkov = Monitored::Scalar<double>("amplitudeCherenkov", cherenkov[cherenkovCounter]);
      fill(m_tools[m_cherenkovVsTOFGroups[tofCounter][cherenkovCounter]], monAmplitudeTOF, monAmplitudeCherenkov);
    }
  }
 
 
  if (run > 2310000) {
    for (int counter = 0; counter < N_SCALER; ++counter) {
      auto monCounts = Monitored::Scalar<double>("counts", scaler[counter]);
      fill(m_tools[m_scalerGroups[counter]], monCounts);
    }
    auto monCounts12 = Monitored::Scalar<double>("counts12", scaler12);
    fill("Scaler12", monCounts12);
  }
 
  for (int pmt = 0; pmt < N_MUON_WALL_PMT; ++pmt) {
    auto monAmplitude = Monitored::Scalar<double>("amplitude", muonWall[pmt]);
    fill(m_tools[m_muonWallGroups[pmt]], monAmplitude);
  }
 
  for (int row = 0; row < 2; ++row) {
    for (int column = 0; column < 4; ++column) {
      auto monRow = Monitored::Scalar<double>("row", row);
      auto monColumn = Monitored::Scalar<double>("column", column);
      auto monAmplitude = Monitored::Scalar<double>("amplitude", muonWall[7 - (row * 4 + column)]);
      fill("PMTHitMap", monColumn, monRow, monAmplitude);
    }
  }
 
  // Beam Chamber Coordinates
  // For BC1
  auto bc1X = Monitored::Scalar<double>("BC1X", 0.);
  auto bc1Y = Monitored::Scalar<double>("BC1Y", 0.);
  if (run > 2211444) {
    bc1X = (btdc[8] - btdc[0]) * m_bc1HorizontalSlope + m_bc1HorizontalOffset; // (right - left)
    bc1Y = (btdc[9] - btdc[3]) * m_bc1VerticalSlope + m_bc1VerticalOffset; // (up - down)
  } else {
    bc1X = (btdc[1] - btdc[0]) * m_bc1HorizontalSlope + m_bc1HorizontalOffset;  // (right - left)
    bc1Y = (btdc[2] - btdc[3]) * m_bc1VerticalSlope + m_bc1VerticalOffset; // (up - down)
  }
  fill(m_tools[m_beamChamberGroups.at("BC1")], bc1X, bc1Y);
 
  // For BC2:
  auto bc2X = Monitored::Scalar<double>("BC2X", (btdc[5] - btdc[4]) * m_bc2HorizontalSlope + m_bc2HorizontalOffset); // (right - left)
  auto bc2Y = Monitored::Scalar<double>("BC2Y", (btdc[6] - btdc[7]) * m_bc2VerticalSlope + m_bc2VerticalOffset); // (up - down)
  fill(m_tools[m_beamChamberGroups.at("BC2")], bc2X, bc2Y);
 
  // Sum Plots
  // For BC1
  auto bc1Xsum = Monitored::Scalar<double>("BC1Xsum", 0.);
  auto bc1Ysum = Monitored::Scalar<double>("BC1Ysum", 0.);;
  if (run > 2211444) {
    bc1Xsum =(btdc[8] + btdc[0]) * m_bc1HorizontalSlope + m_bc1HorizontalOffset;
    bc1Ysum = (btdc[9] + btdc[3]) * m_bc1VerticalSlope + m_bc1VerticalOffset;
  } else {
    bc1Xsum = (btdc[1] + btdc[0]) * m_bc1HorizontalSlope + m_bc1HorizontalOffset;
    bc1Ysum = (btdc[2] + btdc[3]) * m_bc1VerticalSlope + m_bc1VerticalOffset;
  }
  fill(m_tools[m_beamChamberGroups.at("BC1")], bc1Xsum, bc1Ysum);
 
  //For BC2
  auto bc2Xsum = Monitored::Scalar<double>("BC2Xsum", (btdc[5] + btdc[4]) * m_bc2HorizontalSlope + m_bc2HorizontalOffset);
  auto bc2Ysum = Monitored::Scalar<double>("BC2Ysum", (btdc[6] + btdc[7]) * m_bc2VerticalSlope + m_bc2VerticalOffset);
  fill(m_tools[m_beamChamberGroups.at("BC2")], bc2Xsum, bc2Ysum);
 
