// //
///////////////////////////////////////////////////////////////////////////////
-#include <Riostream.h>
#include <TMath.h>
#include "TClass.h"
#include "AliDAQ.h"
-#include "AliRawDataHeader.h"
+#include "AliRawDataHeaderSim.h"
#include "AliRawReader.h"
#include "AliLog.h"
+#include "AliFstream.h"
#include "AliTRDrawData.h"
#include "AliTRDdigitsManager.h"
#include "AliTRDgeometry.h"
#include "AliTRDdataArrayI.h"
+#include "AliTRDdataArrayS.h"
+#include "AliTRDrawStreamBase.h"
#include "AliTRDRawStream.h"
#include "AliTRDRawStreamV2.h"
-
#include "AliTRDcalibDB.h"
-#include "AliFstream.h"
-
#include "AliTRDSignalIndex.h"
-
#include "AliTRDfeeParam.h"
#include "AliTRDmcmSim.h"
//
// Default constructor
//
+
fFee = AliTRDfeeParam::Instance();
fNumberOfDDLs = AliDAQ::NumberOfDdls("TRD");
+
}
//_____________________________________________________________________________
//
// Copy constructor
//
+
fFee = AliTRDfeeParam::Instance();
fNumberOfDDLs = AliDAQ::NumberOfDdls("TRD");
+
}
//_____________________________________________________________________________
//
// Destructor
//
+
}
//_____________________________________________________________________________
// This version simulate only raw data with ADC data and not with tracklet.
//
- const Int_t kMaxHcWords = (fGeo->TBmax()/3)*fGeo->ADCmax()*fGeo->MCMmax()*fGeo->ROBmaxC1()/2 + 100 + 20;
+ const Int_t kMaxHcWords = (fGeo->TBmax()/3)
+ * fGeo->ADCmax()
+ * fGeo->MCMmax()
+ * fGeo->ROBmaxC1()/2
+ + 100 + 20;
// Buffer to temporary store half chamber data
- UInt_t *hc_buffer = new UInt_t[kMaxHcWords];
+ UInt_t *hcBuffer = new UInt_t[kMaxHcWords];
// sect is same as iDDL, so I use only sect here.
for (Int_t sect = 0; sect < fGeo->Nsect(); sect++) {
AliFstream* of = new AliFstream(name);
// Write a dummy data header
- AliRawDataHeader header; // the event header
+ AliRawDataHeaderSim header; // the event header
UInt_t hpos = of->Tellp();
of->WriteBuffer((char *) (& header), sizeof(header));
// GTU common data header (5x4 bytes per super module, shows link mask)
for( Int_t cham = 0; cham < fGeo->Ncham(); cham++ ) {
- UInt_t GtuCdh = (UInt_t)(0xe << 28);
+ UInt_t gtuCdh = (UInt_t)(0xe << 28);
for( Int_t plan = 0; plan < fGeo->Nplan(); plan++) {
Int_t iDet = fGeo->GetDetector(plan, cham, sect);
// If chamber status is ok, we assume that the optical link is also OK.
// This is shown in the GTU link mask.
