class AliFMDCalibSampleRate;
class AliFMDCalibStripRange;
class AliFMDAltroMapping;
+class AliCDBEntry;
+class AliFMDPreprocessor;
+
//____________________________________________________________________
//
// Singleton class to handle various parameters (not geometry) of the
/** Zero suppression parameters */
kZeroSuppression = 0x10, // Zero suppression parameters
/** ALTRO data map */
- kAltroMap = 0x20 // Altro channel map
+ kAltroMap = 0x20, // Altro channel map
+ /** Strip Range */
+ kStripRange = 0x40 //Strip range,
};
-
+ enum {
+ kAll = (kPulseGain|kPedestal|kDeadMap|kSampleRate|
+ kZeroSuppression|kAltroMap|kStripRange)
+ };
+
/** Singleton access
@return single to */
static AliFMDParameters* Instance();
/** Initialize the manager. This tries to read the parameters from
CDB. If that fails, the class uses the hard-coded parameters.
*/
- void Init(Bool_t forceReInit=kFALSE,
- UInt_t what = (kPulseGain|kPedestal|kDeadMap|kSampleRate|
- kZeroSuppression|kAltroMap));
+ void Init(Bool_t forceReInit=kFALSE, UInt_t what=kAll );
+ /** Initialize the manager. This tries to read the parameters from
+ CDB. If that fails, the class uses the hard-coded parameters.
+ */
+ void Init(AliFMDPreprocessor* pp,
+ Bool_t forceReInit=kFALSE,
+ UInt_t what=kAll);
+ /**
+ * Initialize the manager. This will try to read some calibrations
+ * (sample rate, strip range, gains, pedestals) from local comma
+ * separated value (CSV) files in the directory pointed at by @a
+ * path. If they are not found, then they will be retrieved from
+ * OCDB as appropriately. Other calibrations are always read from
+ * OCDB.
+ *
+ * The CSV files should be named as
+ *
+ * - Pedestals: <tt>peds</tt><i>det_number</i><tt>.csv</tt>
+ * - Gains: <tt>gains</tt><i>det_number</i><tt>.csv</tt>
+ * - Sample Rate: <tt>conditions</tt><i>det_number</i><tt>.csv</tt>
+ * - Strip Range: <tt>conditions</tt><i>det_number</i><tt>.csv</tt>
+ *
+ * where <i>det_number</i> is the detector number (1, 2, or 3).
+ *
+ * @param path Where to look for the CSV files
+ * @param forceReInit Always reinitialise
+ * @param what What calibrations to load.
+ */
+ void Init(const char* path,
+ Bool_t forceReInit=kFALSE,
+ UInt_t what=kAll);
+
+ /**
+ * Automatically generate a dead map from the pedestals and gains.
+ * A channel is marked as dead of the noise is too high (currently
+ * more than 10 ADC counts), or the gain is unreasonable (currently
+ * larger than 10, or smaller than 0.1).
+ *
+ * The procedure does not overwrite channels previously marked as
+ * dead - e.g., channels marked as dead in the calibration loaded
+ * from OCDB will continue to be marked as dead. That is, this
+ * procedure will never make a channel un-dead.
+ *
+ * @param maxNoise Maximum noise value before a channel is marked
+ * as dead.
+ * @param minGain Minimum value of the calibrated gain before a
+ * channel is considered dead.
+ * @param maxGain Maximum value of the calibrated gain before a
+ * channel is considered dead.
+ */
+ void MakeDeadMap(Float_t maxNoise=10, Float_t minGain=.1, Float_t maxGain=10);
/** Print all parameters.