  //Impact Coordinates
  // For one cell, plot energy total as a function of x Impact -- (xImp, cell_energy)...
  auto xImp = Monitored::Scalar<double>("Ximp", bc2X + (bc2X - bc1X) * m_beamBC2Z / (m_beamBC1Z - m_beamBC2Z));
  auto yImp = Monitored::Scalar<double>("Yimp", bc2Y + (bc2Y - bc1Y) * m_beamBC2Z / (m_beamBC1Z - m_beamBC2Z));
  fill("ImpactProfile", xImp, yImp);
 
 
  if (!m_caloCellContainerKey.empty()) {
 
    SG::ReadHandle<CaloCellContainer> caloCellContainer(m_caloCellContainerKey, ctx);
    ATH_CHECK( caloCellContainer.isValid() );
 
    if (!caloCellContainer->empty()) {
 
      double cellEnergy = 0;
      double totalEnergy(0.0);
 
      for (const CaloCell* cell : *caloCellContainer) {
        if (m_tileID->is_tile(cell->ID())) {
          const TileCell* tile_cell = dynamic_cast<const TileCell*>(cell);
          if (!tile_cell) continue;
 
          const CaloDetDescrElement* caloDDE = cell->caloDDE();
 
          IdentifierHash hash1 = caloDDE->onl1();
          IdentifierHash hash2 = caloDDE->onl2();
 
          double energy = 0.0;
 
          int gain1 = tile_cell->gain1();
 
          HWIdentifier channelId1 = m_tileHWID->channel_id(hash1);
 
          int ros1 = m_tileHWID->ros(channelId1);
          int drawer1 = m_tileHWID->drawer(channelId1);
          int channel1 = m_tileHWID->channel(channelId1);
          int drawerIdx1 = TileCalibUtils::getDrawerIdx(ros1, drawer1);
 
          if (hash2 == TileHWID::NOT_VALID_HASH) {
            if (m_monitoredDrawerIdx[drawerIdx1]) {
              if (gain1 >= 0 && !((m_maskedChannels[drawerIdx1][channel1] >> gain1) & 1U)) {
                energy = cell->energy();
              }
            }
          } else {
 
            int gain2 = tile_cell->gain2();
 
            HWIdentifier channelId2 = m_tileHWID->channel_id(hash2);
 
            int ros2 = m_tileHWID->ros(channelId2);
            int drawer2 = m_tileHWID->drawer(channelId2);
            int channel2 = m_tileHWID->channel(channelId2);
            int drawerIdx2 = TileCalibUtils::getDrawerIdx(ros2, drawer2);
 
            if (m_monitoredDrawerIdx[drawerIdx1] || m_monitoredDrawerIdx[drawerIdx2]) {
              if (gain1 < 0 || ((m_maskedChannels[drawerIdx1][channel1] >> gain1) & 1U)) {
                if (gain2 >= 0 && !((m_maskedChannels[drawerIdx2][channel2] >> gain2) & 1U)) {
                  energy = tile_cell->ene2() * 2;
                }
              } else if (gain2 >= 0 && ((m_maskedChannels[drawerIdx2][channel2] >> gain2) & 1U)) {
                if (gain1 >= 0 && !((m_maskedChannels[drawerIdx1][channel1] >> gain1) & 1U)) {
                  energy = tile_cell->ene1() * 2;
                }
              } else {
                energy = cell->energy();
              }
            }
          }
 
          double energy_pC = energy * 0.001; // keep energy in pC;
          totalEnergy += energy_pC;
 
          if (energy_pC > cellEnergy)  {
            cellEnergy = energy_pC;
          }
        }
      }
 
      auto monCellEnergy = Monitored::Scalar<double>("cellEnergy", cellEnergy);
      auto monTotalEnergy = Monitored::Scalar<double>("totalEnergy", totalEnergy);
 
      for (int counter = 0; counter < N_CHERENKOV; ++counter) {
        auto monAmplitude = Monitored::Scalar<double>("amplitude", cherenkov[counter]);
        fill(m_tools[m_cherenkovVsEnergyGroups[counter]], monTotalEnergy, monAmplitude);
      }
 
      fill("CellEnergyImpactX", xImp, monCellEnergy);
      fill("CellEnergyImpactY", yImp, monCellEnergy);
      fill("TotalEnergyImpactX", xImp, monTotalEnergy);
      fill("TotalEnergyImpactY", yImp, monTotalEnergy);
 
      auto monAmplitudeS1 = Monitored::Scalar<double>("amplitude", sCounter[0]);
      fill("ScinCalEnergy", monAmplitudeS1, monTotalEnergy);
    }
  }
 
  fill("TileTBBeamMonExecuteTime", 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 111 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 168 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 198 of file AthMonitorAlgorithm.cxx.

                                                                                       {
    return m_trigDecTool;
}

initialize()

StatusCode TileTBBeamMonitorAlgorithm::initialize ( )

overridevirtual

initialize

Returns

StatusCode

Reimplemented from AthMonitorAlgorithm.

Definition at line 16 of file TileTBBeamMonitorAlgorithm.cxx.

