/* ======================================================================== *\ ! ! * ! * This file is part of MARS, the MAGIC Analysis and Reconstruction ! * Software. It is distributed to you in the hope that it can be a useful ! * and timesaving tool in analysing Data of imaging Cerenkov telescopes. ! * It is distributed WITHOUT ANY WARRANTY. ! * ! * Permission to use, copy, modify and distribute this software and its ! * documentation for any purpose is hereby granted without fee, ! * provided that the above copyright notice appear in all copies and ! * that both that copyright notice and this permission notice appear ! * in supporting documentation. It is provided "as is" without express ! * or implied warranty. ! * ! ! ! Author(s): Thomas Bretz 12/2000 ! ! Copyright: MAGIC Software Development, 2000-2008 ! ! \* ======================================================================== */ ///////////////////////////////////////////////////////////////////////////// // // MRawRunHeader // // Root storage container for the RUN HEADER information // // // RAW DATA FORMAT VERSION // ======================= // // Format Version 12: // ----------------- // * fIsSigned // // Format Version 11: // ----------------- // * all variables got four bytes // * header sizes allow to make the format backward compatible // + fHeaderSizeRun // + fHeaderSizeEvt // + fHeaderSizeCrate // + fFileNumber // + fNumSamplesRemovedHead // + fNumSamplesRemovedTail // // Format Version 10: // ----------------- // ? // // Format Version 9: // ----------------- // + fNumEventsRead; // + fSamplingFrequency // - fFreqSampling // + fFadcResolution; // - fNumSignificantBits // // Format Version 8: // ----------------- // + fNumBytesPerSample; // + fFreqSampling; // + fNumSignificantBits // * changes in MRawCrateHeader // // Format Version 7: // ----------------- // - unused // // Format Version 6: // ----------------- // + added CameraVersion // + added TelescopeNumber // + added ObservationMode // + added dummies for TelescopeRa/Dec // // Format Version 5: // ----------------- // - now the sub millisecond information of the time is valid and decoded // which enhances the precision from 51.2us to 200ns // // Format Version 4: // ----------------- // - added support for pixels with negative IDs // // Format Version 3: // ----------------- // - ??? // // Format Version 2: // ----------------- // - removed mjd from data // - added start time // - added stop time // // // MRawRunHeader CLASS VERSION // =========================== // // Format Version 10: // ----------------- // - added fHeaderSizeRun // - added fHeaderSizeEvt // - added fHeaderSizeCrate // - added fFileNumber // - increased fSourceEpochChar // // Format Version 7: // ----------------- // - added fNumEventsRead; // * renamed fFreqSampling to fSamplingFrequency // * renamed fNumSignificantBits to fFadcResolution // // Format Version 6: // ----------------- // - added fNumBytesPerSample; // - added fSamplingFrequency; // - added fFadcResolution; // // Class Version 5: // ----------------- // - for compatibility with newer camera versions // // Class Version 4: // ----------------- // - added fCameraVersion // - added fTelescopeNumber // - changed length of fProjectName to 101 // - changed length of fSourceName to 81 // // Class Version 3: // ---------------- // - enhanced SourceName and ProjectName by one character, because // without telling us the guranteed trailing \0-character has // skipped // // Class Version 2: // ---------------- // - removed fMJD, fYear, fMonth, fDay // - added fRunStart // - added fRunStop // // Class Version 1: // ---------------- // - first implementation // //////////////////////////////////////////////////////////////////////////// #include "MRawRunHeader.h" #include #include #include #include "MLog.h" #include "MLogManip.h" #include "MArrayS.h" #include "MString.h" ClassImp(MRawRunHeader); using namespace std; const UShort_t MRawRunHeader::kMagicNumber = 0xc0c0; const Byte_t MRawRunHeader::kMaxFormatVersion = 11; // -------------------------------------------------------------------------- // // Default constructor. Creates array which stores the pixel assignment. // // MRawRunHeader::MRawRunHeader(const char *name, const char *title) : fPixAssignment(NULL) { fName = name ? name : "MRawRunHeader"; fTitle = title ? title : "Raw Run Header Information"; fPixAssignment = new MArrayS(0); // Remark: If we read old MC data from a root file which do not // yet contain one of these variable, the value given here is // the default. Do not mix files with and without a value if the // files with the value do not match the default! fFormatVersion=11; fSoftVersion=0; fTelescopeNumber=1; fCameraVersion=1; fFadcType=1; fRunType=kRTNone; // use 0xffff for invalidation, 0 means: Data run fRunNumber=0; fFileNumber=0; memset(fProjectName, 0, 101); memset(fSourceName, 0, 81); memset(fObservationMode, 0, 61); fSourceEpochChar[0]=0; fSourceEpochChar[1]=0; fSourceEpochDate=0; fNumCrates=0; fNumPixInCrate=0; fNumSamplesLoGain=0; fNumSamplesHiGain=0; fNumEvents=0; fNumEventsRead=0; fNumBytesPerSample=1; fIsSigned = kFALSE; fSamplingFrequency=300; fFadcResolution=8; fHeaderSizeRun=0; fHeaderSizeEvt=0; fHeaderSizeCrate=0; } MRawRunHeader::MRawRunHeader(const MRawRunHeader &h) { fMagicNumber=h.fMagicNumber; // File type identifier fHeaderSizeRun=h.fHeaderSizeRun; // Size of run header fHeaderSizeEvt=h.fHeaderSizeEvt; // Size of evt header fHeaderSizeCrate=h.fHeaderSizeCrate; // Size of crate header fFormatVersion=h.fFormatVersion; // File format version fSoftVersion=h.fSoftVersion; // DAQ software version fFadcType=h.fFadcType; // FADC type (1=Siegen, 2=MUX) fCameraVersion=h.fCameraVersion; // Camera Version (1=MAGIC I) fTelescopeNumber=h.fTelescopeNumber; // Telescope number (1=Magic I) fRunType=h.fRunType; // Run Type fRunNumber=h.fRunNumber; // Run number fFileNumber=h.fFileNumber; // File number memcpy(fProjectName, h.fProjectName, 101); // Project name memcpy(fSourceName, h.fSourceName, 81); // Source name memcpy(fObservationMode, h.fObservationMode, 61); // observation mode memcpy(fSourceEpochChar, h.fSourceEpochChar, 4); // epoch char of the source fSourceEpochDate=h.fSourceEpochDate; // epoch date of the source fNumCrates=h.fNumCrates; // number of electronic boards fNumPixInCrate=h.fNumPixInCrate; // number of pixels in crate fNumSamplesLoGain=h.fNumSamplesLoGain; // number of logain samples stored fNumSamplesHiGain=h.fNumSamplesHiGain; // number of higain samples stored fNumBytesPerSample=h.fNumBytesPerSample; // number of bytes per sample fNumEvents=h.fNumEvents; // number of events stored fNumEventsRead=h.fNumEventsRead; // number of events read by the electronics fSamplingFrequency=h.fSamplingFrequency; // Sampling Frequency [MHz] fFadcResolution=h.fFadcResolution; // number of significant bits fRunStart=h.fRunStart; // time of run start fRunStop=h.fRunStop; // time of run stop fPixAssignment = new MArrayS(*h.fPixAssignment); //-> pixel assignment table } // -------------------------------------------------------------------------- // // Destructor. Deletes the 'pixel-assignment-array' // MRawRunHeader::~MRawRunHeader() { delete fPixAssignment; } // -------------------------------------------------------------------------- // // Checks