// fSignals->GetXXX..()
// etc.
//________________________________________________________________________
+#include <string>
+#include <sstream>
+#include <fstream>
#include "TProfile.h"
#include "TFile.h"
#include "AliRawReader.h"
-#include "AliRawEventHeaderBase.h"
#include "AliCaloRawStreamV3.h"
//The include file
using namespace std;
// variables for TTree filling; not sure if they should be static or not
-static int fChannelNum; // for regular towers
-static int fRefNum; // for LED
-static double fAmp;
-static double fAvgAmp;
-static double fRMS;
+static int fChannelNum = 0; // for regular towers
+static int fRefNum = 0; // for LED
+static double fAmp = 0;
+static double fAvgAmp = 0;
+static double fRMS = 0;
// ctor; initialize everything in order to avoid compiler warnings
// put some reasonable defaults
fMapping(NULL),
fRunNumber(-1),
fStartTime(0),
- fAmpCut(50),
- fReqFractionAboveAmpCutVal(0.8),
+ fAmpCut(40), // min. 40 ADC counts as default
+ fReqFractionAboveAmpCutVal(0.6), // 60% in a strip, per default
fReqFractionAboveAmp(kTRUE),
+ fAmpCutLEDRef(100), // min. 100 ADC counts as default
+ fReqLEDRefAboveAmpCutVal(kTRUE),
fHour(0),
fLatestHour(0),
fUseAverage(kTRUE),
fSecInAverage(1800),
+ fDownscale(10),
fNEvents(0),
fNAcceptedEvents(0),
fTreeAmpVsTime(NULL),
// copy ctor
//_____________________________________________________________________
-AliCaloCalibSignal::AliCaloCalibSignal(const AliCaloCalibSignal &sig) :
- TObject(sig),
- fDetType(sig.GetDetectorType()),
- fColumns(sig.GetColumns()),
- fRows(sig.GetRows()),
- fLEDRefs(sig.GetLEDRefs()),
- fModules(sig.GetModules()),
- fCaloString(sig.GetCaloString()),
- fMapping(NULL), //! note that we are not copying the map info
- fRunNumber(sig.GetRunNumber()),
- fStartTime(sig.GetStartTime()),
- fAmpCut(sig.GetAmpCut()),
- fReqFractionAboveAmpCutVal(sig.GetReqFractionAboveAmpCutVal()),
- fReqFractionAboveAmp(sig.GetReqFractionAboveAmp()),
- fHour(sig.GetHour()),
- fLatestHour(sig.GetLatestHour()),
- fUseAverage(sig.GetUseAverage()),
- fSecInAverage(sig.GetSecInAverage()),
- fNEvents(sig.GetNEvents()),
- fNAcceptedEvents(sig.GetNAcceptedEvents()),
- fTreeAmpVsTime(NULL),
- fTreeAvgAmpVsTime(NULL),
- fTreeLEDAmpVsTime(NULL),
- fTreeLEDAvgAmpVsTime(NULL)
-{
- // also the TTree contents
- AddInfo(&sig);
-}
-
+//AliCaloCalibSignal::AliCaloCalibSignal(const AliCaloCalibSignal &sig) :
+// TObject(sig),
+// fDetType(sig.GetDetectorType()),
+// fColumns(sig.GetColumns()),
+// fRows(sig.GetRows()),
+// fLEDRefs(sig.GetLEDRefs()),
+// fModules(sig.GetModules()),
+// fCaloString(sig.GetCaloString()),
+// fMapping(), //! note that we are not copying the map info
+// fRunNumber(sig.GetRunNumber()),
+// fStartTime(sig.GetStartTime()),
+// fAmpCut(sig.GetAmpCut()),
+// fReqFractionAboveAmpCutVal(sig.GetReqFractionAboveAmpCutVal()),
+// fReqFractionAboveAmp(sig.GetReqFractionAboveAmp()),
+// fAmpCutLEDRef(sig.GetAmpCutLEDRef()),
+// fReqLEDRefAboveAmpCutVal(sig.GetReqLEDRefAboveAmpCutVal()),
+// fHour(sig.GetHour()),
+// fLatestHour(sig.GetLatestHour()),
+// fUseAverage(sig.GetUseAverage()),
+// fSecInAverage(sig.GetSecInAverage()),
+// fDownscale(sig.GetDownscale()),
+// fNEvents(sig.GetNEvents()),
+// fNAcceptedEvents(sig.GetNAcceptedEvents()),
+// fTreeAmpVsTime(),
+// fTreeAvgAmpVsTime(),
+// fTreeLEDAmpVsTime(),
+// fTreeLEDAvgAmpVsTime()
+//{
+// // also the TTree contents
+// AddInfo(&sig);
+// for (Int_t i = 0; i<fgkMaxTowers; i++) {
+// fNHighGain[i] = sig.fNHighGain[i];
+// fNLowGain[i] = sig.fNLowGain[i];
+// }
+// for (Int_t i = 0; i<(2*fgkMaxRefs); i++) {
+// fNRef[i] = sig.fNRef[i];
+// }
+//
+//
+//}
+//
// assignment operator; use copy ctor to make life easy..