                                                  {
 
  ATH_MSG_INFO("in initialize()");
  ATH_CHECK( AthMonitorAlgorithm::initialize() );
 
  ATH_CHECK( m_beamElemContainerKey.initialize() );
  ATH_CHECK( m_caloCellContainerKey.initialize(SG::AllowEmpty) );
 
  ATH_CHECK( m_cablingSvc.retrieve() );
  ATH_CHECK( detStore()->retrieve(m_tileID) );
  ATH_CHECK( detStore()->retrieve(m_tileHWID) );
 
  std::vector<std::string> modules;
  for (int fragID : m_fragIDs) {
    int ros = fragID >> 8;
    int drawer = fragID & 0x3F;
    modules.push_back(TileCalibUtils::getDrawerString(ros, drawer));
    m_monitoredDrawerIdx[TileCalibUtils::getDrawerIdx(ros, drawer)] = true;
  }
 
  std::ostringstream os;
  if ( m_fragIDs.size() != 0) {
    std::sort(m_fragIDs.begin(), m_fragIDs.end());
    for (int fragID : m_fragIDs) {
      unsigned int ros    = fragID >> 8;
      unsigned int drawer = fragID & 0xFF;
      std::string module = TileCalibUtils::getDrawerString(ros, drawer);
      os << " " << module << "/0x" << std::hex << fragID << std::dec;
    }
  } else {
    os << "NONE";
  }
 
  ATH_MSG_INFO("Monitored modules/frag ID:" << os.str());
 
 
  std::map<std::string, unsigned int> roses = { {"AUX", 0}, {"LBA", 1}, {"LBC", 2}, {"EBA", 3}, {"EBC", 4} };
  for (const std::string& maskedModuleChannels : m_masked) {
 
    std::string module = maskedModuleChannels.substr(0, 5);
    std::string partition = module.substr(0, 3);
    if (roses.count(partition) != 1) {
      ATH_MSG_WARNING("There no such partition: " << partition << " in module: " << module
              << " => skip because of bad format: " << maskedModuleChannels);
      continue;
    }
 
    unsigned int drawer = std::stoi(module.substr(3, 2)) - 1;
    if (drawer >= TileCalibUtils::MAX_DRAWER) {
      ATH_MSG_WARNING("There no such drawer: " << drawer + 1 << " in module: " << module
              << " => skip because of bad format: " << maskedModuleChannels);
      continue;
    }
 
    unsigned int ros = roses.at(partition);
    unsigned int drawerIdx = TileCalibUtils::getDrawerIdx(ros, drawer);
 
    std::string gain = maskedModuleChannels.substr(5,7);
    unsigned int adc = std::stoi(gain);
 
    if (adc >= TileCalibUtils::MAX_GAIN) {
      ATH_MSG_WARNING("There no such gain: " << gain << " => skip because of bad format: " << maskedModuleChannels);
      continue;
    }
 
    std::stringstream channels(maskedModuleChannels.substr(7));
    std::string channel;
    while (std::getline(channels, channel, ',')) {
      if (!channel.empty()) {
        unsigned int chan = std::stoi(channel);
        if (chan >= TileCalibUtils::MAX_CHAN) {
          ATH_MSG_WARNING("There no such channel: " << chan << " in channels: " << channels.str()
                          << " => skip because of bad format: " << maskedModuleChannels);
          continue;
        }
        m_maskedChannels[drawerIdx][chan] |= (1U << adc);
        ATH_MSG_INFO(TileCalibUtils::getDrawerString(ros, drawer) << " ch" << chan << (adc ? " HG" : " LG") << ": masked!");
      }
    }
 
  }
 
  for (unsigned int pmt : m_maskMuonPMTs) {
    if (pmt < m_maskedMuPMTs.size()) {
      m_maskedMuPMTs[pmt] = true;
      ATH_MSG_INFO("Masking Muon Wall PMT: " << pmt);
    }
  }
 
  using namespace Monitored;
 
  m_tofGroups = buildToolMap<int>(m_tools, "TOF", N_TOF);
  m_tofDiffGroups = buildToolMap<int>(m_tools, "TOFDiff", m_tofPairs.size());
  m_sCounterGroups = buildToolMap<int>(m_tools, "Scounter", N_S_COUNTER);
  m_cherenkovGroups = buildToolMap<int>(m_tools, "Cherenkov", N_CHERENKOV);
  m_scalerGroups = buildToolMap<int>(m_tools, "Scaler", N_SCALER);
  m_muonWallGroups = buildToolMap<int>(m_tools, "MuonWallPMT", N_MUON_WALL_PMT);
 
  m_cherenkovVsTOFGroups = buildToolMap<std::vector<int>>(m_tools, "CherenkovVsTOF", N_TOF, N_CHERENKOV);
 
  std::vector<std::string> beamChambers{"BC1", "BC2"};
  m_beamChamberGroups = buildToolMap<int>(m_tools, "BeamChamber", beamChambers);
 
  if (!m_caloCellContainerKey.empty()) {
    m_cherenkovVsEnergyGroups = buildToolMap<int>(m_tools, "CherenkovVsEnergy", N_CHERENKOV);
  }
 
  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 ( ) const

overridevirtualinherited

Specify if the algorithm is clonable.