for consistency between two run headers. Checks: // fNumCrates // fNumPixInCrate // fNumSamplesLoGain // fNumSamplesHiGain // fNumBytesPerSample // Bool_t MRawRunHeader::IsConsistent(const MRawRunHeader &h) const { return fNumCrates==h.fNumCrates && fNumPixInCrate==h.fNumPixInCrate && fNumSamplesLoGain==h.fNumSamplesLoGain && fNumSamplesHiGain==h.fNumSamplesHiGain && fNumBytesPerSample==h.fNumBytesPerSample; } // -------------------------------------------------------------------------- // // Swap the assignment of the pixels with hardware id id0 and id1 // Bool_t MRawRunHeader::SwapAssignment(Short_t id0, Short_t id1) { const Int_t n = fPixAssignment->GetSize(); // Look-up-table UShort_t *lut = fPixAssignment->GetArray(); // Search for one of the hardware indices to get exchanged int i; for (i=0; i10) { if (GetTypeID()!=fTelescopeNumber && GetTypeID()!=fTelescopeNumber*10U && GetTypeID()!=5U) { *fLog << err << "ERROR - Telescope number " << fTelescopeNumber << " doesn't match the first two digits of the run number " << fRunNumber << " and run number doesn't start with 5." << endl; return kFALSE; } // Old formats can not contain a run number larger 999999 if (fRunNumber<1000000) { *fLog << err << "ERROR - Run number " << fRunNumber << " smaller than 1000000." << endl; return kFALSE; } } // Check for correct number of bytes in data stream if (fFormatVersion>7 && fNumBytesPerSample!=2) { *fLog << err << "ERROR - " << fNumBytesPerSample << " bytes per sample are not supported!" << endl; return kFALSE; } // If we have a vlid stop time check its consistency with the start time if (fRunStop!=MTime() && fRunStop999) { *fLog << err << "ERROR - File number " << fFileNumber << " larger than 999." << endl; return kFALSE; } // Old formats can not contain a run number larger 0 if (fFormatVersion<11 && fFileNumber>0) { *fLog << err << "ERROR - File number " << fFileNumber << " larger than 0." << endl; return kFALSE; } if (fFormatVersion>1) { // For most of the formats the start time must be valid if (fRunStart==MTime()) { *fLog << err << "ERROR - Start time invalid." << endl; return kFALSE; } // For most of the formats an invalid stop time cannot happen if file closed if (fMagicNumber==kMagicNumber && fRunStop==MTime()) { *fLog << err << "ERROR - File closed but stop time invalid." << endl; return kFALSE; } } return kTRUE; } void MRawRunHeader::FixRunNumbers() { if (fFormatVersion<11 || fTelescopeNumber!=1) return; // Map 1:1001349 to 47:1001395 if (fRunNumber<48 && fRunStart.GetMjd()>54674.5 && fRunStart.GetMjd()<56476.5) { fRunNumber += 1001348; *fLog << warn << "Format >V10: Wrong run number increased by 1001348 to " << fRunNumber << "." << endl; } // Map 1001916:1001922 to 1002349:1002355 if (fRunNumber>1001915 && fRunNumber<1001923 && fRunStart.GetMjd()>54710.5 && fRunStart.GetMjd()<54711.5) { fRunNumber += 433; *fLog << warn << "Format >V10: Wrong run number increased by 434 to " << fRunNumber << "." << endl; } // Map 10000342:1000343 to 10000351:1000351 if (fRunNumber>10000342 && fRunNumber<10000352 && fRunStart.GetMjd()>54254.5 && fRunStart.GetMjd()<54255.5) { fRunNumber -= 9000000; *fLog << warn << "Format >V10: Wrong run number decreased by 9000000 to " << fRunNumber << "." << endl; } if (fRunNumber==1000382 && fRunStart.GetMjd()>54256.5 && fRunStart.GetMjd()<54257.5 && !strcmp(fSourceName, "GRB080605-2347")) { fFileNumber += 99; *fLog << warn << "Format >V10: Ambiguous file number increased by 99 to " << fFileNumber << "." << endl; } } // -------------------------------------------------------------------------- // // This implements a