/************************************************************************** * Copyright(c) 1998-1999, ALICE Experiment at CERN, All rights reserved. * * * * Author: The ALICE Off-line Project. * * Contributors are mentioned in the code where appropriate. * * * * Permission to use, copy, modify and distribute this software and its * * documentation strictly for non-commercial purposes is hereby granted * * without fee, provided that the above copyright notice appears in all * * copies and that both the copyright notice and this permission notice * * appear in the supporting documentation. The authors make no claims * * about the suitability of this software for any purpose. It is * * provided "as is" without express or implied warranty. * **************************************************************************/ /* $Id$ */ /** @file AliFMDRawReader.cxx @author Christian Holm Christensen @date Mon Mar 27 12:45:23 2006 @brief Class to read raw data @ingroup FMD_rec */ //____________________________________________________________________ // // Class to read ADC values from a AliRawReader object. // // This class uses the AliFMDRawStreamer class to read the ALTRO // formatted data. // // +-------+ // | TTask | // +-------+ // ^ // | // +-----------------+ <> +--------------+ // | AliFMDRawReader |<>----------------| AliRawReader | // +-----------------+ +--------------+ // | ^ // | <> | // V | // +-----------------+ <> | // | AliFMDRawStream |------------------------+ // +-----------------+ // | // V // +----------------+ // | AliAltroStream | // +----------------+ // // #include // ALILOG_H #include "AliFMDDebug.h" // Better debug macros #include "AliFMDParameters.h" // ALIFMDPARAMETERS_H #include "AliFMDDigit.h" // ALIFMDDIGIT_H #include "AliFMDSDigit.h" // ALIFMDSDIGIT_H // #include "AliFMDRawStream.h" // ALIFMDRAWSTREAM_H #include "AliRawReader.h" // ALIRAWREADER_H #include "AliFMDRawReader.h" // ALIFMDRAWREADER_H #include "AliFMDDebug.h" #include "AliFMDCalibSampleRate.h" #include "AliFMDCalibStripRange.h" #include "AliFMDAltroMapping.h" #include "AliFMDUShortMap.h" // #include "AliFMDAltroIO.h" // ALIFMDALTROIO_H #include "AliAltroRawStreamV3.h" #include // ROOT_TArrayS #include // ROOT_TTree #include // ROOT_TClonesArray #include #include #include // #include //____________________________________________________________________ ClassImp(AliFMDRawReader) #if 0 ; // This is here to keep Emacs for indenting the next line #endif //____________________________________________________________________ AliFMDRawReader::AliFMDRawReader(AliRawReader* reader, TTree* tree) : TTask("FMDRawReader", "Reader of Raw ADC values from the FMD"), fTree(tree), fReader(reader), // fSampleRate(1), fData(0), fNbytes(0), fMinStrip(0), fMaxStrip(127), fPreSamp(14+5), fSeen(0), fVerbose(false), fErrors("TObject"), fNErrChanLen(0), fNErrAddress(0) { // Default CTOR for (Int_t i = 0; i < 3; i++) { fSampleRate[i] = 0; fZeroSuppress[i] = kFALSE; fNoiseFactor[i] = 1; fL1Phase[i] = 0; fNErrors[i] = 0; } } //____________________________________________________________________ void AliFMDRawReader::Exec(Option_t*) { // Read the data TClonesArray* array = new TClonesArray("AliFMDDigit"); if (!fTree) { AliError("No tree"); return; } fTree->Branch("FMD", &array); ReadAdcs(array); Int_t nWrite = fTree->Fill(); AliDebug(1,Form("Got a grand total of %d digits, wrote %d bytes to tree", array->GetEntriesFast(), nWrite)); delete array; } //____________________________________________________________________ void AliFMDRawReader::AddError(Int_t ddl, Int_t hwaddr) { Int_t nErr = fErrors.GetEntries(); TObject* o = new (fErrors[nErr]) TObject; o->SetUniqueID((ddl & 0xFF) << 12 & (hwaddr & 0xFFF)); } //____________________________________________________________________ void AliFMDRawReader::ReadbackError(const AliAltroRawStreamV3& input, const char* format, ...) { static char buf[512]; va_list ap; va_start(ap, format); vsnprintf(buf, 511, format, ap); buf[511] = '\0'; va_end(ap); // { AliWarning(buf); } if (AliDebugLevel() > 10) { AliLog::Flush(); AliWarning(buf); input.HexDumpChannel(); } Int_t ddl = input.GetDDLNumber(); Int_t hwaddr = input.GetHWAddress(); fReader->AddMinorErrorLog(AliAltroRawStreamV3::kAltroPayloadErr,buf); AddError(ddl, hwaddr); fNErrors[ddl]++; } //____________________________________________________________________ Int_t AliFMDRawReader::NewDDL(AliAltroRawStreamV3& input, UShort_t& det) { // Process a new DDL. Sets the internal data members fZeroSuppress, // fSampleRate, and fNoiseFactor based on information in the RCU trailer. // // Parameters: // input Input stream // det On return, the detector number // // Return value: // negative value in case of problems, the DDL number otherwise // Get the DDL number UInt_t ddl = input.GetDDLNumber(); AliDebug(2,Form("DDL number %d", ddl)); // Note, previously, the ALTROCFG1 register was interpreted as // // Bits Value Description // 0- 3 0/1 1st Baseline filter, mode // 4- 5 Over-1 2nd baseline filter, # of pre-samples // 6- 9 factor 2nd baseline filter, # of post-samples // 10- 0 2nd baseline filter, enable // 11-12 00 Zero suppression, glitch filter mode // 13-15 001 Zero suppression, # of post samples // 16-17 01 Zero suppression, # of pre samples // 18 0/1 Zero suppression, enable // // The interpretation used in AliAltroRawStreamerV3 - which // corresponds directly to ALTRO DPCFG register - is // // Bits Value Description // 0- 3 0/1 1st Baseline filter, mode // 4 0 Polarity (if '1', then "1's inverse") // 5- 6 01 Zero suppression, # of pre samples // 7-10 0001 Zero suppression, # of post samples // 11 0 2nd baseline filter, enable // 12-13 00 Zero suppression, glitch filter mode // 14-16 factor 2nd baseline filter, # of post-samples // 17-18 01 2nd baseline filter, # of pre-samples // 19 0/1 Zero suppression, enable // // Writing 'x' for variable values, that means we have the // following patterns for the 2 cases // // bit # 20 16 12 8 4 0 // old |0x01|0010|00xx|xxxx|xxxx| // new |x01x|xx00|0000|1010|xxxx| // // That means that we can check if bits 10-13 are '1000' or // '0000', which will tell us if the value was written with the // new or the old interpretation. That is, we can check that // // if (((altrocfg1 >> 10) & 0x8) == 0x8) { // // old interpretation // } // else { // // New interpretation // } // // That means, that we should never // // - change the # of zero suppression post samples // - Turn on 2nd baseline correction // - Change the zero-suppression glitch filter mode // // This change as introduced in version 1.2 of Rcu++ // UInt_t cfg1 = input.GetAltroCFG1(); if (((cfg1 >> 10) & 0x8) == 0x8) { UInt_t cfg2 = input.GetAltroCFG2(); AliDebug(3,Form("We have data from older MiniConf 0x%x cfg2=0x%08x", ((cfg1 >> 10) & 0x8), cfg2)); fZeroSuppress[ddl] = (cfg1 >> 0) & 0x1; fNoiseFactor[ddl] = (cfg1 >> 6) & 0xF; fSampleRate[ddl] = (cfg2 >> 20) & 0xF; } else { AliDebug(3,Form("We have data from newer MiniConf 0x%x", ((cfg1 >> 10) & 0x8))); fZeroSuppress[ddl] = input.GetZeroSupp(); // WARNING: We store the noise factor in the 2nd baseline // filters excluded post samples, since we'll never use that // mode. fNoiseFactor[ddl] = input.GetNPostsamples(); // WARNING: We store the sample rate in the number of pre-trigger // samples, since we'll never use that mode. fSampleRate[ddl] = input.GetNPretriggerSamples(); // } AliDebug(10,Form("Phase of DDL=%d is %g (%d)", ddl, input.GetL1Phase(), input.GetAltroCFG2() & 0x1F)); fL1Phase[ddl] = input.GetAltroCFG2() & 0x1F; // input.GetL1Phase(); AliDebug(3,Form("RCU @ DDL %d zero suppression: %s", ddl, (fZeroSuppress[ddl] ? "yes" : "no"))); AliDebug(3,Form("RCU @ DDL %d noise factor: %d", ddl,fNoiseFactor[ddl])); AliDebug(3,Form("RCU @ DDL %d sample rate: %d", ddl,fSampleRate[ddl])); // Get Errors seen Int_t nChAddrMismatch = input.GetNChAddrMismatch(); Int_t nChLenMismatch = input.GetNChLengthMismatch(); if (nChAddrMismatch != 0) { ReadbackError(input, "Got %d channels with address mis-matches for 0x%03x", nChAddrMismatch, ddl); fNErrAddress += nChAddrMismatch; } if (nChLenMismatch != 0) { ReadbackError(input, "Got %d channels with length mis-matches for 0x%03x", nChLenMismatch, ddl); fNErrChanLen += nChLenMismatch; } // Map DDL number to the detector number AliFMDParameters* pars = AliFMDParameters::Instance(); AliFMDAltroMapping* map = pars->GetAltroMap(); if (map->DDL2Detector(ddl) < 0) return -1; det = map->DDL2Detector(ddl); if (AliLog::GetDebugLevel("FMD", 0) > 