//_____________________________________________________________________
-AliCaloCalibSignal& AliCaloCalibSignal::operator = (const AliCaloCalibSignal &source)
-{
- // assignment operator; use copy ctor
- if (&source == this) return *this;
-
- new (this) AliCaloCalibSignal(source);
- return *this;
-}
+//AliCaloCalibSignal& AliCaloCalibSignal::operator = (const AliCaloCalibSignal &source)
+//{
+// // assignment operator; use copy ctor
+// if (&source == this) return *this;
+//
+// new (this) AliCaloCalibSignal(source);
+// return *this;
+//}
//_____________________________________________________________________
void AliCaloCalibSignal::CreateTrees()
//_____________________________________________________________________
void AliCaloCalibSignal::ResetInfo()
-{
+{ // reset trees and counters
Zero(); // set all counters to 0
DeleteTrees(); // delete previous stuff
CreateTrees(); // and create some new ones
fNEvents = 0;
fNAcceptedEvents = 0;
- // Set the number of points for each tower: Amp vs. Time
+ // Set the number of points for each tower: Amp vs. Time
memset(fNHighGain, 0, sizeof(fNHighGain));
memset(fNLowGain, 0, sizeof(fNLowGain));
// and LED reference
}
//_____________________________________________________________________
-Bool_t AliCaloCalibSignal::CheckFractionAboveAmp(int *AmpVal, int nTotChan)
-{
- int nAbove = 0;
+Bool_t AliCaloCalibSignal::CheckFractionAboveAmp(const int *iAmpVal,
+ int resultArray[]) const
+{ // check fraction of towers, per column, that are above amplitude cut
+ Bool_t returnCode = false;
- int TowerNum = 0;
+ int iTowerNum = 0;
+ double fraction = 0;
for (int i = 0; i<fModules; i++) {
for (int j = 0; j<fColumns; j++) {
+ int nAbove = 0;
for (int k = 0; k<fRows; k++) {
- TowerNum = GetTowerNum(i,j,k);
- if (AmpVal[TowerNum] > fAmpCut) {
+ iTowerNum = GetTowerNum(i,j,k);
+ if (iAmpVal[iTowerNum] > fAmpCut) {
nAbove++;
}
}
+ resultArray[i*fColumns +j] = 0; // init. to denied
+ if (nAbove > 0) {
+ fraction = (1.0*nAbove) / fRows;
+ /*
+ printf("DS mod %d col %d nAbove %d fraction %3.2f\n",
+ i, j, nAbove, fraction);
+ */
+ if (fraction > fReqFractionAboveAmpCutVal) {
+ resultArray[i*fColumns + j] = nAbove;
+ returnCode = true;
+ }
+ }
}
- }
+ } // modules loop
- double fraction = (1.0*nAbove) / nTotChan;
+ return returnCode;
+}
+
+
+//_____________________________________________________________________
+Bool_t AliCaloCalibSignal::CheckLEDRefAboveAmp(const int *iAmpVal,
+ int resultArray[]) const
+{ // check which LEDRef/Mon strips are above amplitude cut
+ Bool_t returnCode = false;
+
+ int iRefNum = 0;
+ int gain = 1; // look at high gain; this should be rather saturated usually..