fix of the pixel assignment before 25.9.2005 // // From magic_online (the pixel numbers are hardware indices): // -------------------------------------------------------------------------- // From: Florian Goebel // Date: Sun Sep 25 2005 - 05:13:19 CEST // // [...] // - problem 2: pixels were swaped // - cause: opical fibers were wrongly connected to receiver board // 554 <-> 559 // 555 <-> 558 // 556 <-> 557 // - action: reconnect correctly // - result: ok now // - comment: I don't know when this error was introduced, so backward // correction of the data is difficult. // Fortunately the effect is not too large since the affected 6 pixels are // on the outermost edge of the camera // Since this board has special pixels the optical fibers have been // unplugged several times. // !!!!! Whenever you unplug and reconnect optical fibers make really !!!!! // !!!!! sure you connect them back correctly. !!!!! // !!!!! Always contact me before you do so and if you have any doubts !!!!! // !!!!! how to reconnect the fibers ask me. !!!!! // These swapped pixels have only been found by chance when doing the // flatfielding. // [...] // // -------------------------------------------------------------------------- // // MAGIC runbook CC_2006_04_22_22_28_52.rbk // // [2006-04-22 23:14:13] // // [...] // Found 2 pairs of swapped pixels. // We corrected swapped pixels 54<->55 in the receiver boards. We probably // swapped today in the camera. // We did not correct 92<-<93 which are likely swapped. Will check and correct // tomorrow. // // --- // // comments: // - 54<->55 were corrected but have not been swapped, hence they are swapped // since then (run 88560 ok, run 88669 swapped; between them mostly dummy and // test runs) // - 92<->93 are never swapped, always ok. // // -------------------------------------------------------------------------- // // MAGIC runbook CC_2006_08_28_19_40_18.rbk // // [2006-08-28 23:09:07] // While doing a flatfielding we have found out that the signals for pixels // 119 and 120 were swapped. We have fixed it by exchanging the corresponding // fibers at the input of the receivers (not before the splitters!). // // --- // // MAGIC runbook CC_2006_08_29_15_19_14.rbk // // [2006-08-29 16:43:09] // In the last hours we have found out and fixed a good number of pixels which // were swapped: 119-120, 160-161-162 and 210-263. According to Florian, // 160-161-162 and 210-263 were swapped since November 2005. // // --- // // mail Florian Goebel (08/30/2006 03:13 PM): // // As far as I can tell pixels 161 and 162 as well as 263 and 210 were // swapped in the trigger. This leads to some inefficiency of the trigger. // However, they were not swapped in the readout. So, you don't have to // correct anything in the data for these pixels. // // --- // // comments: // - 119-120 swapped between run 93251 (not swapped) and 93283 (swapped) // (only testruns between these runs) // corrected since run 99354 (== runbook [2006-08-28 23:09:07]) // - 160 never swapped // - 161-162 were only swapped in the trigger, but nevertheless were // "corrected" also in the signal. Hence signal swapped since 99354 // Bool_t MRawRunHeader::FixAssignment() { if (fTelescopeNumber!