if ( AliTRDcalibDB::Instance()->GetChamberStatus(iDet) )
- GtuCdh = GtuCdh | (3 << (2*plan));
+ gtuCdh = gtuCdh | (3 << (2*plan));
}
- of->WriteBuffer((char *) (& GtuCdh), sizeof(GtuCdh));
+ of->WriteBuffer((char *) (& gtuCdh), sizeof(gtuCdh));
npayloadbyte += 4;
}
Int_t iDet = fGeo->GetDetector(plan,cham,sect);
// Get the digits array
- AliTRDdataArrayI *digits = digitsManager->GetDigits(iDet);
- digits->Expand();
+ AliTRDdataArrayS *digits = (AliTRDdataArrayS *) digitsManager->GetDigits(iDet);
+ if (digits->HasData()) {
+
+ digits->Expand();
+
+ Int_t hcwords = 0;
+ Int_t rv = fFee->GetRAWversion();
+
+ // Process A side of the chamber
+ if ( rv >= 1 && rv <= 2 ) {
+ hcwords = ProduceHcDataV1andV2(digits,0,iDet,hcBuffer,kMaxHcWords);
+ }
+ if ( rv == 3 ) {
+ hcwords = ProduceHcDataV3 (digits,0,iDet,hcBuffer,kMaxHcWords);
+ }
- Int_t hcwords = 0;
- Int_t rv = fFee->GetRAWversion();
+ of->WriteBuffer((char *) hcBuffer, hcwords*4);
+ npayloadbyte += hcwords*4;
- // Process A side of the chamber
- if ( rv >= 1 && rv <= 2 ) hcwords = ProduceHcDataV1andV2(digits,0,iDet,hc_buffer,kMaxHcWords);
- if ( rv == 3 ) hcwords = ProduceHcDataV3 (digits,0,iDet,hc_buffer,kMaxHcWords);
+ // Process B side of the chamber
+ if ( rv >= 1 && rv <= 2 ) {
+ hcwords = ProduceHcDataV1andV2(digits,1,iDet,hcBuffer,kMaxHcWords);
+ }
+ if ( rv >= 3 ) {
+ hcwords = ProduceHcDataV3 (digits,1,iDet,hcBuffer,kMaxHcWords);
+ }
- of->WriteBuffer((char *) hc_buffer, hcwords*4);
- npayloadbyte += hcwords*4;
+ of->WriteBuffer((char *) hcBuffer, hcwords*4);
+ npayloadbyte += hcwords*4;
- // Process B side of the chamber
- if ( rv >= 1 && rv <= 2 ) hcwords = ProduceHcDataV1andV2(digits,1,iDet,hc_buffer,kMaxHcWords);
- if ( rv >= 3 ) hcwords = ProduceHcDataV3 (digits,1,iDet,hc_buffer,kMaxHcWords);
+ }
- of->WriteBuffer((char *) hc_buffer, hcwords*4);
- npayloadbyte += hcwords*4;
}
}
delete of;
}
- delete [] hc_buffer;
+ delete [] hcBuffer;
+
return kTRUE;
}
//_____________________________________________________________________________
-Int_t AliTRDrawData::ProduceHcDataV1andV2(AliTRDdataArrayI *digits, Int_t side
+Int_t AliTRDrawData::ProduceHcDataV1andV2(AliTRDdataArrayS *digits, Int_t side
, Int_t det, UInt_t *buf, Int_t maxSize)
{
//
// the function will finish without crash (this behaviour is similar to the MCM).
//
- Int_t nw = 0; // Number of written words
- Int_t of = 0; // Number of overflowed words
- Int_t plan = fGeo->GetPlane( det ); // Plane
- Int_t cham = fGeo->GetChamber( det ); // Chamber
- Int_t sect = fGeo->GetSector( det ); // Sector (=iDDL)
- Int_t nRow = fGeo->GetRowMax( plan, cham, sect );
- Int_t nCol = fGeo->GetColMax( plan );
- const Int_t nTBin = AliTRDcalibDB::Instance()->GetNumberOfTimeBins();
- Int_t kCtype = 0; // Chamber type (0:C0, 1:C1)
- Int_t iEv = 0xA; // Event ID. Now fixed to 10, how do I get event id?
- UInt_t x = 0; // General used number
- Int_t rv = fFee->GetRAWversion();
+ Int_t nw = 0; // Number of written words
+ Int_t of = 0; // Number of overflowed words
+ Int_t plan = fGeo->GetPlane( det ); // Plane
+ Int_t cham = fGeo->GetChamber( det ); // Chamber
+ Int_t sect = fGeo->GetSector( det ); // Sector (=iDDL)
+ Int_t nRow = fGeo->GetRowMax( plan, cham, sect );
+ Int_t nCol = fGeo->GetColMax( plan );
+ const Int_t kNTBin = AliTRDcalibDB::Instance()->GetNumberOfTimeBins();
+ Int_t kCtype = 0; // Chamber type (0:C0, 1:C1)
+ Int_t iEv = 0xA; // Event ID. Now fixed to 10, how do I get event id?