Reentrant algorithms are clonable.

Reimplemented in InDet::GNNSeedingTrackMaker, InDet::SCT_Clusterization, InDet::SiSPGNNTrackMaker, InDet::SiSPSeededTrackFinder, InDet::SiTrackerSpacePointFinder, ITkPixelCablingAlg, ITkStripCablingAlg, RoIBResultToxAOD, SCT_ByteStreamErrorsTestAlg, SCT_CablingCondAlgFromCoraCool, SCT_CablingCondAlgFromText, SCT_ConditionsParameterTestAlg, SCT_ConditionsSummaryTestAlg, SCT_ConfigurationConditionsTestAlg, SCT_FlaggedConditionTestAlg, SCT_LinkMaskingTestAlg, SCT_MajorityConditionsTestAlg, SCT_ModuleVetoTestAlg, SCT_MonitorConditionsTestAlg, SCT_PrepDataToxAOD, SCT_RawDataToxAOD, SCT_ReadCalibChipDataTestAlg, SCT_ReadCalibDataTestAlg, SCT_RODVetoTestAlg, SCT_SensorsTestAlg, SCT_SiliconConditionsTestAlg, SCT_StripVetoTestAlg, SCT_TdaqEnabledTestAlg, SCT_TestCablingAlg, SCTEventFlagWriter, SCTRawDataProvider, SCTSiLorentzAngleTestAlg, SCTSiPropertiesTestAlg, and Simulation::BeamEffectsAlg.

Definition at line 68 of file AthCommonReentrantAlgorithm.cxx.

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

msg()

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

inlineinherited

Definition at line 24 of file AthCommonMsg.h.

                                {
    return this->msgStream();
  }

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 345 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 HypoBase, and InputMakerBase.

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.

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 203 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

_

TileTBBeamMonitorAlgorithm._

protected

Definition at line 249 of file TileTBBeamMonitorAlgorithm.py.

args

TileTBBeamMonitorAlgorithm.args

Definition at line 249 of file TileTBBeamMonitorAlgorithm.py.

AtlasVersion

TileTBBeamMonitorAlgorithm.AtlasVersion

Definition at line 254 of file TileTBBeamMonitorAlgorithm.py.

BestPhaseFromCOOL

TileTBBeamMonitorAlgorithm.BestPhaseFromCOOL

Definition at line 266 of file TileTBBeamMonitorAlgorithm.py.

Cardinality

TileTBBeamMonitorAlgorithm.Cardinality

Definition at line 302 of file TileTBBeamMonitorAlgorithm.py.

cells [1/2]

TileTBBeamMonitorAlgorithm.cells = args.cells

Definition at line 282 of file TileTBBeamMonitorAlgorithm.py.

cells [2/2]

str TileTBBeamMonitorAlgorithm.cells = 'AllCalo'

Definition at line 312 of file TileTBBeamMonitorAlgorithm.py.

cfg

TileTBBeamMonitorAlgorithm.cfg = MainServicesCfg(flags)

Definition at line 279 of file TileTBBeamMonitorAlgorithm.py.

correctTime

TileTBBeamMonitorAlgorithm.correctTime

Definition at line 264 of file TileTBBeamMonitorAlgorithm.py.

correctTimeJumps

TileTBBeamMonitorAlgorithm.correctTimeJumps

Definition at line 265 of file TileTBBeamMonitorAlgorithm.py.

default

TileTBBeamMonitorAlgorithm.default

Definition at line 238 of file TileTBBeamMonitorAlgorithm.py.

dest

TileTBBeamMonitorAlgorithm.dest

Definition at line 243 of file TileTBBeamMonitorAlgorithm.py.

doFit

TileTBBeamMonitorAlgorithm.doFit

Definition at line 261 of file TileTBBeamMonitorAlgorithm.py.

doOverflowFit

TileTBBeamMonitorAlgorithm.doOverflowFit

Definition at line 267 of file TileTBBeamMonitorAlgorithm.py.

enableLumiAccess

TileTBBeamMonitorAlgorithm.enableLumiAccess

Definition at line 257 of file TileTBBeamMonitorAlgorithm.py.

evaluate

TileTBBeamMonitorAlgorithm.evaluate

Definition at line 275 of file TileTBBeamMonitorAlgorithm.py.