@param option Option string */
void Print(Option_t* option="A") const;
void SetChannelsPerAltro(UShort_t size=128) { fChannelsPerAltro = size; }
/** @param f Factor to use for accepting a signal. */
void SetPedestalFactor(Float_t f=3) { fPedestalFactor = f; }
+ /** @param n Number of pre-samples to keep during zero-suppression -
+ only used in simulation. */
+ void SetZSPreSamples(UShort_t n=1) { fZSPre = (n & 0x3); }
+ /** @param n Number of post-samples to keep during zero-suppression -
+ only used in simulation. */
+ void SetZSPostSamples(UShort_t n=1) { fZSPost = (n & 0x3); }
+ /** @param use If true, do pedestal subtraction before zero
+ suppression - only used in simulation */
+ void SetZSPedSubtract(Bool_t use=kTRUE) { fZSPedSubtract = use; }
/** @} */
/** @{ */
/** @param s Zero suppression threshold in ADC counts */
void SetZeroSuppression(UShort_t s=0) { fFixedZeroSuppression = s; }
/** @param r How many times we oversample each strip. */
- void SetSampleRate(UShort_t r=1) { fFixedSampleRate = (r>2?2:r);}
+ void SetSampleRate(UShort_t r=1) { fFixedSampleRate = r ;}//(r>2?2:r);}
+ void SetSampleRate(AliFMDCalibSampleRate* r) { fSampleRate = r; }
/** @param p Pedestal value in ADC counts */
void SetPedestal(Float_t p=10) { fFixedPedestal = p; }
+ /** @param p Pedestal map */
+ void SetPedestal(AliFMDCalibPedestal* p) { fPedestal = p; }
/** @param w Pedestal width in ADC counts */
void SetPedestalWidth(Float_t w=1) { fFixedPedestalWidth = w; }
/** @param t Threshold used for 1 MIP acceptance. */
@param min Minimum strip number (0-127).
@param max Maximum strip number (0-127). */
void SetStripRange(UShort_t min=0, UShort_t max=127);
+ void SetStripRange(AliFMDCalibStripRange* r) { fStripRange = r; }
+ /** Whether raw data has full common data header (8 32bit words) or
+ the older invalid format (7 32bit words with bogus entries)
+ @param yes if true the raw data has complete data header */
+ void UseCompleteHeader(Bool_t yes=kTRUE) { fHasCompleteHeader = yes; }
+ /** @param g Gain map */
+ void SetGain(AliFMDCalibGain* g) { fPulseGain = g; }
/** @} */
/** @{ */
UShort_t GetChannelsPerAltro() const { return fChannelsPerAltro; }
/** @return The average energy deposited by one MIP */
Float_t GetEdepMip() const;
+ /** @return The conversion factor from DAC to ADC */
+ Float_t GetDACPerMIP() const;
/** @return The factor used of signal acceptance */
Float_t GetPedestalFactor() const { return fPedestalFactor; }
+ /** @param n Number of pre-samples to keep during zero-suppression -
+ only used in simulation. */
+ UShort_t GetZSPreSamples() const { return fZSPre; }
+ /** @param n Number of post-samples to keep during zero-suppression -
+ only used in simulation. */
+ UShort_t GetZSPostSamples() const { return fZSPost; }
+ /** @param use If true, do pedestal subtraction before zero
+ suppression - only used in simulation */
+ Bool_t IsZSPedSubtract() const { return fZSPedSubtract; }
/** @} */
/** @{ */
- /** @name Get variable parameters */
+ /** @name Various varible conditions */
/** Whether the strip is considered dead
@param detector Detector # (1-3)
@param ring Ring ID ('I' or 'O')
Char_t ring,
UShort_t sector,
UShort_t strip) const;
+ /** Get the number of pre-samples in ALTRO channels
+ @param detector Detector # (1-3)
+ @param ring Ring ID ('I' or 'O')
+ @param sector Sector number (0-39)
+ @param strip Strip number (0-511)
+ @return Maximum strip */
+ UShort_t GetPreSamples(UShort_t,
+ Char_t,
+ UShort_t,
+ UShort_t) const { return 14+5; }
+ /** @} */
+
+ /** @{
+ @name Hardware to detector translation (and inverse) */
+ /** Map a hardware address into a detector index.
+ @param ddl Hardware DDL number
+ @param board FEC number
+ @param altro ALTRO number
+ @param channel Channel number
+ @param timebin Timebin
+ @param det On return, the detector #
+ @param ring On return, the ring ID
+ @param sec On return, the sector #
+ @param str On return, the base of strip #
+ @param sam On return, the sample number for this strip
+ @return @c true on success, false otherwise */
+ Bool_t Hardware2Detector(UShort_t ddl, UShort_t board,
+ UShort_t altro, UShort_t chan,
+ UShort_t timebin,
+ UShort_t& det, Char_t& ring,
+ UShort_t& sec, Short_t& str,
+ UShort_t& sam) const;
+ /** Map a hardware address into a detector index.