+ for (int i = 0; i<fModules; i++) {
+ for (int j = 0; j<fLEDRefs; j++) {
+ iRefNum = GetRefNum(i, j, gain);
+ if (iAmpVal[iRefNum] > fAmpCutLEDRef) {
+ resultArray[i*fLEDRefs +j] = 1; // enough signal
+ returnCode = true;
+ }
+ else {
+ resultArray[i*fLEDRefs +j] = 0; // not enough signal
+ }
+
+ /*
+ printf("DS mod %d LEDRef %d ampVal %d\n",
+ i, j, iAmpVal[iRefNum]);
+ */
+ } // LEDRefs
+ } // modules loop
- if (fraction > fReqFractionAboveAmpCutVal) {
- return true;
+ return returnCode;
+}
+
+// Parameter/cut handling
+//_____________________________________________________________________
+void AliCaloCalibSignal::SetParametersFromFile(const char *parameterFile)
+{ // set parameters from file
+ static const string delimitor("::");
+
+ // open, check input file
+ ifstream in( parameterFile );
+ if( !in ) {
+ printf("in AliCaloCalibSignal::SetParametersFromFile - Using default/run_time parameters.\n");
+ return;
+ }
+
+ // Note: this method is a bit more complicated than it really has to be
+ // - allowing for multiple entries per line, arbitrary order of the
+ // different variables etc. But I wanted to try and do this in as
+ // correct a C++ way as I could (as an exercise).
+
+ // read in
+ char readline[1024];
+ while ((in.rdstate() & ios::failbit) == 0 ) {
+
+ // Read into the raw char array and then construct a string
+ // to do the searching
+ in.getline(readline, 1024);
+ istringstream s(readline);
+
+ while ( ( s.rdstate() & ios::failbit ) == 0 ) {
+
+ string keyValue;
+ s >> keyValue;
+
+ // check stream status
+ if( ( s.rdstate() & ios::failbit ) == ios::failbit ) break;
+
+ // skip rest of line if comments found
+ if( keyValue.substr( 0, 2 ) == "//" ) break;
+
+ // look for "::" in keyValue pair
+ size_t position = keyValue.find( delimitor );
+ if( position == string::npos ) {
+ printf("wrong format for key::value pair: %s\n", keyValue.c_str());
+ }
+
+ // split keyValue pair
+ string key( keyValue.substr( 0, position ) );
+ string value( keyValue.substr( position+delimitor.size(),
+ keyValue.size()-delimitor.size() ) );
+
+ // check value does not contain a new delimitor
+ if( value.find( delimitor ) != string::npos ) {
+ printf("wrong format for key::value pair: %s\n", keyValue.c_str());
+ }
+
+ // debug: check key value pair
+ // printf("AliCaloCalibSignal::SetParametersFromFile - key %s value %s\n", key.c_str(), value.c_str());
+
+ // if the key matches with something we expect, we assign the new value
+ if ( (key == "fAmpCut") || (key == "fReqFractionAboveAmpCutVal") ||
+ (key == "fAmpCutLEDRef") || (key == "fSecInAverage") ||
+ (key == "fDownscale") ) {
+ istringstream iss(value);
+ printf("AliCaloCalibSignal::SetParametersFromFile - key %s value %s\n", key.c_str(), value.c_str());
+
+ if (key == "fAmpCut") {
+ iss >> fAmpCut;
+ }
+ else if (key == "fReqFractionAboveAmpCutVal") {
+ iss >> fReqFractionAboveAmpCutVal;
+ }
+ else if (key == "fAmpCutLEDRef") {
+ iss >> fAmpCutLEDRef;
+ }
+ else if (key == "fSecInAverage") {
+ iss >> fSecInAverage;
+ }
+ else if (key == "fDownscale") {
+ iss >> fDownscale;
+ }
+ } // some match found/expected
+
+ }
}
- else return false;
+
+ in.close();
+ return;
+}
+
+//_____________________________________________________________________
+void AliCaloCalibSignal::WriteParametersToFile(const char *parameterFile)
+{ // write parameters to file
+ static const string delimitor("::");
+ ofstream out( parameterFile );
+ out << "// " << parameterFile << endl;
+ out << "fAmpCut" << "::" << fAmpCut << endl;
+ out << "fReqFractionAboveAmpCutVal" << "::" << fReqFractionAboveAmpCutVal << endl;
+ out << "fAmpCutLEDRef" << "::" << fAmpCutLEDRef << endl;
+ out << "fSecInAverage" << "::" << fSecInAverage << endl;
+ out << "fDownscale" << "::" << fDownscale << endl;
+
+ out.close();
+ return;
}
//_____________________________________________________________________
Bool_t AliCaloCalibSignal::AddInfo(const AliCaloCalibSignal *sig)
-{
+{
// note/FIXME: we are not yet adding correctly the info for fN{HighGain,LowGain,Ref} here - but consider this a feature for now (20080905): we'll do Analyze() unless entries were found for a tower in this original object.