5) input.PrintRCUTrailer(); return ddl; } //____________________________________________________________________ Int_t AliFMDRawReader::NewChannel(const AliAltroRawStreamV3& input, UShort_t det, Char_t& ring, UShort_t& sec, Short_t& strbase) { // Processs a new channel. Sets the internal data members // fMinStrip, fMaxStrip, and fPreSamp. // // Parameter: // input Input stream // ring On return, the ring identifier // sec On return, the sector number // strbase On return, the strip base // // Return value // negative value in case of problems, hardware address otherwise // Get the hardware address, and map that to detector coordinates UShort_t board, chip, channel; Int_t ddl = input.GetDDLNumber(); Int_t hwaddr = input.GetHWAddress(); if (input.IsChannelBad()) { ReadbackError(input, "Ignoring channel %03d/0x%03x with errors", ddl, hwaddr); return 0xFFFF; } AliFMDParameters* pars = AliFMDParameters::Instance(); AliFMDAltroMapping* map = pars->GetAltroMap(); // Map to hardware stuff map->ChannelAddress(hwaddr, board, chip, channel); // Then try to map to detector address if (!map->Channel2StripBase(board, chip, channel, ring, sec, strbase)) { AliError(Form("Failed to get detector id from DDL %d, " "hardware address 0x%03x", ddl, hwaddr)); return -1; } AliDebug(4,Form("Board: 0x%02x, Altro: 0x%x, Channel: 0x%x", board, chip, channel)); // Get the 'conditions' fMinStrip = pars->GetMinStrip(det, ring, sec, strbase); fMaxStrip = pars->GetMaxStrip(det, ring, sec, strbase); fPreSamp = pars->GetPreSamples(det, ring, sec, strbase); if (fSampleRate[ddl] == 0) { AliDebug(3,Form("Get sample rate for RCU @ DDL %d from OCDB", ddl)); fSampleRate[ddl] = pars->GetSampleRate(det, ring, sec, strbase); } AliDebug(3,Form("RCU @ DDL %d sample rate: %d", ddl,fSampleRate[ddl])); return hwaddr; } //____________________________________________________________________ Bool_t AliFMDRawReader::NewBunch(const AliAltroRawStreamV3& input, UShort_t& start, UShort_t& length) { // // Do some checks on the bunch data // Int_t ddl = input.GetDDLNumber(); Int_t hwaddr = input.GetHWAddress(); UShort_t nSamples = input.GetNSamplesPerCh() + fPreSamp; UShort_t tstart = input.GetStartTimeBin(); length = input.GetBunchLength(); if (tstart >= nSamples) { ReadbackError(input, "Bunch in %03d/0x%03x has an start time greater " "than number of samples: 0x%x >= 0x%x", ddl, hwaddr, tstart, nSamples); return false; } if ((int(tstart) - length + 1) < 0) { ReadbackError(input, "Bunch in %03d/0x%03x has an invalid length and " "start time: 0x%x,0x%x (%d-%d+1=%d<0)", ddl, hwaddr, length, tstart, tstart, length, int(tstart)-length+1); return false; } if (tstart >= start) { ReadbackError(input, "Bunch in %03d/0x%03x has early start time: " "0x%x >= 0x%x", ddl, hwaddr, tstart, start); return false; } start = tstart; return true; } //____________________________________________________________________ Int_t AliFMDRawReader::NewSample(const AliAltroRawStreamV3& input, Int_t i, UShort_t t, UShort_t sec, UShort_t strbase, Short_t& str, UShort_t& samp) { // Process a new timebin // // Parameters: // input Input stream // i Index into bunch data // t Time // strbase Base of strip numbers for this channel // str On return, the strip number // samp On return, the sample number // // Return value // negative value in case of problems, ADC value otherwise if (t < fPreSamp) return -1; Int_t ddl = input.GetDDLNumber(); Int_t hwa = input.GetHWAddress(); const UShort_t* data = input.GetSignals(); Short_t adc = data[i]; AliDebug(10,Form("0x%04x/0x%03x/%04d %4d", ddl, hwa, t, adc)); AliFMDParameters* pars = AliFMDParameters::Instance(); AliFMDAltroMapping* map = pars->GetAltroMap(); samp = 0; Short_t stroff = 0; map->Timebin2Strip(sec, t, fPreSamp, fSampleRate[ddl], stroff, samp); str = strbase + stroff; AliDebug(20,Form("0x%04x/0x%03x/%04d=%4d maps to strip %3d sample %d " "(pre: %d, min: %d, max: %d, rate: %d)", ddl, hwa, t, adc, str, samp, fPreSamp, fMinStrip, fMaxStrip, fSampleRate[ddl])); if (str < 0) { AliDebug(10,Form("Got presamples at timebin %d", i)); return -1; } // VA1 Local strip number Short_t lstrip = (t - fPreSamp) / fSampleRate[ddl] + fMinStrip; AliDebug(15,Form("Checking if strip %d (%d) in range [%d,%d]", lstrip, str, fMinStrip, fMaxStrip)); if (lstrip < fMinStrip || lstrip > fMaxStrip) { AliDebug(10,Form("Strip %03d-%d (%d,%d) from t=%d out of range (%3d->%3d)", str, samp, lstrip, stroff, t, fMinStrip, fMaxStrip)); adc = -1; } // Possibly do pedestal subtraction of signal if (adc > 1023) AliWarning(Form("ADC value out of range: %4d", adc)); return adc; } //____________________________________________________________________ Int_t AliFMDRawReader::NextSample(UShort_t& det, Char_t& rng, UShort_t& sec, UShort_t& str, UShort_t& sam, UShort_t& rat, Short_t& adc, Bool_t& zs, UShort_t& fac) { // Scan current event for next signal. It returns kFALSE when // there's no more data in the event. // // Note, that this member function is in principle very fast, but // contains less error checking. In particular, channels that have // bad bunches cannot be checked here. Seeing a bad bunch will only // skip the remainder of the channel and not reset the already read // digits. This is potentially dangerous. // // Parameters: // det On return, contain the detector number // rng On return, contain the ring identifier // sec On return, contain the sector number // str On return, contain the strip number // sam On return, contain the sample number // rat On return, contain the sample rate // adc On return, contain the ADC counts // zs On return, contain the zero-supp. flag // fac On return, contain the zero-supp. noise factor // // Return values: // 0 No more data // -1 Read sample belongs to a bad bunch // >0 Good status - contains bit mask of values // Bit 1 New DDL // Bit 2 New Channel // Bit 3 New Bunch // Bit 4 New Sample static AliAltroRawStreamV3 stream(fReader); // = 0; static Int_t ddl = -1; static UShort_t tdet = 0; static Char_t trng = '\0'; static UShort_t tsec = 0; static Short_t tstr = 0; static Short_t bstr = -1; static UShort_t tsam = 0; // static UInt_t trate = 0; static Int_t hwaddr = -1; static UShort_t start = 0; static UShort_t length = 0; static Short_t t = -1; static Int_t i = 0; // First entry! if (stream.GetDDLNumber() < 0) { fReader->Reset(); fReader->Select("FMD"); stream.Reset(); stream.SelectRawData("FMD"); stream.SetCheckAltroPayload(false); for (Int_t j = 0; j < kNDDL; j++) fNErrors[j] = 0; // Reset variables ddl = -1; // trate= 0; tdet = 0; trng = '\0'; tsec = 0; tstr = 0; tsam = -1; hwaddr = -1; } UShort_t ret = 0; do { AliDebug(15,Form("t=%4d, start=%4d, length=%4d", t, start, length)); if (t < start - length + 1) { AliDebug(10,Form("Time t=%d < start-length+1=%d-%d+1 (%3d/0x%03x)", t, start, length, ddl, hwaddr)); if (hwaddr > 0xFFF || hwaddr < 0 || !stream.NextBunch()) { if (AliDebugLevel() >= 10 && hwaddr > 0xFFF) { AliDebug(10,"Last channel read was marked bad"); } if (AliDebugLevel() >= 10 && hwaddr < 0) { AliDebug(10,"No more channels"); } AliDebug(10,"No next bunch, or first entry"); if (ddl < 0 || !stream.NextChannel()) { if (AliDebugLevel() >= 10 && ddl < 0) { AliDebug(10,"No DDL"); } AliDebug(10,"No next channel, or first entry"); if (!stream.NextDDL()) { AliDebug(10,"No more DDLs"); stream.Reset(); return 0; } ddl = NewDDL(stream, tdet); AliDebug(5,Form("New DDL: %d (%d)", ddl, tdet)); ret |= 0x1; continue; } hwaddr = NewChannel(stream, tdet, trng, tsec, bstr); if (hwaddr > 0xFFF) fNErrors[ddl] += 1; AliDebug(5,Form("New Channel: %3d/0x%03x", ddl, hwaddr)); start = 1024; ret |= 0x2; continue; } if (!NewBunch(stream, start, length)) { // AliWarning(Form("Bad bunch in %3d/0x%03x read - " // "should progress to next channel " // "(t=%4d,start=%4d,length=%4d)", // ddl, hwaddr, t,start, length)); hwaddr = 0xFFFF; // Bad channel return -1; } AliDebug(5, Form("New bunch in %3d/0x%03x: start=0x%03x, length=%4d", ddl, hwaddr, start, length)); ret |= 0x4; t = start; i = 0; AliDebug(10,Form("Got new bunch FMD%d%c[%2d], bunch @ %d, length=%d", tdet, trng, tsec, start, length)); } Int_t tadc = NewSample(stream, i, t, tsec, bstr, tstr, tsam); AliDebug(10,Form("New sample FMD%d%c[%2d,%3d]-%d = 0x%03x", tdet, trng, tsec, tstr, tsam, tadc)); ret |= 0x8; if (tadc >= 0) { det = tdet; rng = trng; sec = tsec; str = tstr; sam = tsam; adc = tadc; rat = fSampleRate[ddl]; zs = fZeroSuppress[ddl]; fac = fNoiseFactor[ddl]; t--; i++; AliDebug(10,Form("Returning FMD%d%c[%2d,%3d]-%d = 0x%03x (%d,%d,%d)", det, rng, sec, str, sam, adc, rat, zs, fac)); break; } t--; i++; } while (true); AliDebug(5,Form("Returning 0x%02x", ret)); return ret; } //____________________________________________________________________ Int_t AliFMDRawReader::NextSignal(UShort_t& det, Char_t& rng, UShort_t& sec, UShort_t& str, Short_t& adc, Bool_t& zs, UShort_t& fac) { // // Get the next signal // // Parameters: // det On return, the detector // rng On return, the ring // sec On return, the sector // str On return, the strip // adc On return, the ADC value // zs On return, whether zero-supp. is enabled // fac On return, the usd noise factor // // Return: // true if valid data is returned // Int_t ret = 0; do { UShort_t samp, rate; if ((ret = NextSample(det, rng, sec, str, samp, rate, adc, zs, fac)) <= 0) return ret; Bool_t take = SelectSample(samp, rate); if (!take) continue; break; } while (true); return ret; } //____________________________________________________________________ Bool_t AliFMDRawReader::SelectSample(UShort_t samp, UShort_t rate) { // Check if the passed sample is the one we need Bool_t take = kFALSE; switch (rate) { case 1: take = kTRUE; break; case 2: if (samp == 1) take = kTRUE; break; case 3: if (samp == 1) take = kTRUE; break; case 4: if (samp == 2) take = kTRUE; break; default: if (samp == rate-2) take = kTRUE; break; } return take; } //____________________________________________________________________ Bool_t AliFMDRawReader::ReadAdcs(TClonesArray* array) { // Read ADC values from raw input into passed TClonesArray of AliFMDDigit // objects. AliDebug(3,Form("Reading ADC values into a TClonesArray")); // Read raw data into the digits array, using AliFMDAltroReader. if (!array) { AliError("No TClonesArray passed"); return kFALSE; } // static ULong_t unique = 0; const UShort_t kUShortMax = (1 << 16) - 1; fSeen.Reset(kUShortMax); fErrors.Clear(); fNErrChanLen = 0; fNErrAddress = 0; for (Int_t ddl = 0; ddl < kNDDL; ddl++) fNErrors[ddl] = 0; AliAltroRawStreamV3 input(fReader); input.Reset(); input.SetCheckAltroPayload(false); input.SelectRawData("FMD"); // Loop over input RORCs while (input.NextDDL()) { UShort_t det = 0; Int_t ddl = NewDDL(input, det); if (ddl < 0) break; fNErrors[ddl] = 0; while (input.NextChannel()) { // Get the hardware address, and map that to detector coordinates Char_t ring; UShort_t sec; Short_t strbase; Int_t hwaddr = NewChannel(input, det, ring, sec, strbase); if (hwaddr < 0) break; if (hwaddr > 0xFFF) continue; UShort_t start = 0x3FF; Bool_t errors = false; Int_t first = -1; Int_t last = -1; // Loop over bunches while (input.NextBunch()) { // Get Lenght of bunch, and pointer to the data const UShort_t* data = input.GetSignals(); UShort_t length; if (!NewBunch(input, start, length)) { errors = true; break; } // Loop over the data and store it. for (Int_t i = 0; i < length; i++) { // Time Short_t str; UShort_t samp; Int_t t = start - i; Int_t adc = NewSample(input, i, t, sec, strbase, str, samp); if (adc < 0) continue; UShort_t counts = adc; AliDebug(10, Form("FMD%d%c[%02d,%03d]-%d: %4d", det, ring, sec, str, samp, counts)); // Check the cache of indicies Int_t idx = fSeen(det, ring, sec, str); AliFMDDigit* digit = 0; if (idx == kUShortMax) { // We haven't seen this strip yet. fSeen(det, ring, sec, str) = idx = array->GetEntriesFast(); AliDebug(7,Form("making digit @ %5d for FMD%d%c[%2d,%3d]-%d " "from %3d/0x%03x/%4d", idx, det, ring, sec, str, samp, ddl, hwaddr, t)); digit = new ((*array)[idx]) AliFMDDigit(det, ring, sec, str); digit->SetDefaultCounts(fSampleRate[ddl]); } else { digit = static_cast(array->At(idx)); } if (first < 0) first = idx; last = idx; AliDebug(10, Form("Setting FMD%d%c[%2d,%3d]-%d from timebin " "%4d=%4d (%4d)", det, ring, sec, str, samp, t, counts, data[i])); digit->SetCount(samp, counts); } // for (i) } // while (bunch) if (errors) { AliWarning(Form("Channel %3d/0x%03x contain errors, " "resetting index %d to %d", ddl, hwaddr, first, last)); if (first >= 0) { for (Int_t i = first; i <= last; i++) { AliFMDDigit* digit = static_cast(array->At(i)); for (Int_t j = 0; j < fSampleRate[ddl]; j++) { AliDebug(10,Form("Resetting strip %s=%d", digit->GetName(),digit->Counts())); digit->SetCount(j, kBadSignal); } } } } // if (errors && (AliDebugLevel() > 0)) input.HexDumpChannel(); } // while (channel) } // while (ddl) if (fNErrors[0] > 0 || fNErrors[1] > 0 || fNErrors[2] > 0 || fNErrChanLen > 0 || fNErrAddress > 0) { // AliLog::Flush(); AliLog::SetPrintRepetitions(false); AliWarningF("R/O errors: FMD1=%d, FMD2=%d, FMD3=%d, " "Channel Length=%d, address=%d", fNErrors[0], fNErrors[1], fNErrors[2], fNErrChanLen, fNErrAddress); AliLog::SetPrintRepetitions(true); } if (fVerbose && fErrors.GetEntries() > 0) { TString msg; Int_t nErr = fErrors.GetEntries(); for (Int_t i = 0; i < nErr; i++) { UInt_t where = fErrors.At(i)->GetUniqueID(); if (i % 6 == 0) msg.Append("\n"); msg.Append(Form(" %3d/0x%03x", (where >> 12) & 0xFF, (where & 0xFFF))); } // AliLog::Flush(); AliLog::SetPrintRepetitions(false); AliWarningF("Got %d errors in channels %s", nErr, msg.Data()); AliLog::SetPrintRepetitions(true); } return kTRUE; } //____________________________________________________________________ Bool_t AliFMDRawReader::ReadAdcs(AliFMDUShortMap& map) { // Read ADC values from raw input into passed TClonesArray of AliFMDDigit // objects. AliDebug(3,Form("Reading ADC values into a map")); // const UShort_t kUShortMax = (1 << 16) - 1; for (Int_t ddl = 0; ddl < kNDDL; ddl++) fNErrors[ddl] = 0; AliAltroRawStreamV3 input(fReader); input.Reset(); input.SetCheckAltroPayload(false); input.SelectRawData("FMD"); // Loop over input RORCs while (input.NextDDL()) { UShort_t det = 0; Int_t ddl = NewDDL(input, det); if (ddl < 0) break; fNErrors[ddl] = 0; while (input.NextChannel()) { // Get the hardware address, and map that to detector coordinates Char_t ring; UShort_t sec; Short_t strbase; Int_t hwaddr = NewChannel(input, det, ring, sec, strbase); if (hwaddr < 0) break; if (hwaddr > 0xFFF) continue; UShort_t start = 0x3FF; Bool_t errors = false; Int_t first = -1; Int_t last = -1; // Loop over bunches while (input.NextBunch()) { // Get Lenght of bunch, and pointer to the data // const UShort_t* data = input.GetSignals(); UShort_t length; if (!NewBunch(input, start, length)) { errors = true; break; } // Loop over the data and store it. for (Int_t i = 0; i < length; i++) { // Time Short_t str; UShort_t samp; Int_t t = start - i; Int_t adc = NewSample(input, i, t, sec, strbase, str, samp); if (adc < 0) continue; UShort_t counts = adc; AliDebug(10, Form("FMD%d%c[%02d,%03d]-%d: %4d", det, ring, sec, str, samp, counts)); if (SelectSample(samp, fSampleRate[ddl])) map(det,ring,sec,str) = counts; if (first < 0) first = str; last = str; } // for (i) } // while (bunch) if (errors) { AliWarning(Form("Channel %3d/0x%03x contain errors, " "resetting strips %d to %d", ddl, hwaddr, first, last)); if (first >= 0) { Int_t ds = first <= last ? 1 : -1; for (Int_t i = first; i != last+ds; i += ds) { AliDebug(10, Form("Resetting strip FMD%d%c[%02d,%03d]=%d", det,ring,sec,i,map(det,ring,sec,i))); map(det,ring,sec,i) = kBadSignal; } } } } // while (channel) } // while (ddl) return kTRUE; } //____________________________________________________________________ Bool_t AliFMDRawReader::ReadSODevent(AliFMDCalibSampleRate* sampleRate, AliFMDCalibStripRange* stripRange, TArrayS &pulseSize, TArrayS &pulseLength, Bool_t* detectors) { // // Read SOD event into passed objects. // // Parameters: // samplerate The sample rate object to fill // striprange The strip range object to fill // pulseSize The pulse size object to fill // pulseLength The pulse length (in events) object to fill // // Return: // @c true on success // AliDebug(0,Form("Start of SOD/EOD")); UInt_t shift_clk[18]; UInt_t sample_clk[18]; UInt_t strip_low[18]; UInt_t strip_high[18]; UInt_t pulse_size[18]; UInt_t pulse_length[18]; for (size_t i = 0; i < 18; i++) { shift_clk[i] = 0; sample_clk[i] = 0; strip_low[i] = 0; strip_high[i] = 0; pulse_size[i] = 0; pulse_length[i] = 0; } AliFMDParameters* param = AliFMDParameters::Instance(); AliFMDAltroMapping* map = param->GetAltroMap(); AliAltroRawStreamV3 streamer(fReader); streamer.Reset(); streamer.SelectRawData("FMD"); //fReader->GetDDLID(); while (streamer.NextDDL()) { Int_t ddl = streamer.GetDDLNumber(); Int_t detID = fReader->GetDetectorID(); if (detectors) detectors[map->DDL2Detector(ddl)-1] = kTRUE; AliDebug(0,Form(" From reader: DDL number is %d , det ID is %d",ddl,detID)); ULong_t nPayloadWords = streamer.GetRCUPayloadSizeInSOD(); UChar_t* payloadData = streamer.GetRCUPayloadInSOD(); UInt_t* payloadWords = reinterpret_cast(payloadData); //UInt_t* payloadWords = streamer.GetRCUPayloadInSOD(); //std::cout<> 21) & 0xf); UInt_t error = ((address >> 20) & 0x1); UInt_t bcast = ((address >> 18) & 0x1); UInt_t bc_not_altro = ((address >> 17) & 0x1); UInt_t board = ((address >> 12) & 0x1f); UInt_t instruction = 0; UInt_t chip = 0; UInt_t channel = 0; if(bc_not_altro) instruction = address & 0xfff; else { chip = ((address >> 9) & 0x7); channel = ((address >> 5) & 0x5); instruction = (address & 0x1f); } Bool_t readDataWord = kFALSE; switch(type) { case 0x0: // Fec read readDataWord = kTRUE; case 0x1: // Fec cmd case 0x2: // Fec write i++; payloadWords++; break; case 0x4: // Loop case 0x5: // Wait break; case 0x6: // End sequence case 0x7: // End Mem i = nPayloadWords + 1; break; default: break; } //Don't read unless we have a FEC_RD if(!readDataWord) continue; UInt_t dataWord = *payloadWords;//Get32bitWord(i); UInt_t data = (0xFFFFF & dataWord) ; //UInt_t data = (0xFFFF & dataWord) ; if(error) { AliWarning(Form("error bit detected at Word 0x%06x; " "error % d, type %d, bc_not_altro %d, " "bcast %d, board 0x%02x, chip 0x%x, " "channel 0x%02x, instruction 0x%03x", address, error, type, bc_not_altro, bcast,board,chip,channel,instruction)); //process error continue; } switch(instruction) { case 0x01: break; // First ADC T case 0x02: break; // I 3.3 V case 0x03: break; // I 2.5 V altro digital case 0x04: break; // I 2.5 V altro analog case 0x05: break; // I 2.5 V VA case 0x06: break; // First ADC T case 0x07: break; // I 3.3 V case 0x08: break; // I 2.5 V altro digital case 0x09: break; // I 2.5 V altro analog case 0x0A: break; // I 2.5 V VA case 0x2D: break; // Second ADC T case 0x2E: break; // I 1.5 V VA case 0x2F: break; // I -2.0 V case 0x30: break; // I -2.0 V VA case 0x31: break; // 2.5 V Digital driver case 0x32: break; // Second ADC T case 0x33: break; // I 1.5 V VA case 0x34: break; // I -2.0 V case 0x35: break; // I -2.0 V VA case 0x36: break; // 2.5 V Digital driver case 0x37: break; // Third ADC T case 0x38: break; // Temperature sens. 1 case 0x39: break; // Temperature sens. 2 case 0x3A: break; // U 2.5 altro digital (m) case 0x3B: break; // U 2.5 altro analog (m) case 0x3C: break; // Third ADC T case 0x3D: break; // Temperature sens. 1 case 0x3E: break; // Temperature sens. 2 case 0x3F: break; // U 2.5 altro digital (m) case 0x40: break; // U 2.5 altro analog (m) case 0x41: break; // Forth ADC T case 0x42: break; // U 2.5 VA (m) case 0x43: break; // U 1.5 VA (m) case 0x44: break; // U -2.0 VA (m) case 0x45: break; // U -2.0 (m) case 0x46: break; // Forth ADC T case 0x47: break; // U 2.5 VA (m) case 0x48: break; // U 1.5 VA (m) case 0x49: break; // U -2.0 VA (m) case 0x4A: break; // U -2.0 (m) // Counters case 0x0B: break; // L1 trigger CouNTer case 0x0C: break; // L2 trigger CouNTer case 0x0D: break; // Sampling CLK CouNTer case 0x0E: break; // DSTB CouNTer // Test mode case 0x0F: break; // Test mode word case 0x10: break; // Undersampling ratio. // Configuration and status case 0x11: break; // Config/Status Register 0 case 0x12: break; // Config/Status Register 1 case 0x13: break; // Config/Status Register 2 case 0x14: break; // Config/Status Register 3 case 0x15: break; // Free // Comands: case 0x16: break; // Latch L1, L2, SCLK Counters case 0x17: break; // Clear counters case 0x18: break; // Clear CSR1 case 0x19: break; // rstb ALTROs case 0x1A: break; // rstb BC case 0x1B: break; // Start conversion case 0x1C: break; // Scan event length case 0x1D: break; // Read event length case 0x1E: break; // Start test mode case 0x1F: break; // Read acquisition memory // FMD case 0x20: break; // FMDD status case 0x21: break; // L0 counters case 0x22: break; // FMD: Wait to hold case 0x23: break; // FMD: L1 timeout case 0x24: break; // FMD: L2 timeout case 0x25: // FMD: Shift clk shift_clk[board] = ((data >> 8 ) & 0xFF); AliDebug(30,Form("Read shift_clk=%d for board 0x%02x", shift_clk[board], board)); break; case 0x26: // FMD: Strips strip_low[board] = ((data >> 0 ) & 0xFF); strip_high[board] = ((data >> 8 ) & 0xFF); break; case 0x27: // FMD: Cal pulse pulse_size[board] = ((data >> 8 ) & 0xFF); break; case 0x28: break; // FMD: Shape bias case 0x29: break; // FMD: Shape ref case 0x2A: break; // FMD: Preamp ref case 0x2B: // FMD: Sample clk sample_clk[board] = ((data >> 8 ) & 0xFF); AliDebug(30,Form("Read sample_clk=%d for board 0x%02x", sample_clk[board], board)); break; case 0x2C: break; // FMD: Commands case 0x4B: // FMD: Cal events pulse_length[board] = ((data >> 0 ) & 0xFF); break; default: break; } AliDebug(50,Form("instruction 0x%x, dataword 0x%x", instruction,dataWord)); } // End of loop over Result memory event UShort_t det = 0; UShort_t sector = 0; Short_t strip = -1; Char_t ring = '\0'; const UInt_t boards[4] = {0,1,16,17}; for(Int_t i=0;i<4;i++) { if(ddl==0 && (i==1 || i==3)) continue; UInt_t chip =0, channel=0; det = map->DDL2Detector(ddl); map->Channel2StripBase(boards[i], chip, channel, ring, sector, strip); UInt_t samplerate = 0; #if USE_VOTE if(sample_clk[boards[i]] == 0) { if(ddl == 0) { Int_t sample1 = sample_clk[boards[0]]; Int_t sample2 = sample_clk[boards[2]]; if(sample1) sample_clk[boards[i]] = sample1; else sample_clk[boards[i]] = sample2; } else { Int_t sample1 = sample_clk[boards[0]]; Int_t sample2 = sample_clk[boards[1]]; Int_t sample3 = sample_clk[boards[2]]; Int_t sample4 = sample_clk[boards[3]]; Int_t agreement = 0; if(sample1 == sample2) agreement++; if(sample1 == sample3) agreement++; if(sample1 == sample4) agreement++; if(sample2 == sample3) agreement++; if(sample2 == sample4) agreement++; if(sample3 == sample4) agreement++; Int_t idx = 0; if(i<3) idx = i+1; else idx = i-1; if(agreement == 3) { sample_clk[boards[i]] = sample_clk[boards[idx]]; shift_clk[boards[i]] = shift_clk[boards[idx]]; strip_low[boards[i]] = strip_low[boards[idx]]; strip_high[boards[i]] = strip_high[boards[idx]]; pulse_length[boards[i]] = pulse_length[boards[idx]]; pulse_size[boards[i]] = pulse_size[boards[idx]]; AliDebug(3,Form("Vote taken for ddl %d, board 0x%x", ddl,boards[i])); } } } #endif if(sample_clk[boards[i]]) samplerate = shift_clk[boards[i]]/sample_clk[boards[i]]; AliDebug(10,Form("Sample rate for board 0x%02x is %d", boards[i], samplerate)); sampleRate->Set(det,ring,sector,0,samplerate); stripRange->Set(det,ring,sector,0, strip_low[boards[i]],strip_high[boards[i]]); AliDebug(20,Form("det %d, ring %c, ",det,ring)); pulseLength.AddAt(pulse_length[boards[i]], GetHalfringIndex(det,ring,boards[i]/16)); pulseSize.AddAt(pulse_size[boards[i]], GetHalfringIndex(det,ring,boards[i]/16)); AliDebug(20,Form(": Board: 0x%02x\n" "\tstrip_low %3d, strip_high %3d\n" "\tshift_clk %3d, sample_clk %3d\n" "\tpulse_size %3d, pulse_length %3d", boards[i], strip_low[boards[i]], strip_high[boards[i]], shift_clk[boards[i]], sample_clk[boards[i]], pulse_size[boards[i]],pulse_length[boards[i]])); } } AliFMDParameters::Instance()->SetSampleRate(sampleRate); AliFMDParameters::Instance()->SetStripRange(stripRange); AliDebug(0,Form("End of SOD/EOD")); return kTRUE; } //____________________________________________________________________ UInt_t AliFMDRawReader::Get32bitWord(Int_t idx) { // This method returns the 32 bit word at a given // position inside the raw data payload. // The 'index' points to the beginning of the next word. // The method is supposed to be endian (platform) // independent. if (!fData) { AliFatal("Raw data paylod buffer is not yet initialized !"); } Int_t index = 4*idx; if (index < 4) { // fRawReader->AddFatalErrorLog(k32bitWordReadErr,Form("pos = %d",index)); // PrintDebug(); AliWarning(Form("Invalid raw data payload position (%d) !",index)); } UInt_t word = 0; word = fData[--index] << 24; word |= fData[--index] << 16; word |= fData[--index] << 8; word |= fData[--index] << 0 ; return word; } //_____________________________________________________________________ Int_t AliFMDRawReader::GetHalfringIndex(UShort_t det, Char_t ring, UShort_t board) const { // // Get short index for a given half-ring // // Parameters: // det Detector number // ring Ring identifer // board Board number // // Return: // // UShort_t iring = (ring == 'I' ? 1 : 0); Int_t index = (((det-1) << 2) | (iring << 1) | (board << 0)); return index-2; } //____________________________________________________________________ // // EOF //