+ @param ddl Hardware DDL number
+ @param hwaddr Hardware address.
+ @param timebin Timebin
+ @param det On return, the detector #
+ @param ring On return, the ring ID
+ @param sec On return, the sector #
+ @param str On return, the base of strip #
+ @param sam On return, the sample number for this strip
+ @return @c true on success, false otherwise */
+ Bool_t Hardware2Detector(UShort_t ddl, UShort_t hwaddr,
+ UShort_t timebin,
+ UShort_t& det, Char_t& ring,
+ UShort_t& sec, Short_t& str,
+ UShort_t& sam) const;
+#if 0
/** Translate hardware address to detector coordinates
@param ddl DDL number
@param board Board address
@param sec On return, Sector number (0-39)
@param str On return, Strip number (0-511)
@return @c true on success. */
- Bool_t Hardware2Detector(UInt_t ddl, UInt_t board,
- UInt_t chip, UInt_t channel,
+ Bool_t Hardware2Detector(UShort_t ddl, UShort_t board,
+ UShort_t chip, UShort_t channel,
UShort_t& det, Char_t& ring,
- UShort_t& sec, UShort_t& str) const;
+ UShort_t& sec, Short_t& str) const;
/** Translate hardware address to detector coordinates
@param ddl DDL number
@param addr Hardware address
@param sec On return, Sector number (0-39)
@param str On return, Strip number (0-511)
@return @c true on success. */
- Bool_t Hardware2Detector(UInt_t ddl, UInt_t addr, UShort_t& det,
- Char_t& ring, UShort_t& sec, UShort_t& str) const;
+ Bool_t Hardware2Detector(UShort_t ddl, UShort_t addr, UShort_t& det,
+ Char_t& ring, UShort_t& sec, Short_t& str) const;
+#endif
+ /** Map a detector index into a hardware address.
+ @param det The detector #
+ @param ring The ring ID
+ @param sec The sector #
+ @param str The strip #
+ @param sam The sample number
+ @param ddl On return, hardware DDL number
+ @param board On return, the FEC board address (local to DDL)
+ @param altro On return, the ALTRO number (local to FEC)
+ @param channel On return, the channel number (local to ALTRO)
+ @param timebin On return, the timebin number (local to ALTRO)
+ @return @c true on success, false otherwise */
+ Bool_t Detector2Hardware(UShort_t det, Char_t ring,
+ UShort_t sec, UShort_t str,
+ UShort_t sam,
+ UShort_t& ddl, UShort_t& board,
+ UShort_t& altro, UShort_t& channel,
+ UShort_t& timebin) const;
+ /** Map a detector index into a hardware address.
+ @param det The detector #
+ @param ring The ring ID
+ @param sec The sector #
+ @param str The strip #
+ @param sam The sample number
+ @param ddl On return, hardware DDL number
+ @param hwaddr On return, hardware address.