// add info from sig's TTrees to ours..
fTreeLEDAvgAmpVsTime->Fill();
}
+ // We should also copy other pieces of info: counters and parameters
+ // (not number of columns and rows etc which should be the same)
+ // note that I just assign them here rather than Add them, but we
+ // normally just Add (e.g. in Preprocessor) one object so this should be fine.
+ fRunNumber = sig->GetRunNumber();
+ fStartTime = sig->GetStartTime();
+ fAmpCut = sig->GetAmpCut();
+ fReqFractionAboveAmpCutVal = sig->GetReqFractionAboveAmpCutVal();
+ fReqFractionAboveAmp = sig->GetReqFractionAboveAmp();
+ fAmpCutLEDRef = sig->GetAmpCutLEDRef();
+ fReqLEDRefAboveAmpCutVal = sig->GetReqLEDRefAboveAmpCutVal();
+ fHour = sig->GetHour();
+ fLatestHour = sig->GetLatestHour();
+ fUseAverage = sig->GetUseAverage();
+ fSecInAverage = sig->GetSecInAverage();
+ fDownscale = sig->GetDownscale();
+ fNEvents = sig->GetNEvents();
+ fNAcceptedEvents = sig->GetNAcceptedEvents();
return kTRUE;//We hopefully succesfully added info from the supplied object
}
Bool_t AliCaloCalibSignal::ProcessEvent(AliRawReader *rawReader)
{
// if fMapping is NULL the rawstream will crate its own mapping
- AliCaloRawStreamV3 rawStream(rawReader, fCaloString, (AliAltroMapping**)fMapping);
-
- return ProcessEvent( &rawStream, (AliRawEventHeaderBase*)rawReader->GetEventHeader() );
+ AliCaloRawStreamV3 rawStream(rawReader, fCaloString, (AliAltroMapping**)fMapping);
+ if (fDetType == kEmCal) {
+ rawReader->Select("EMCAL", 0, AliEMCALGeoParams::fgkLastAltroDDL) ; //select EMCAL DDL range
+ }
+ return ProcessEvent( &rawStream, rawReader->GetTimestamp() );
}
//_____________________________________________________________________
-Bool_t AliCaloCalibSignal::ProcessEvent(AliCaloRawStreamV3 *in, AliRawEventHeaderBase *aliHeader)
+Bool_t AliCaloCalibSignal::ProcessEvent(AliCaloRawStreamV3 *in, UInt_t Timestamp)
{
// Method to process=analyze one event in the data stream
if (!in) return kFALSE; //Return right away if there's a null pointer
fNEvents++; // one more event
+ if ( (fNEvents%fDownscale)!=0 ) return kFALSE; // mechanism to skip some of the input events, if we want
+
// use maximum numbers to set array sizes
- int AmpValHighGain[fgkMaxTowers];
- int AmpValLowGain[fgkMaxTowers];
- memset(AmpValHighGain, 0, sizeof(AmpValHighGain));
- memset(AmpValLowGain, 0, sizeof(AmpValLowGain));
+ int iAmpValHighGain[fgkMaxTowers];
+ int iAmpValLowGain[fgkMaxTowers];
+ memset(iAmpValHighGain, 0, sizeof(iAmpValHighGain));
+ memset(iAmpValLowGain, 0, sizeof(iAmpValLowGain));
// also for LED reference