=1) return kTRUE; if (fRunNumber>=53300 && fRunNumber<=68754) { if (!SwapAssignment(554, 559)) return kFALSE; if (!SwapAssignment(555, 558)) return kFALSE; if (!SwapAssignment(556, 557)) return kFALSE; } if (fRunNumber>=93283 && fRunNumber<99354) { if (!SwapAssignment(119, 120)) return kFALSE; } if (fRunNumber>=99354 && fRunNumber<=101789) { if (!SwapAssignment(161, 162)) return kFALSE; if (!SwapAssignment(210, 263)) return kFALSE; } if (fRunNumber>=88669) { if (!SwapAssignment(54, 55)) return kFALSE; } if (fRunNumber>=200000) { if (!SwapAssignment(428, 429)) return kFALSE; } return kTRUE; } // -------------------------------------------------------------------------- // // Fixes to fix bugs in the run header // Bool_t MRawRunHeader::Fixes() { FixRunNumbers(); if (fFormatVersion>8 && fRunNumber>326152 && fTelescopeNumber==1) { fNumEvents--; fNumEventsRead--; *fLog << inf << "Format >V8 and Run>M1:326152: Stored number of events decreased by 1." << endl; } return FixAssignment(); } // -------------------------------------------------------------------------- // // Reading function to read/interpret the file formats 1-10 // Bool_t MRawRunHeader::ReadEvtOld(istream& fin) { if (fFormatVersion==7) { *fLog << err << "ERROR - File format V7 was for testing only and is not correctly implemented!" << endl; return kFALSE; } // ----- DAQ software format version ----- fin.read((char*)&fSoftVersion, 2); // Total=6 fFadcType = 1; if (fFormatVersion>7) fin.read((char*)&fFadcType, 2); // ----- Camera geometry and telescope number ----- fCameraVersion = 1; fTelescopeNumber = 1; if (fFormatVersion>5) { fin.read((char*)&fCameraVersion, 2); // (+2) fin.read((char*)&fTelescopeNumber, 2); // (+2) } // ----- Run information ----- fin.read((char*)&fRunType, 2); // Total=8 fin.read((char*)&fRunNumber, 4); // Total=12 fin.read((char*)&fProjectName, fFormatVersion>5?100:22); // Total=34 (+78) fin.read((char*)&fSourceName, fFormatVersion>5? 80:12); // Total=46 (+58) if (fFormatVersion>5) fin.read((char*)fObservationMode, 60); // (+60) // Maybe we should set fObservationMode to something // in case of fFormatVersion<6 // ----- Source position ----- fin.seekg(fFormatVersion>5 ? 16 : 8, ios::cur); /* if (fFormatVersion>5) { fin.read((char*)&fSourceRa, 4); // F32 SourceRA; Total=48 fin.read((char*)&fSourceDec, 4); // F32 SourceDEC; Total=52 } fin.read((char*)&fTelescopeRa, 4); // F32 TelescopeRA; (+4) fin.read((char*)&fTelescopeDec, 4); // F32 TelescopeDEC; (+4) */ // Maybe we should set these to something // in case of fFormatVersion<6 fin.read((char*)&fSourceEpochChar, 2); // Total=56 fin.read((char*)&fSourceEpochDate, 2); // Total=58 // ----- Old Start time ----- if (fFormatVersion<2) // Total += 10 { UShort_t y, m, d; fin.seekg(4, ios::cur); // Former fMJD[4], fin.read((char*)&y, 2); // Former fDateYear[2] fin.read((char*)&m, 2); // Former fDateMonth[2] fin.read((char*)&d, 2); // Former fDateDay[2] fRunStart.Set(y, m, d, 0, 0, 0, 0); } // ----- Data Geometry ----- fin.read((char*)&fNumCrates, 2); // MUX: number of channels fin.read((char*)&fNumPixInCrate, 2); // MUX: number of pix in channel fin.read((char*)&fNumSamplesLoGain, 2); // MUX: dummy (must be 0 for MUX data) fin.read((char*)&fNumSamplesHiGain, 2); // MUX: Number of samples per pixel char dummy[16]; if (fFormatVersion>8) fin.read(dummy, 4); // 2xU16 (NumSamplesRemovedHead and NumSamplesRemovedTail) // ----- Number of events ----- fin.read((char*)&fNumEvents, 4); // Total=70 if (fFormatVersion>8) fin.read((char*)&fNumEventsRead, 4); // New in general features: (should they be included in new MAGIC1 formats, too?) fNumBytesPerSample = 1; // 2 for MUX DATA fSamplingFrequency = 300; fFadcResolution = 8; if (fFormatVersion>7) { fin.read((char*)&fNumBytesPerSample, 2); fin.read((char*)&fSamplingFrequency, 2); // [MHz], 2000 for MuxFadc fin.read((char*)&fFadcResolution, 1); // nominal resolution [# Bits], 10 for MuxFadc } // ----- Start/Stop time ----- if (fFormatVersion>1) { fRunStart.ReadBinary(fin); // Total += 7 fRunStop.ReadBinary(fin); // Total += 7 } // // calculate size of array, create it and fill it // const Int_t nPixel = fNumCrates*fNumPixInCrate; fPixAssignment->Set(nPixel); // ----- Pixel Assignement ----- fin.read((char*)fPixAssignment->GetArray(), nPixel*2); if (fFormatVersion<7) fin.read(dummy, 16); // ----- Fixes for broken files or contents ----- if (!Fixes()) return kFALSE; // ----- Consistency checks ----- return IsConsistent(); } // -------------------------------------------------------------------------- // // Read in one run header from the binary file // Bool_t MRawRunHeader::ReadEvt(istream& fin) { // // read one RUN HEADER from the input stream // fMagicNumber = 0; fin.read((char*)&fMagicNumber, 2); // Total=2 // // check whether the the file has the right file type or not // if (fMagicNumber != kMagicNumber && fMagicNumber != kMagicNumber+1) { *fLog << err << "ERROR - Wrong Magic Number (0x" << hex << fMagicNumber << "): Not a Magic File!" << endl; return kFALSE; } if (fMagicNumber == kMagicNumber+1) *fLog << warn << "WARNING - This file maybe broken (0xc0c1) - DAQ didn't close it correctly!" << endl; // ----- File format version ----- fin.read((char*)&fFormatVersion, 2); // Total=4 if (fFormatVersion==10 || fFormatVersion>kMaxFormatVersion) { *fLog << err << "ERROR - File format V" << fFormatVersion << " not implemented!" << endl; return kFALSE; } // ----- Process old file formats ----- if (fFormatVersion<10) return ReadEvtOld(fin); // ----- Overwrite format version for format 11 ----- fin.read((char*)&fFormatVersion, 4); if (fFormatVersion<11) { *fLog << err << "ERROR - Format Version <11." << endl; return kFALSE; } // ----- Read Header by size as written in the header ----- fin.read((char*)&fHeaderSizeRun, 4); if (fHeaderSizeRun<346) { *fLog << err << "ERROR - Event header too small (<388b)." << endl; return kFALSE; } TArrayC h(fHeaderSizeRun-12); fin.read(h.GetArray(), h.GetSize()); if (!fin) return kFALSE; // ----- convert ----- const Byte_t *Char = reinterpret_cast(h.GetArray()); const UInt_t *Int = reinterpret_cast(h.GetArray()); //const Float_t *Float = reinterpret_cast(h.GetArray()); // ----- Start interpretation ----- fHeaderSizeEvt = Int[0]; fHeaderSizeCrate = Int[1]; fSoftVersion = Int[2]; fFadcType = Int[3]; fCameraVersion = Int[4]; fTelescopeNumber = Int[5]; fRunType = Int[6]; fRunNumber = Int[7]; fFileNumber = Int[8]; memcpy(fProjectName, Char+ 36, 100); // 25 memcpy(fSourceName, Char+136, 80); // 20 memcpy(fObservationMode, Char+216, 60); // 15 //F32 fSourceRA = Float[69]; //F32 fSourceDEC = Float[70]; //F32 fTelescopeRA = Float[71]; //F32 fTelescopeDEC = Float[72]; memcpy(fSourceEpochChar, Char+232, 4); fSourceEpochDate = Int[74]; fNumCrates = Int[75]; fNumPixInCrate = Int[76]; fNumSamplesHiGain = Int[77]; fNumSamplesLoGain = 0; //fNumSamplesRemovedHead = Int[78]; //fNumSamplesRemovedTail = Int[79]; fNumEvents = Int[80]; fNumEventsRead = Int[81]; fNumBytesPerSample = Int[82]; fSamplingFrequency = Int[83]; fFadcResolution = Int[84]; fRunStart.SetBinary(Int+85); fRunStop.SetBinary(Int+91); // ----- 388 bytes so far ----- const UInt_t n = fNumCrates*fNumPixInCrate; if (fHeaderSizeRun<388+n*4) { *fLog << err << "ERROR - Event header too small to contain pix assignment." << endl; return kFALSE; } // ----- Pixel Assignment ----- fPixAssignment->Set(n); for (UInt_t i=0; i(h.GetArray()); UInt_t *Int = reinterpret_cast(h.GetArray()); //const Float_t *Float = reinterpret_cast(h.GetArray()); // ----- Start interpretation ----- Int[0] = 0; // fHeaderSizeEvt; Int[1] = 0; // fHeaderSizeCrate; Int[2] = 0; // fSoftVersion; Int[3] = fFadcType; Int[4] = fCameraVersion; Int[5] = fTelescopeNumber; Int[5] = fRunType; Int[6] = fRunNumber; Int[7] = fFileNumber; memcpy(Char+ 