+ @param timebin On return, the timebin number (local to ALTRO)
+ @return @c true on success, false otherwise */
+ Bool_t Detector2Hardware(UShort_t det, Char_t ring,
+ UShort_t sec, UShort_t str,
+ UShort_t sam,
+ UShort_t& ddl, UShort_t& hwaddr,
+ UShort_t& timebin) const;
+#if 0
/** Translate detector coordinates to hardware address
@param det Detector # (1-3)
@param ring Ring ID ('I' or 'O')
@return @c true on success. */
Bool_t Detector2Hardware(UShort_t det, Char_t ring,
UShort_t sec, UShort_t str,
- UInt_t& ddl, UInt_t& board,
- UInt_t& chip, UInt_t& channel) const;
+ UShort_t& ddl, UShort_t& board,
+ UShort_t& chip, UShort_t& channel) const;
/** Translate detector coordinates to hardware address
@param det Detector # (1-3)
@param ring Ring ID ('I' or 'O')
@param addr On return, Hardware address
@return @c true on success. */
Bool_t Detector2Hardware(UShort_t det, Char_t ring, UShort_t sec,
- UShort_t str, UInt_t& ddl, UInt_t& addr) const;
+ UShort_t str, UShort_t& ddl, UShort_t& addr) const;
+#endif
/** Get the map that translates hardware to detector coordinates
@return Get the map that translates hardware to detector
coordinates */
AliFMDAltroMapping* GetAltroMap() const;
+ /** Whether raw data has full common data header (8 32bit words) or
+ the older invalid format (7 32bit words with bogus entries)
+ @return false if the raw data has incomplete data header */
+ Bool_t HasCompleteHeader() const { return fHasCompleteHeader; }
+
/** @} */
static const char* PulseGainPath() { return fgkPulseGain; }
static const char* AltroMapPath() { return fgkAltroMap; }
static const char* ZeroSuppressionPath() { return fgkZeroSuppression; }
static const char* StripRangePath() { return fgkStripRange; }
+ static const char* GetPedestalShuttleID() {return fkPedestalShuttleID;}
+ static const char* GetGainShuttleID() {return fkGainShuttleID;}
+ static const char* GetConditionsShuttleID() {return fkConditionsShuttleID;}
+
protected:
/** CTOR */
AliFMDParameters();
fAltroChannelSize(o.fAltroChannelSize),
fChannelsPerAltro(o.fChannelsPerAltro),
fPedestalFactor(o.fPedestalFactor),
+ fZSPre(o.fZSPre),
+ fZSPost(o.fZSPost),
+ fZSPedSubtract(o.fZSPedSubtract),
fFixedPedestal(o.fFixedPedestal),
fFixedPedestalWidth(o.fFixedPedestalWidth),
fFixedZeroSuppression(o.fFixedZeroSuppression),
fFixedMaxStrip(o.fFixedMaxStrip),
fFixedPulseGain(o.fFixedPulseGain),
fEdepMip(o.fEdepMip),
+ fHasCompleteHeader(o.fHasCompleteHeader),
fZeroSuppression(o.fZeroSuppression),
fSampleRate(o.fSampleRate),
fPedestal(o.fPedestal),
virtual ~AliFMDParameters() {}
/** Singleton instance */
static AliFMDParameters* fgInstance; // Static singleton instance
+ /**
+ * Check if the file <i>prefix</i><i>number</i> exists in @a path,
+ * and write the full path to @a f.
+ *
+ * @param prefix File prefix (cond, peds, gains, ...)
+ * @param path Path to files
+ * @param number Detector number (1, 2, or 3)
+ * @param f On return full path to file (if found)
+ *
+ * @return @c true if file exists and is readable, @c false otherwise
+ */
+ Bool_t CheckFile(const char* prefix, const char* path,
+ int number, TString& f) const;
+ /** Get an entry from either global AliCDBManager or passed
+ AliFMDPreprocessor.
+ @param path Path to CDB object.
+ @param pp AliFMDPreprocessor
+ @param fatal If true, raise a fatal flag if we didn't get the entry.
+ @return AliCDBEntry if found */
+ AliCDBEntry* GetEntry(const char* path, AliFMDPreprocessor* pp,
+ Bool_t fatal=kTRUE) const;
/** Initialize gains. Try to get them from CDB */
- void InitPulseGain();
+ void InitPulseGain(AliFMDPreprocessor* pp=0);
/** Initialize pedestals. Try to get them from CDB */
- void InitPedestal();
+ void InitPedestal(AliFMDPreprocessor* pp=0);
/** Initialize dead map. Try to get it from CDB */
- void InitDeadMap();
+ void InitDeadMap(AliFMDPreprocessor* pp=0);
/** Initialize sample rates. Try to get them from CDB */
- void InitSampleRate();
+ void InitSampleRate(AliFMDPreprocessor* pp=0);
/** Initialize zero suppression thresholds. Try to get them from CDB */
- void InitZeroSuppression();
+ void InitZeroSuppression(AliFMDPreprocessor* pp=0);
/** Initialize hardware map. Try to get it from CDB */
- void InitAltroMap();
+ void InitAltroMap(AliFMDPreprocessor* pp=0);
/** Initialize strip range. Try to get it from CDB */
- void InitStripRange();
+ void InitStripRange(AliFMDPreprocessor* pp=0);
- Bool_t fIsInit; // Whether we've been initialised
+ Bool_t fIsInit; // Whether we've been initialised
- static const char* fgkPulseGain; // Path to PulseGain calib object
- static const char* fgkPedestal; // Path to Pedestal calib object
- static const char* fgkDead; // Path to Dead calib object
- static const char* fgkSampleRate; // Path to SampleRate calib object
- static const char* fgkAltroMap; // Path to AltroMap calib object
- static const char* fgkZeroSuppression; // Path to ZeroSuppression cal object
- static const char* fgkStripRange; // Path to strip range cal object
- const Float_t fkSiDeDxMip; // MIP dE/dx in Silicon
- UShort_t fVA1MipRange; // # MIPs the pre-amp can do
- UShort_t fAltroChannelSize; // Largest # to store in 1 ADC ch.