- int LEDAmpVal[fgkMaxRefs * 2]; // factor 2 is for the two gain values
- memset(LEDAmpVal, 0, sizeof(LEDAmpVal));
+ int iLEDAmpVal[fgkMaxRefs * 2]; // factor 2 is for the two gain values
+ memset(iLEDAmpVal, 0, sizeof(iLEDAmpVal));
- int sample; // temporary value
+ int sample = 0; // temporary value
int gain = 0; // high or low gain
- // Number of Low and High gain channels for this event:
+ // Number of Low and High gain, and LED Ref, channels for this event:
int nLowChan = 0;
int nHighChan = 0;
+ int nLEDRefChan = 0;
- int TowerNum = 0; // array index for regular towers
- int RefNum = 0; // array index for LED references
+ int iTowerNum = 0; // array index for regular towers
+ int iRefNum = 0; // array index for LED references
// loop first to get the fraction of channels with amplitudes above cut
// counters
int max = AliEMCALGeoParams::fgkSampleMin, min = AliEMCALGeoParams::fgkSampleMax; // min and max sample values
-
+ int nsamples = 0;
+
while (in->NextBunch()) {
const UShort_t *sig = in->GetSignals();
+ nsamples += in->GetBunchLength();
for (Int_t i = 0; i < in->GetBunchLength(); i++) {
sample = sig[i];
} // loop over samples in bunch
} // loop over bunches
+ if (nsamples > 0) { // this check is needed for when we have zero-supp. on, but not sparse readout
+
gain = -1; // init to not valid value
//If we're here then we're done with this tower
if ( in->IsLowGain() ) {
if ( in->IsHighGain() || in->IsLowGain() ) { // regular tower
// get tower number for AmpVal array
- TowerNum = GetTowerNum(arrayPos, in->GetColumn(), in->GetRow());
+ iTowerNum = GetTowerNum(arrayPos, in->GetColumn(), in->GetRow());
if (gain == 0) {
// fill amplitude into the array
- AmpValLowGain[TowerNum] = max - min;
+ iAmpValLowGain[iTowerNum] = max - min;
nLowChan++;
}
else if (gain==1) {//fill the high gain ones
// fill amplitude into the array
- AmpValHighGain[TowerNum] = max - min;
+ iAmpValHighGain[iTowerNum] = max - min;
nHighChan++;
}//end if gain
} // regular tower
- else if ( in->IsLEDMonData() ) { // LED ref.
- RefNum = GetRefNum(arrayPos, in->GetColumn(), gain);
- LEDAmpVal[RefNum] = max - min;
+ else if ( in->IsLEDMonData() ) { // LED ref.;
+ // strip # is coded is 'column' in the channel maps
+ iRefNum = GetRefNum(arrayPos, in->GetColumn(), gain);
+ iLEDAmpVal[iRefNum] = max - min;
+ nLEDRefChan++;
} // end of LED ref
-
+
+ } // nsamples>0 check, some data found for this channel; not only trailer/header
} // end while over channel
}//end while over DDL's, of input stream
in->Reset(); // just in case the next customer forgets to check if the stream was reset..