36, fProjectName, 100); // 25 memcpy(Char+136, fSourceName, 80); // 20 memcpy(Char+216, fObservationMode, 60); // 15 //F32 fSourceRA = Float[69]; //F32 fSourceDEC = Float[70]; //F32 fTelescopeRA = Float[71]; //F32 fTelescopeDEC = Float[72]; memcpy(Char+232, fSourceEpochChar, 4); Int[74] = fSourceEpochDate; Int[75] = fNumCrates; Int[76] = fNumPixInCrate; Int[77] = fNumSamplesHiGain; //fNumSamplesRemovedHead = Int[78]; //fNumSamplesRemovedTail = Int[79]; Int[80] = fNumEvents; Int[81] = fNumEvents; //fNumEventsRead; Int[82] = fNumBytesPerSample; Int[83] = fSamplingFrequency; Int[84] = fFadcResolution; fRunStart.GetBinary(Int+85); fRunStop.GetBinary(Int+91); // ----- 388 bytes so far ----- //const UInt_t n = fNumCrates*fNumPixInCrate; //if (fHeaderSizeRun<(97+n)*4) //{ // *fLog << err << "ERROR - Event header too small to contain pix assignment." << endl; // return kFALSE; //} // ----- Pixel Assignment ----- for (UInt_t i=0; i"; default: return ""; } } Char_t MRawRunHeader::GetRunTypeChar() const { switch (fRunType&0xff) { case kRTData: case kRTPointRun: return 'D'; case kRTPedestal: return 'P'; case kRTCalibration: return 'C'; case kRTDominoCal: return 'L'; case kRTLinearity: return 'N'; default: return ' '; } } // -------------------------------------------------------------------------- // // print run header information on *fLog. The option 'header' supresses // the pixel index translation table. // void MRawRunHeader::Print(Option_t *t) const { *fLog << all << endl; *fLog << "MagicNumber: 0x" << hex << fMagicNumber << " - "; switch (fMagicNumber) { case kMagicNumber: *fLog << "OK"; break; case kMagicNumber+1: *fLog << "File not closed!"; break; default: *fLog << "Wrong!"; break; } *fLog << endl; *fLog << "Versions: " << dec << "Format="; if (fFormatVersion==0xf172) *fLog << "FITS[f172]"; else *fLog << fFormatVersion; *fLog << " Software=" << fSoftVersion << " "; if (fFormatVersion>5) { *fLog << "Camera="; if (fCameraVersion==0xfac7) *fLog << "FACT[fac7]"; else *fLog << fCameraVersion; } *fLog << endl; if (fFormatVersion>10 && fHeaderSizeRun>0 && fHeaderSizeEvt>0 && fHeaderSizeCrate>0) *fLog << "Header sizes: " << fHeaderSizeRun << "b (run), " << fHeaderSizeEvt << "b (evt), " << fHeaderSizeCrate << "b (crate)" << endl; if (fRunNumber>0) { if (fFormatVersion>5 && fTelescopeNumber>0) *fLog << "Telescope: " << fTelescopeNumber << endl; *fLog << "RunNumber: " << fRunNumber; if (fFormatVersion>10) *fLog << "/" << fFileNumber << " (id=" << GetFileID() << ")"; *fLog << " (Type=" << GetRunTypeStr() << ")" << endl; } if (fFormatVersion>7) { *fLog << "FadcType: " << fFadcType << " ("; switch (fFadcType) { case 1: *fLog << "Siegen"; break; case 2: *fLog << "MUX"; break; case 0xfac7: *fLog << "FACT DRS4"; break; case 0xffff: *fLog << "artificial"; break; default: *fLog << "unknown"; } *fLog << ")" << endl; } *fLog << "ProjectName: '" << fProjectName << "'" << endl; if (fFormatVersion>5) *fLog << "Observation: '" << fObservationMode << "'" << endl; if (fSourceName[0]!=0 || fSourceEpochChar[0]!=0 || fSourceEpochDate!