+ UInt_t x = 0; // General used number
+ Int_t rv = fFee->GetRAWversion();
// Check the nCol and nRow.
if ((nCol == 144) &&
of++;
}
// h[1]
- Int_t bc_ctr = 99; // bunch crossing counter. Here it is set to 99 always for no reason
- Int_t pt_ctr = 15; // pretrigger counter. Here it is set to 15 always for no reason
- Int_t pt_phase = 11; // pretrigger phase. Here it is set to 11 always for no reason
- x = (bc_ctr<<16) | (pt_ctr<<12) | (pt_phase<<8) | ((nTBin-1)<<2) | 1;
+ Int_t bcCtr = 99; // bunch crossing counter. Here it is set to 99 always for no reason
+ Int_t ptCtr = 15; // pretrigger counter. Here it is set to 15 always for no reason
+ Int_t ptPhase = 11; // pretrigger phase. Here it is set to 11 always for no reason
+ x = (bcCtr<<16) | (ptCtr<<12) | (ptPhase<<8) | ((kNTBin-1)<<2) | 1;
if (nw < maxSize) {
buf[nw++] = x;
}
of++;
}
// h[2]
- Int_t ped_setup = 1; // Pedestal filter setup (0:1). Here it is always 1 for no reason
- Int_t gain_setup = 1; // Gain filter setup (0:1). Here it is always 1 for no reason
- Int_t tail_setup = 1; // Tail filter setup (0:1). Here it is always 1 for no reason
- Int_t xt_setup = 0; // Cross talk filter setup (0:1). Here it is always 0 for no reason
- Int_t nonlin_setup = 0; // Nonlinearity filter setup (0:1). Here it is always 0 for no reason
- Int_t bypass_setup = 0; // Filter bypass (for raw data) setup (0:1). Here it is always 0 for no reason
- Int_t common_additive = 10; // Digital filter common additive (0:63). Here it is always 10 for no reason
- x = (ped_setup<<31) | (gain_setup<<30) | (tail_setup<<29) | (xt_setup<<28) | (nonlin_setup<<27)
- | (bypass_setup<<26) | (common_additive<<20) | 1;
+ Int_t pedSetup = 1; // Pedestal filter setup (0:1). Here it is always 1 for no reason
+ Int_t gainSetup = 1; // Gain filter setup (0:1). Here it is always 1 for no reason
+ Int_t tailSetup = 1; // Tail filter setup (0:1). Here it is always 1 for no reason
+ Int_t xtSetup = 0; // Cross talk filter setup (0:1). Here it is always 0 for no reason
+ Int_t nonlinSetup = 0; // Nonlinearity filter setup (0:1). Here it is always 0 for no reason
+ Int_t bypassSetup = 0; // Filter bypass (for raw data) setup (0:1). Here it is always 0 for no reason
+ Int_t commonAdditive = 10; // Digital filter common additive (0:63). Here it is always 10 for no reason
+ x = (pedSetup<<31) | (gainSetup<<30) | (tailSetup<<29) | (xtSetup<<28) | (nonlinSetup<<27)
+ | (bypassSetup<<26) | (commonAdditive<<20) | 1;
if (nw < maxSize) {
buf[nw++] = x;
}
for (Int_t iAdc = 0; iAdc < 21; iAdc++ ) {
Int_t padcol = fFee->GetPadColFromADC(iRob, iMcm, iAdc);
UInt_t aa = !(iAdc & 1) + 2;
- UInt_t *a = new UInt_t[nTBin+2];
+ UInt_t *a = new UInt_t[kNTBin+2];
// 3 timebins are packed into one 32 bits word
- for (Int_t iT = 0; iT < nTBin; iT+=3) {
+ for (Int_t iT = 0; iT < kNTBin; iT+=3) {
if ((padcol >= 0) && (padcol < nCol)) {
- a[iT ] = ((iT ) < nTBin ) ? digits->GetDataUnchecked(padrow,padcol,iT ) : 0;
- a[iT+1] = ((iT + 1) < nTBin ) ? digits->GetDataUnchecked(padrow,padcol,iT + 1) : 0;
- a[iT+2] = ((iT + 2) < nTBin ) ? digits->GetDataUnchecked(padrow,padcol,iT + 2) : 0;
+ a[iT ] = ((iT ) < kNTBin ) ? digits->GetDataUnchecked(padrow,padcol,iT ) : 0;
+ a[iT+1] = ((iT + 1) < kNTBin ) ? digits->GetDataUnchecked(padrow,padcol,iT + 1) : 0;
+ a[iT+2] = ((iT + 2) < kNTBin ) ? digits->GetDataUnchecked(padrow,padcol,iT + 2) : 0;
}
else {
a[iT] = a[iT+1] = a[iT+2] = 0; // This happenes at the edge of chamber (should be pedestal! How?)