- UShort_t fChannelsPerAltro; // Number of pre-amp. chan/adc chan.
- Float_t fPedestalFactor; // Number of pedestal widths
+ static const char* fgkPulseGain; // Path to PulseGain calib object
+ static const char* fgkPedestal; // Path to Pedestal calib object
+ static const char* fgkDead; // Path to Dead calib object
+ static const char* fgkSampleRate; // Path to SampleRate calib object
+ static const char* fgkAltroMap; // Path to AltroMap calib object
+ static const char* fgkZeroSuppression; // Path to ZeroSuppression cal object
+ static const char* fgkStripRange; // Path to strip range cal object
+ const Float_t fkSiDeDxMip; // MIP dE/dx in Silicon
+ UShort_t fVA1MipRange; // # MIPs the pre-amp can do
+ UShort_t fAltroChannelSize; // Largest # to store in 1 ADC ch.
+ UShort_t fChannelsPerAltro; // Number of pre-amp. chan/adc chan.
+ Float_t fPedestalFactor; // Number of pedestal widths
+ UShort_t fZSPre; // Number of pre-samples in ZS
+ UShort_t fZSPost; // Number of post-samples in ZS
+ Bool_t fZSPedSubtract; // Pedestal subtraction before ZS
- Float_t fFixedPedestal; // Pedestal to subtract
- Float_t fFixedPedestalWidth; // Width of pedestal
- UShort_t fFixedZeroSuppression; // Threshold for zero-suppression
- UShort_t fFixedSampleRate; // Times the ALTRO samples pre-amp.
- Float_t fFixedThreshold; // Threshold in ADC counts
- UShort_t fFixedMinStrip; // Minimum strip read-out
- UShort_t fFixedMaxStrip; // Maximum strip read-out
- mutable Float_t fFixedPulseGain; //! Gain (cached)
- mutable Float_t fEdepMip; //! Cache of energy loss for a MIP
+ Float_t fFixedPedestal; // Pedestal to subtract
+ Float_t fFixedPedestalWidth; // Width of pedestal
+ UShort_t fFixedZeroSuppression; // Threshold for zero-suppression
+ UShort_t fFixedSampleRate; // Times the ALTRO samples pre-amp.
+ Float_t fFixedThreshold; // Threshold in ADC counts
+ UShort_t fFixedMinStrip; // Minimum strip read-out
+ UShort_t fFixedMaxStrip; // Maximum strip read-out
+ mutable Float_t fFixedPulseGain; //! Gain (cached)
+ mutable Float_t fEdepMip; //! Cache of energy loss for a MIP
+ Bool_t fHasCompleteHeader; // raw data has incomplete data header
+
+ static const char* fkPedestalShuttleID; // Shuttle/preprocessor ID for pedestals
+ static const char* fkGainShuttleID; // Shuttle/preprocessor ID for gains
+ static const char* fkConditionsShuttleID; // Shuttle/preprocessor ID for conditions
AliFMDCalibZeroSuppression* fZeroSuppression; // Zero suppression from CDB
AliFMDCalibSampleRate* fSampleRate; // Sample rate from CDB
AliFMDAltroMapping* fAltroMap; // Map of hardware
AliFMDCalibStripRange* fStripRange; // Strip range
- ClassDef(AliFMDParameters,5) // Manager of parameters
+ ClassDef(AliFMDParameters,6) // Manager of parameters
};
#endif
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