Files

TileTBBeamMonitorAlgorithm.Files

Definition at line 253 of file TileTBBeamMonitorAlgorithm.py.

flags

TileTBBeamMonitorAlgorithm.flags = initConfigFlags()

Definition at line 235 of file TileTBBeamMonitorAlgorithm.py.

fragIDs

list TileTBBeamMonitorAlgorithm.fragIDs = [int(fragID, base=16) for fragID in args.fragIDs]

Definition at line 251 of file TileTBBeamMonitorAlgorithm.py.

help

TileTBBeamMonitorAlgorithm.help

Definition at line 237 of file TileTBBeamMonitorAlgorithm.py.

HISTFileName

TileTBBeamMonitorAlgorithm.HISTFileName

Definition at line 255 of file TileTBBeamMonitorAlgorithm.py.

int

TileTBBeamMonitorAlgorithm.int

Definition at line 245 of file TileTBBeamMonitorAlgorithm.py.

isOnline

TileTBBeamMonitorAlgorithm.isOnline

Definition at line 259 of file TileTBBeamMonitorAlgorithm.py.

m_bc1HorizontalOffset

Gaudi::Property<double> TileTBBeamMonitorAlgorithm::m_bc1HorizontalOffset

private

Initial value:

{this,
        "BC1HorizontalOffset", 0.181797 + 0.5, "BC1 horizontal offset."}

Definition at line 57 of file TileTBBeamMonitorAlgorithm.h.

                                               {this,
        "BC1HorizontalOffset", 0.181797 + 0.5, "BC1 horizontal offset."};

m_bc1HorizontalSlope

Gaudi::Property<double> TileTBBeamMonitorAlgorithm::m_bc1HorizontalSlope

private

Initial value:

{this,
        "BC1HorizontalSlope", -0.175657, "BC1 horizontal slope."}

Definition at line 54 of file TileTBBeamMonitorAlgorithm.h.

                                              {this,
        "BC1HorizontalSlope", -0.175657, "BC1 horizontal slope."};

m_bc1VerticalOffset

Gaudi::Property<double> TileTBBeamMonitorAlgorithm::m_bc1VerticalOffset

private

Initial value:

{this,
        "BC1VerticalOffset", -0.128910 - 1.9, "BC1 vertical offset."}

Definition at line 63 of file TileTBBeamMonitorAlgorithm.h.

                                             {this,
        "BC1VerticalOffset", -0.128910 - 1.9, "BC1 vertical offset."};

m_bc1VerticalSlope

Gaudi::Property<double> TileTBBeamMonitorAlgorithm::m_bc1VerticalSlope

private

Initial value:

{this,
        "BC1VerticalSlope", -0.175965, "BC1 vertical slope."}

Definition at line 60 of file TileTBBeamMonitorAlgorithm.h.

                                            {this,
        "BC1VerticalSlope", -0.175965, "BC1 vertical slope."};

m_bc2HorizontalOffset

Gaudi::Property<double> TileTBBeamMonitorAlgorithm::m_bc2HorizontalOffset

private

Initial value:

{this,
        "BC2HorizontalOffset", 0.622896039922 - 25., "BC2 horizontal offset."}

Definition at line 69 of file TileTBBeamMonitorAlgorithm.h.

                                               {this,
        "BC2HorizontalOffset", 0.622896039922 - 25., "BC2 horizontal offset."};

m_bc2HorizontalSlope

Gaudi::Property<double> TileTBBeamMonitorAlgorithm::m_bc2HorizontalSlope

private

Initial value:

{this,
        "BC2HorizontalSlope", -0.176735, "BC2 horizontal slope."}

Definition at line 66 of file TileTBBeamMonitorAlgorithm.h.

                                              {this,
        "BC2HorizontalSlope", -0.176735, "BC2 horizontal slope."};

m_bc2VerticalOffset

Gaudi::Property<double> TileTBBeamMonitorAlgorithm::m_bc2VerticalOffset

private

Initial value:

{this,
        "BC2VerticalOffset", 0.195954125116 + 17.7, "BC2 vertical offset."}

Definition at line 75 of file TileTBBeamMonitorAlgorithm.h.

                                             {this,
        "BC2VerticalOffset", 0.195954125116 + 17.7, "BC2 vertical offset."};

m_bc2VerticalSlope

Gaudi::Property<double> TileTBBeamMonitorAlgorithm::m_bc2VerticalSlope

private

Initial value:

{this,
        "BC2VerticalSlope", -0.176182117624, "BC2 vertical slope."}

Definition at line 72 of file TileTBBeamMonitorAlgorithm.h.