// Diagnostics
Float_t avg = 0;
Float_t rms = 0;
- for (Int_t iT = 0; iT < nTBin; iT++) {
+ for (Int_t iT = 0; iT < kNTBin; iT++) {
avg += (Float_t) (a[iT]);
}
- avg /= (Float_t) nTBin;
- for (Int_t iT = 0; iT < nTBin; iT++) {
+ avg /= (Float_t) kNTBin;
+ for (Int_t iT = 0; iT < kNTBin; iT++) {
rms += ((Float_t) (a[iT]) - avg) * ((Float_t) (a[iT]) - avg);
}
- rms = TMath::Sqrt(rms / (Float_t) nTBin);
+ rms = TMath::Sqrt(rms / (Float_t) kNTBin);
if (rms > 1.7) {
AliDebug(2,Form("Large RMS (>1.7) (ROB,MCM,ADC)=(%02d,%02d,%02d), avg=%03.1f, rms=%03.1f"
,iRob,iMcm,iAdc,avg,rms));
}
-
//_____________________________________________________________________________
-Int_t AliTRDrawData::ProduceHcDataV3(AliTRDdataArrayI *digits, Int_t side
- , Int_t det, UInt_t *buf, Int_t maxSize)
+Int_t AliTRDrawData::ProduceHcDataV3(AliTRDdataArrayS *digits, Int_t side
+ , Int_t det, UInt_t *buf, Int_t maxSize)
{
//
// This function simulates: Raw Version == 3 (Zero Suppression Prototype)
//
- Int_t nw = 0; // Number of written words
- Int_t of = 0; // Number of overflowed words
- Int_t plan = fGeo->GetPlane( det ); // Plane
- Int_t cham = fGeo->GetChamber( det ); // Chamber
- Int_t sect = fGeo->GetSector( det ); // Sector (=iDDL)
- Int_t nRow = fGeo->GetRowMax( plan, cham, sect );
- Int_t nCol = fGeo->GetColMax( plan );
- const Int_t nTBin = AliTRDcalibDB::Instance()->GetNumberOfTimeBins();
- Int_t kCtype = 0; // Chamber type (0:C0, 1:C1)
- Int_t iEv = 0xA; // Event ID. Now fixed to 10, how do I get event id?
- UInt_t x = 0; // General used number
- Int_t rv = fFee->GetRAWversion();
+ Int_t nw = 0; // Number of written words
+ Int_t of = 0; // Number of overflowed words
+ Int_t plan = fGeo->GetPlane( det ); // Plane
+ Int_t cham = fGeo->GetChamber( det ); // Chamber
+ Int_t sect = fGeo->GetSector( det ); // Sector (=iDDL)
+ Int_t nRow = fGeo->GetRowMax( plan, cham, sect );
+ Int_t nCol = fGeo->GetColMax( plan );
+ const Int_t kNTBin = AliTRDcalibDB::Instance()->GetNumberOfTimeBins();
+ Int_t kCtype = 0; // Chamber type (0:C0, 1:C1)
+ //Int_t iEv = 0xA; // Event ID. Now fixed to 10, how do I get event id?