- // now check if it was a led event, only use high gain (that should be sufficient)
+ // now check if it was an LED event, using the LED Reference info per strip
+
+ // by default all columns are accepted (init check to > 0)
+ int checkResultArray[AliEMCALGeoParams::fgkEMCALModules * AliEMCALGeoParams::fgkEMCALCols];
+ for (int ia=0; ia<(AliEMCALGeoParams::fgkEMCALModules * AliEMCALGeoParams::fgkEMCALCols); ia++) {
+ checkResultArray[ia] = 1;
+ }
if (fReqFractionAboveAmp) {
bool ok = false;
if (nHighChan > 0) {
- ok = CheckFractionAboveAmp(AmpValHighGain, nHighChan);
+ ok = CheckFractionAboveAmp(iAmpValHighGain, checkResultArray);
+ }
+ if (!ok) return false; // skip event
+ }
+
+ // by default all columns are accepted (init check to > 0)
+ int checkResultArrayLEDRef[AliEMCALGeoParams::fgkEMCALModules * AliEMCALGeoParams::fgkEMCALLEDRefs];
+ for (int ia=0; ia<(AliEMCALGeoParams::fgkEMCALModules * AliEMCALGeoParams::fgkEMCALLEDRefs); ia++) {
+ checkResultArrayLEDRef[ia] = 1;
+ }
+ if (fReqLEDRefAboveAmpCutVal) {
+ bool ok = false;
+ if (nLEDRefChan > 0) {
+ ok = CheckLEDRefAboveAmp(iLEDAmpVal, checkResultArrayLEDRef);
}
if (!ok) return false; // skip event
}
fNAcceptedEvents++; // one more event accepted
if (fStartTime == 0) { // if start-timestamp wasn't set,we'll pick it up from the first event we encounter
- fStartTime = aliHeader->Get("Timestamp");
+ fStartTime = Timestamp;
}
- fHour = (aliHeader->Get("Timestamp")-fStartTime)/(double)fgkNumSecInHr;
+ fHour = (Timestamp - fStartTime)/(double)fgkNumSecInHr;
if (fLatestHour < fHour) {
fLatestHour = fHour;
}
// it is a led event, now fill TTree
+ // We also do the activity check for LEDRefs/Strips, but need to translate between column
+ // and strip indices for that; based on these relations:
+ // iStrip = AliEMCALGeoParams::GetStripModule(iSM, iCol);
+ // iStrip = (iSM%2==0) ? iCol/2 : AliEMCALGeoParams::fgkEMCALLEDRefs - 1 - iCol/2;
+ // which leads to
+ // iColFirst = (iSM%2==0) ? iStrip*2 : (AliEMCALGeoParams::fgkEMCALLEDRefs - 1 - iStrip)*2;
+
for(int i=0; i<fModules; i++){
- for(int j=0; j<fColumns; j++){
+ for(int j=0; j<fColumns; j++) {
+ int iStrip = (i%2==0) ? j/2 : AliEMCALGeoParams::fgkEMCALLEDRefs - 1 - j/2;
+ if (checkResultArray[i*fColumns + j]>0 && checkResultArrayLEDRef[i*fLEDRefs + iStrip]>0) { // column passed check
for(int k=0; k<fRows; k++){
- TowerNum = GetTowerNum(i, j, k);
+ iTowerNum = GetTowerNum(i, j, k);
- if(AmpValHighGain[TowerNum]) {
- fAmp = AmpValHighGain[TowerNum];
+ if(iAmpValHighGain[iTowerNum]) {
+ fAmp = iAmpValHighGain[iTowerNum];
fChannelNum = GetChannelNum(i,j,k,1);
- fTreeAmpVsTime->Fill();//fChannelNum,fHour,AmpValHighGain[TowerNum]);
- fNHighGain[TowerNum]++;
+ fTreeAmpVsTime->Fill();//fChannelNum,fHour,AmpValHighGain[iTowerNum]);
+ fNHighGain[iTowerNum]++;
}
- if(AmpValLowGain[TowerNum]) {
- fAmp = AmpValLowGain[TowerNum];
+ if(iAmpValLowGain[iTowerNum]) {
+ fAmp = iAmpValLowGain[iTowerNum];
fChannelNum = GetChannelNum(i,j,k,0);
- fTreeAmpVsTime->Fill();//fChannelNum,fHour,AmpValLowGain[TowerNum]);
- fNLowGain[TowerNum]++;
+ fTreeAmpVsTime->Fill();//fChannelNum,fHour,AmpValLowGain[iTowerNum]);
+ fNLowGain[iTowerNum]++;
}
} // rows
+ } // column passed check, and LED Ref for strip passed check (if any)
} // columns
// also LED refs
for(int j=0; j<fLEDRefs; j++){
- for (gain=0; gain<2; gain++) {
- fRefNum = GetRefNum(i, j, gain);
- if (LEDAmpVal[fRefNum]) {
- fAmp = LEDAmpVal[fRefNum];
- fTreeLEDAmpVsTime->Fill();//fRefNum,fHour,fAmp);
- fNRef[fRefNum]++;
- }
- }
+ int iColFirst = (i%2==0) ? j*2 : (AliEMCALGeoParams::fgkEMCALLEDRefs - 1 - j)*2; //CHECKME!!!