                                            {this,
        "BC2VerticalSlope", -0.176182117624, "BC2 vertical slope."};

m_beamBC1Z

Gaudi::Property<double> TileTBBeamMonitorAlgorithm::m_beamBC1Z

private

Initial value:

{this,
        "BC1Z", 15600.0, "BC1 z position."}

Definition at line 78 of file TileTBBeamMonitorAlgorithm.h.

                                    {this,
        "BC1Z", 15600.0, "BC1 z position."};

m_beamBC2Z

Gaudi::Property<double> TileTBBeamMonitorAlgorithm::m_beamBC2Z

private

Initial value:

{this,
        "BC2Z", 2600.0, "BC2 z position."}

Definition at line 81 of file TileTBBeamMonitorAlgorithm.h.

                                    {this,
        "BC2Z", 2600.0, "BC2 z position."};

m_beamChamberGroups

std::map<std::string, int> TileTBBeamMonitorAlgorithm::m_beamChamberGroups

private

Definition at line 103 of file TileTBBeamMonitorAlgorithm.h.

m_beamElemContainerKey

SG::ReadHandleKey<TileBeamElemContainer> TileTBBeamMonitorAlgorithm::m_beamElemContainerKey

private

Initial value:

{this,
        "TileBeamElemContainer", "TileBeamElemCnt", "Input Tile beam elements container key"}

Definition at line 38 of file TileTBBeamMonitorAlgorithm.h.

                                                                 {this,
        "TileBeamElemContainer", "TileBeamElemCnt", "Input Tile beam elements container key"};

m_cablingSvc

ServiceHandle<TileCablingSvc> TileTBBeamMonitorAlgorithm::m_cablingSvc

private

Initial value:

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

Name of Tile cabling service.

Definition at line 44 of file TileTBBeamMonitorAlgorithm.h.

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

m_caloCellContainerKey

SG::ReadHandleKey<CaloCellContainer> TileTBBeamMonitorAlgorithm::m_caloCellContainerKey

private

Initial value:

{this,
        "CaloCellContainer", "AllCalo", "Calo cell container name"}

Definition at line 84 of file TileTBBeamMonitorAlgorithm.h.

                                                             {this,
        "CaloCellContainer", "AllCalo", "Calo cell container name"};

m_cherenkovGroups

std::vector<int> TileTBBeamMonitorAlgorithm::m_cherenkovGroups

private

Definition at line 99 of file TileTBBeamMonitorAlgorithm.h.

m_cherenkovVsEnergyGroups

std::vector<int> TileTBBeamMonitorAlgorithm::m_cherenkovVsEnergyGroups

private

Definition at line 102 of file TileTBBeamMonitorAlgorithm.h.

m_cherenkovVsTOFGroups

std::vector<std::vector<int> > TileTBBeamMonitorAlgorithm::m_cherenkovVsTOFGroups

private

Definition at line 104 of file TileTBBeamMonitorAlgorithm.h.

m_dataType

AthMonitorAlgorithm::DataType_t AthMonitorAlgorithm::m_dataType

protectedinherited

Instance of the DataType_t enum.

Definition at line 356 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 358 of file AthMonitorAlgorithm.h.

{this,"DataType","userDefined"}; 

m_defaultLBDuration

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

protectedinherited

Default duration of one lumi block.

Definition at line 365 of file AthMonitorAlgorithm.h.

{this,"DefaultLBDuration",60.}; 

m_detailLevel

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

protectedinherited

Sets the level of detail used in the monitoring.

Definition at line 366 of file AthMonitorAlgorithm.h.

{this,"DetailLevel",0}; 

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_DQFilterTools

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

protectedinherited

Array of Data Quality filter tools.

Definition at line 346 of file AthMonitorAlgorithm.h.

{this,"FilterTools",{}}; 

m_dummy

const ToolHandle<GenericMonitoringTool> AthMonitorAlgorithm::m_dummy

privateinherited

Definition at line 374 of file AthMonitorAlgorithm.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 377 of file AthMonitorAlgorithm.h.

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

m_environment

AthMonitorAlgorithm::Environment_t AthMonitorAlgorithm::m_environment

protectedinherited

Instance of the Environment_t enum.

Definition at line 355 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 357 of file AthMonitorAlgorithm.h.

{this,"Environment","user"}; 

m_EventInfoKey

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

protectedinherited

Key for retrieving EventInfo from StoreGate.

Definition at line 367 of file AthMonitorAlgorithm.h.

{this,"EventInfoKey","EventInfo"}; 

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 363 of file AthMonitorAlgorithm.h.