+ UInt_t x = 0; // General used number
+ Int_t rv = fFee->GetRAWversion();
// Check the nCol and nRow.
if ((nCol == 144) &&
of++;
}
// h[1]
- Int_t bc_ctr = 99; // bunch crossing counter. Here it is set to 99 always for no reason
- Int_t pt_ctr = 15; // pretrigger counter. Here it is set to 15 always for no reason
- Int_t pt_phase = 11; // pretrigger phase. Here it is set to 11 always for no reason
- x = (bc_ctr<<16) | (pt_ctr<<12) | (pt_phase<<8) | ((nTBin-1)<<2) | 1;
+ Int_t bcCtr = 99; // bunch crossing counter. Here it is set to 99 always for no reason
+ Int_t ptCtr = 15; // pretrigger counter. Here it is set to 15 always for no reason
+ Int_t ptPhase = 11; // pretrigger phase. Here it is set to 11 always for no reason
+ x = (bcCtr<<16) | (ptCtr<<12) | (ptPhase<<8) | ((kNTBin-1)<<2) | 1;
if (nw < maxSize) {
buf[nw++] = x;
}
of++;
}
// h[2]
- Int_t ped_setup = 1; // Pedestal filter setup (0:1). Here it is always 1 for no reason
- Int_t gain_setup = 1; // Gain filter setup (0:1). Here it is always 1 for no reason
- Int_t tail_setup = 1; // Tail filter setup (0:1). Here it is always 1 for no reason
- Int_t xt_setup = 0; // Cross talk filter setup (0:1). Here it is always 0 for no reason
- Int_t nonlin_setup = 0; // Nonlinearity filter setup (0:1). Here it is always 0 for no reason
- Int_t bypass_setup = 0; // Filter bypass (for raw data) setup (0:1). Here it is always 0 for no reason
- Int_t common_additive = 10; // Digital filter common additive (0:63). Here it is always 10 for no reason
- x = (ped_setup<<31) | (gain_setup<<30) | (tail_setup<<29) | (xt_setup<<28) | (nonlin_setup<<27)
- | (bypass_setup<<26) | (common_additive<<20) | 1;
+ Int_t pedSetup = 1; // Pedestal filter setup (0:1). Here it is always 1 for no reason
+ Int_t gainSetup = 1; // Gain filter setup (0:1). Here it is always 1 for no reason
+ Int_t tailSetup = 1; // Tail filter setup (0:1). Here it is always 1 for no reason
+ Int_t xtSetup = 0; // Cross talk filter setup (0:1). Here it is always 0 for no reason
+ Int_t nonlinSetup = 0; // Nonlinearity filter setup (0:1). Here it is always 0 for no reason
+ Int_t bypassSetup = 0; // Filter bypass (for raw data) setup (0:1). Here it is always 0 for no reason
+ Int_t commonAdditive = 10; // Digital filter common additive (0:63). Here it is always 10 for no reason
+ x = (pedSetup<<31) | (gainSetup<<30) | (tailSetup<<29) | (xtSetup<<28) | (nonlinSetup<<27)
+ | (bypassSetup<<26) | (commonAdditive<<20) | 1;
if (nw < maxSize) {
buf[nw++] = x;
}
of++;
}
-
// Scan for ROB and MCM
for (Int_t iRobRow = 0; iRobRow < (kCtype + 3); iRobRow++ ) {
Int_t iRob = iRobRow * 2 + side;
for (Int_t iAdc = 0; iAdc < 21; iAdc++ ) {
Int_t padcol = mcm->GetCol( iAdc );
if ((padcol >= 0) && (padcol < nCol)) {
- for (Int_t iT = 0; iT < nTBin; iT++) {
+ for (Int_t iT = 0; iT < kNTBin; iT++) {
mcm->SetData( iAdc, iT, digits->GetDataUnchecked( padrow, padcol, iT) );