=0) { *fLog << "Source: '" << fSourceName << "' " << " "; *fLog << fSourceEpochChar << dec << fSourceEpochDate << endl; } if (fRunStart) *fLog << "Run Start: " << fRunStart << endl; if (fRunStop) *fLog << "Run Stop: " << fRunStop << endl; if (fNumCrates>0 || fNumPixInCrate>0) *fLog << "Crates: " << fNumCrates << " x " << fNumPixInCrate << " Pixel/Crate = " << fNumCrates*fNumPixInCrate << " Pixel/Evt" << endl; if (GetNumConnectedPixels()>0) *fLog << "Num Pixels: " << GetNumNormalPixels() << " (normal) + " << GetNumSpecialPixels() << " (special) = " << GetNumConnectedPixels() << " (total)" << endl; if (fFormatVersion>6) *fLog << "Sampling: " << fSamplingFrequency << "MHz with " << (int)fFadcResolution << " significant bits" << endl; *fLog << "Samples: " << fNumSamplesHiGain << "/" << fNumSamplesLoGain << " (hi/lo) * " << fNumBytesPerSample << "B/sample = "; if (fNumCrates>0) *fLog << (fNumSamplesLoGain+fNumSamplesHiGain) * fNumCrates * fNumPixInCrate * fNumBytesPerSample/1000 << "kB/Evt" << endl; else *fLog << (fNumSamplesLoGain+fNumSamplesHiGain) * fNumBytesPerSample << "B/pix" << endl; if (fNumEvents>0 || fNumEventsRead>0) { *fLog << "Evt Counter: " << fNumEvents; if (fFormatVersion>8) *fLog << " (read=" << fNumEventsRead << ")"; *fLog << endl; } if (TString(t).Contains("header", TString::kIgnoreCase)) return; *fLog << inf3 << "Assignment:" << hex << endl; for (int i=0; iGetSize(); UShort_t rc = 0; for (int i=0; i0) // UShort_t MRawRunHeader::GetNumNormalPixels() const { const Int_t num = fPixAssignment->GetSize(); UShort_t rc = 0; for (int i=0; i0) rc++; } return rc; } // -------------------------------------------------------------------------- // // Return the number of pixel which are markes as connected and so-called // 'special' pixels in the pix assignment (<0) // UShort_t MRawRunHeader::GetNumSpecialPixels() const { const Int_t num = fPixAssignment->GetSize(); UShort_t rc = 0; for (int i=0; iGetSize(); Short_t rc = 0; for (int i=0; iGetSize(); Short_t rc = 0; for (int i=0; iGetSize(); } // -------------------------------------------------------------------------- // // Returns absolute size in bytes of the run header as read from a raw file. // This must be done _after_ the header is read, because the header doesn't // have a fixed size (used in MRawSocketRead) // Int_t MRawRunHeader::GetNumTotalBytes() const { switch (fFormatVersion) { case 1: return 80+fNumCrates*fNumPixInCrate*2+16; case 2: case 3: case 4: case 5: return 84+fNumCrates*fNumPixInCrate*2+16; case 6: return 84+fNumCrates*fNumPixInCrate*2+16 +4+78+58+60+8; case 7: return 84+fNumCrates*fNumPixInCrate*2+16 +4+78+58+60+8 +3-16; } return 0; } // -------------------------------------------------------------------------- // // Monte Carlo Interface // // This is a (prelimiary) way to setup an existing FADC system. // // 1: Siegen FADCs // 2: MUX FADCs // void MRawRunHeader::InitFadcType(UShort_t type) { switch (type) { case 1: fNumSamplesHiGain = 15; fNumSamplesLoGain = 15; fNumBytesPerSample = 1; // number of bytes per sample fSamplingFrequency = 300; // Sampling Frequency [MHz] fFadcResolution = 8; // number of significant bits break; case 2: fNumSamplesHiGain = 50; fNumSamplesLoGain = 0; fNumBytesPerSample = 2; // number of bytes per sample fSamplingFrequency = 2000; // Sampling Frequency [MHz] fFadcResolution = 12; // number of significant bits break; case 3: fNumSamplesHiGain = 150; fNumSamplesLoGain = 0; fNumBytesPerSample = 2; // number of bytes per sample fSamplingFrequency = 1000; // Sampling Frequency [MHz] fFadcResolution = 12; // number of significant bits break; } fFadcType = type; } // -------------------------------------------------------------------------- // // Monte Carlo Interface // // Init a camera // void MRawRunHeader::InitCamera(UShort_t type, UShort_t pix) { switch (type) { case 1: fNumCrates = 1; fNumPixInCrate = 577; break; case 2: fNumCrates = 1; fNumPixInCrate = 703; break; case (UShort_t)-1: fNumCrates = 1; fNumPixInCrate = pix; break; } fCameraVersion = type; const Int_t n = fNumCrates*fNumPixInCrate; fPixAssignment->Set(n); for (int i=0; iSet(num*pix); if (map) for (int i=0; i