{this,"FileKey",""}; 

m_fragIDs

Gaudi::Property<std::vector<int> > TileTBBeamMonitorAlgorithm::m_fragIDs

private

Initial value:

{this,
        "TileFragIDs", {0x100, 0x101, 0x200, 0x201, 0x402}, "Tile Frag IDs of modules to process."}

Definition at line 47 of file TileTBBeamMonitorAlgorithm.h.

                                           {this,
        "TileFragIDs", {0x100, 0x101, 0x200, 0x201, 0x402}, "Tile Frag IDs of modules to process."};

m_lbDurationDataKey

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

protectedinherited

Definition at line 350 of file AthMonitorAlgorithm.h.

{this,"LBDurationCondDataKey","LBDurationCondData","SG Key of LBDurationCondData object"};

m_lumiDataKey

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

protectedinherited

Definition at line 348 of file AthMonitorAlgorithm.h.

{this,"LuminosityCondDataKey","LuminosityCondData","SG Key of LuminosityCondData object"};

m_masked

Gaudi::Property<std::vector<std::string> > TileTBBeamMonitorAlgorithm::m_masked

private

Initial value:

{this,
        "Masked", {}, "Masked channels: 'module gain channel,channel' (channels are separated by comma)"}

Definition at line 87 of file TileTBBeamMonitorAlgorithm.h.

                                                {this,
        "Masked", {}, "Masked channels: 'module gain channel,channel' (channels are separated by comma)"};

m_maskedChannels

std::array<std::array<unsigned char, TileCalibUtils::MAX_CHAN>, TileCalibUtils::MAX_DRAWERIDX> TileTBBeamMonitorAlgorithm::m_maskedChannels = {{}}

private

Definition at line 113 of file TileTBBeamMonitorAlgorithm.h.

{{}};

m_maskedMuPMTs

std::array<bool, N_MUON_WALL_PMT> TileTBBeamMonitorAlgorithm::m_maskedMuPMTs = {}

private

Definition at line 112 of file TileTBBeamMonitorAlgorithm.h.

{};

m_maskMuonPMTs

Gaudi::Property<std::vector<unsigned int> > TileTBBeamMonitorAlgorithm::m_maskMuonPMTs

private

Initial value:

{this,
        "MaskMuonPMTs", {}, "Masked muon wall PMTs"}

Definition at line 90 of file TileTBBeamMonitorAlgorithm.h.

                                                          {this,
        "MaskMuonPMTs", {}, "Masked muon wall PMTs"};

m_monitoredDrawerIdx

std::array<bool, TileCalibUtils::MAX_DRAWERIDX> TileTBBeamMonitorAlgorithm::m_monitoredDrawerIdx {}

private

Definition at line 111 of file TileTBBeamMonitorAlgorithm.h.

{};

m_muonWallGroups

std::vector<int> TileTBBeamMonitorAlgorithm::m_muonWallGroups

private

Definition at line 101 of file TileTBBeamMonitorAlgorithm.h.

m_name

std::string AthMonitorAlgorithm::m_name

privateinherited

Definition at line 371 of file AthMonitorAlgorithm.h.

m_scalerGroups

std::vector<int> TileTBBeamMonitorAlgorithm::m_scalerGroups

private

Definition at line 100 of file TileTBBeamMonitorAlgorithm.h.

m_sCounterGroups

std::vector<int> TileTBBeamMonitorAlgorithm::m_sCounterGroups

private

Definition at line 98 of file TileTBBeamMonitorAlgorithm.h.

m_TBperiod

Gaudi::Property<int> TileTBBeamMonitorAlgorithm::m_TBperiod

private

Initial value:

{this,
        "TBperiod", 2016, "Tile TB period."}

Definition at line 50 of file TileTBBeamMonitorAlgorithm.h.

                                 {this,
        "TBperiod", 2016, "Tile TB period."};

m_tileHWID

const TileHWID* TileTBBeamMonitorAlgorithm::m_tileHWID {nullptr}

private

Definition at line 109 of file TileTBBeamMonitorAlgorithm.h.

{nullptr};

m_tileID

const TileHWID* TileTBBeamMonitorAlgorithm::m_tileID {nullptr}

private

Definition at line 108 of file TileTBBeamMonitorAlgorithm.h.

{nullptr};

m_tofDiffGroups

std::vector<int> TileTBBeamMonitorAlgorithm::m_tofDiffGroups

private

Definition at line 97 of file TileTBBeamMonitorAlgorithm.h.

m_tofGroups

std::vector<int> TileTBBeamMonitorAlgorithm::m_tofGroups

private

Definition at line 96 of file TileTBBeamMonitorAlgorithm.h.

m_tofPairs

Gaudi::Property<std::vector<std::pair<int, int> > > TileTBBeamMonitorAlgorithm::m_tofPairs

private

Initial value:

{this,
         "TOFDifferencePairs", {}, "TOF pairs to monitor time differnce"}

Definition at line 93 of file TileTBBeamMonitorAlgorithm.h.