}
} else { // this means it is out of chamber, and masked ADC
//mcm->DumpData( "trdmcmdata.txt", "RFZS" ); // debugging purpose
// Write MCM data to buffer
- Int_t temp_nw = mcm->ProduceRawStream( &buf[nw], maxSize - nw );
- if( temp_nw < 0 ) {
- of += temp_nw;
+ Int_t tempNw = mcm->ProduceRawStream( &buf[nw], maxSize - nw );
+ if( tempNw < 0 ) {
+ of += tempNw;
nw += maxSize - nw;
AliError(Form("Buffer overflow detected. Please increase the buffer size and recompile."));
} else {
- nw += temp_nw;
+ nw += tempNw;
}
delete mcm;
// Vx of the raw data reading
//
- AliTRDdataArrayI *digits = 0;
+ AliTRDdataArrayS *digits = 0;
+ AliTRDdataArrayI *track0 = 0;
+ AliTRDdataArrayI *track1 = 0;
+ AliTRDdataArrayI *track2 = 0;
+
+ //AliTRDSignalIndex *indexes = 0;
+ // Create the digits manager
+ AliTRDdigitsManager* digitsManager = new AliTRDdigitsManager();
+ digitsManager->CreateArrays();
+
+ //AliTRDRawStream input(rawReader);
+ // AliTRDRawStreamV2 input(rawReader);
+ // input.SetRawVersion( fFee->GetRAWversion() );
+ // input.Init();
+
+ AliTRDrawStreamBase *pinput = AliTRDrawStreamBase::GetRawStream(rawReader);
+ AliTRDrawStreamBase &input = *pinput;
+
+ AliInfo(Form("Stream version: %s", input.IsA()->GetName()));
+
+ // Loop through the digits
+ Int_t det = 0;
+
+ while (det >= 0)
+ {
+ det = input.NextChamber(digitsManager);
+ if (det >= 0)
+ {
+ // get...
+ digits = (AliTRDdataArrayS *) digitsManager->GetDigits(det);
+ track0 = (AliTRDdataArrayI *) digitsManager->GetDictionary(det,0);
+ track1 = (AliTRDdataArrayI *) digitsManager->GetDictionary(det,1);
+ track2 = (AliTRDdataArrayI *) digitsManager->GetDictionary(det,2);
+ // and compress
+ if (digits) digits->Compress(1,0);
+ if (track0) track0->Compress(1,0);
+ if (track1) track1->Compress(1,0);
+ if (track2) track2->Compress(1,0);
+ }
+ }
+
+ delete pinput;
+ pinput = NULL;
+
+ return digitsManager;
+}
+
+//_____________________________________________________________________________
+AliTRDdigitsManager *AliTRDrawData::Raw2DigitsOLD(AliRawReader *rawReader)
+{
+ //
+ // Vx of the raw data reading
+ //
+
+ AliTRDdataArrayS *digits = 0;
AliTRDdataArrayI *track0 = 0;
AliTRDdataArrayI *track1 = 0;
AliTRDdataArrayI *track2 = 0;
if (track2) track2->Compress(1,0);
// Add a container for the digits of this detector
- digits = digitsManager->GetDigits(det);
- track0 = digitsManager->GetDictionary(det,0);
- track1 = digitsManager->GetDictionary(det,1);
- track2 = digitsManager->GetDictionary(det,2);
+ digits = (AliTRDdataArrayS *) digitsManager->GetDigits(det);
+ track0 = (AliTRDdataArrayI *) digitsManager->GetDictionary(det,0);
+ track1 = (AliTRDdataArrayI *) digitsManager->GetDictionary(det,1);
+ track2 = (AliTRDdataArrayI *) digitsManager->GetDictionary(det,2);
// Allocate memory space for the digits buffer
if (digits->GetNtime() == 0)