+ if ( ((checkResultArray[i*fColumns + iColFirst]>0) || (checkResultArray[i*fColumns + iColFirst + 1]>0)) && // at least one column in strip passed check
+ (checkResultArrayLEDRef[i*fLEDRefs + j]>0) ) { // and LED Ref passed checks
+ for (gain=0; gain<2; gain++) {
+ fRefNum = GetRefNum(i, j, gain);
+ if (iLEDAmpVal[fRefNum]) {
+ fAmp = iLEDAmpVal[fRefNum];
+ fTreeLEDAmpVsTime->Fill();//fRefNum,fHour,fAmp);
+ fNRef[fRefNum]++;
+ }
+ } // gain
+ } // at least one column in strip passed check, and LED Ref passed check (if any)
}
} // modules
//1: set up TProfiles for the towers that had data
TProfile * profile[fgkMaxTowers*2]; // *2 is since we include both high and low gains
memset(profile, 0, sizeof(profile));
-
- char name[200]; // for profile id and title
- int TowerNum = 0;
+ const Int_t buffersize = 200;
+ char name[buffersize]; // for profile id and title
+ int iTowerNum = 0;
for (int i = 0; i<fModules; i++) {
for (int ic=0; ic<fColumns; ic++){
for (int ir=0; ir<fRows; ir++) {
- TowerNum = GetTowerNum(i, ic, ir);
+ iTowerNum = GetTowerNum(i, ic, ir);
// high gain
- if (fNHighGain[TowerNum] > 0) {
+ if (fNHighGain[iTowerNum] > 0) {
fChannelNum = GetChannelNum(i, ic, ir, 1);
- sprintf(name, "profileChan%d", fChannelNum);
+ snprintf(name,buffersize,"profileChan%d", fChannelNum);
profile[fChannelNum] = new TProfile(name, name, numProfBins, timeMin, timeMax, "s");
}
// same for low gain
- if (fNLowGain[TowerNum] > 0) {
+ if (fNLowGain[iTowerNum] > 0) {
fChannelNum = GetChannelNum(i, ic, ir, 0);
- sprintf(name, "profileChan%d", fChannelNum);
+ snprintf(name,buffersize,"profileChan%d", fChannelNum);
profile[fChannelNum] = new TProfile(name, name, numProfBins, timeMin, timeMax, "s");
}
for (int gain=0; gain<2; gain++) {
fRefNum = GetRefNum(i, j, gain);
if (fNRef[fRefNum] > 0) {
- sprintf(name, "profileLEDRef%d", fRefNum);
+ snprintf(name, buffersize, "profileLEDRef%d", fRefNum);
profileLED[fRefNum] = new TProfile(name, name, numProfBins, timeMin, timeMax, "s");
}
}// gain
return kTRUE;
}
+
+//_____________________________________________________________________
+Bool_t AliCaloCalibSignal::DecodeChannelNum(const int chanId,
+ int *imod, int *icol, int *irow, int *igain) const
+{ // return the module, column, row, and gain for a given channel number
+ *igain = chanId/(fModules*fColumns*fRows);
+ *imod = (chanId/(fColumns*fRows)) % fModules;
+ *icol = (chanId/fRows) % fColumns;
+ *irow = chanId % fRows;
+ return kTRUE;
+}
+
+//_____________________________________________________________________
+Bool_t AliCaloCalibSignal::DecodeRefNum(const int refId,
+ int *imod, int *istripMod, int *igain) const
+{ // return the module, stripModule, and gain for a given reference number
+ *igain = refId/(fModules*fLEDRefs);
+ *imod = (refId/(fLEDRefs)) % fModules;
+ *istripMod = refId % fLEDRefs;
+ return kTRUE;
+}