                                                          {this,
         "TOFDifferencePairs", {}, "TOF pairs to monitor time differnce"};

m_toolLookupMap

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

privateinherited

Definition at line 372 of file AthMonitorAlgorithm.h.

m_tools

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

protectedinherited

Array of Generic Monitoring Tools.

Definition at line 341 of file AthMonitorAlgorithm.h.

{this,"GMTools",{}}; 

m_trigDecTool

PublicToolHandle<Trig::TrigDecisionTool> AthMonitorAlgorithm::m_trigDecTool

protectedinherited

Tool to tell whether a specific trigger is passed.

Definition at line 345 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 360 of file AthMonitorAlgorithm.h.

{this,"TriggerChain",""}; 

m_trigLiveFractionDataKey

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

protectedinherited

Definition at line 352 of file AthMonitorAlgorithm.h.

{this,"TrigLiveFractionCondDataKey","TrigLiveFractionCondData", "SG Key of TrigLiveFractionCondData object"};

m_useLumi

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

protectedinherited

Allows use of various luminosity functions.

Definition at line 364 of file AthMonitorAlgorithm.h.

{this,"EnableLumi",false}; 

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 361 of file AthMonitorAlgorithm.h.

MaxEvents

TileTBBeamMonitorAlgorithm.MaxEvents

Definition at line 258 of file TileTBBeamMonitorAlgorithm.py.

nargs

TileTBBeamMonitorAlgorithm.nargs

Definition at line 243 of file TileTBBeamMonitorAlgorithm.py.

NoiseFilter

TileTBBeamMonitorAlgorithm.NoiseFilter

Definition at line 263 of file TileTBBeamMonitorAlgorithm.py.

NSamples

TileTBBeamMonitorAlgorithm.NSamples

Definition at line 322 of file TileTBBeamMonitorAlgorithm.py.

parser

TileTBBeamMonitorAlgorithm.parser = flags.getArgumentParser()

Definition at line 236 of file TileTBBeamMonitorAlgorithm.py.

pattern

TileTBBeamMonitorAlgorithm.pattern

Definition at line 275 of file TileTBBeamMonitorAlgorithm.py.

RawChannelContainer

TileTBBeamMonitorAlgorithm.RawChannelContainer

Definition at line 270 of file TileTBBeamMonitorAlgorithm.py.

rawChannels

TileTBBeamMonitorAlgorithm.rawChannels = args.channels

Definition at line 281 of file TileTBBeamMonitorAlgorithm.py.

rawChMaker

TileTBBeamMonitorAlgorithm.rawChMaker = cfg.getEventAlgo('TileRChMaker')

Definition at line 301 of file TileTBBeamMonitorAlgorithm.py.

readDigitsFlx

str TileTBBeamMonitorAlgorithm.readDigitsFlx = 'Flx' in args.digits

Definition at line 284 of file TileTBBeamMonitorAlgorithm.py.

sc

TileTBBeamMonitorAlgorithm.sc = cfg.run()

Definition at line 334 of file TileTBBeamMonitorAlgorithm.py.

summariseProps

TileTBBeamMonitorAlgorithm.summariseProps

Definition at line 330 of file TileTBBeamMonitorAlgorithm.py.

tileInfoLoader

TileTBBeamMonitorAlgorithm.tileInfoLoader = cfg.getService('TileInfoLoader')

Definition at line 321 of file TileTBBeamMonitorAlgorithm.py.

TrigSample

TileTBBeamMonitorAlgorithm.TrigSample

Definition at line 323 of file TileTBBeamMonitorAlgorithm.py.

True

TileTBBeamMonitorAlgorithm.True

Definition at line 330 of file TileTBBeamMonitorAlgorithm.py.

type

TileTBBeamMonitorAlgorithm.type

Definition at line 245 of file TileTBBeamMonitorAlgorithm.py.

useDCS

TileTBBeamMonitorAlgorithm.useDCS

Definition at line 262 of file TileTBBeamMonitorAlgorithm.py.

useTrigger

TileTBBeamMonitorAlgorithm.useTrigger

Definition at line 256 of file TileTBBeamMonitorAlgorithm.py.

withDetails

TileTBBeamMonitorAlgorithm.withDetails

Definition at line 330 of file TileTBBeamMonitorAlgorithm.py.

---

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

• TileTBBeamMonitorAlgorithm.h
• TileTBBeamMonitorAlgorithm.py
• TileTBBeamMonitorAlgorithm.cxx