#include #include #include "Dim.h" #include "Event.h" #include "Shell.h" #include "StateMachineDim.h" #include "Connection.h" #include "Configuration.h" #include "Console.h" #include "tools.h" #include "zfits.h" namespace ba = boost::asio; namespace bs = boost::system; using namespace std; // ------------------------------------------------------------------------ #include "DimDescriptionService.h" #include "DimState.h" // ------------------------------------------------------------------------ void SetupConfiguration(Configuration &conf) { po::options_description control("Program options"); control.add_options() ("target,t", var()->required(), "") ("event,e", var(), "") ; po::positional_options_description p; p.add("target", 1); // The first positional options p.add("event", 2); // The second positional options conf.AddOptions(control); conf.SetArgumentPositions(p); } /* Extract usage clause(s) [if any] for SYNOPSIS. Translators: "Usage" and "or" here are patterns (regular expressions) which are used to match the usage synopsis in program output. An example from cp (GNU coreutils) which contains both strings: Usage: cp [OPTION]... [-T] SOURCE DEST or: cp [OPTION]... SOURCE... DIRECTORY or: cp [OPTION]... -t DIRECTORY SOURCE... */ void PrintUsage() { cout << "Retrieve an event from a file in binary representation.\n" "\n" "Usage: getevent [-c type] [OPTIONS]\n" " or: getevent [OPTIONS]\n"; cout << endl; } void PrintHelp() { //Main::PrintHelp(); /* Additional help text which is printed after the configuration options goes here */ /* cout << "bla bla bla" << endl << endl; cout << endl; cout << "Environment:" << endl; cout << "environment" << endl; cout << endl; cout << "Examples:" << endl; cout << "test exam" << endl; cout << endl; cout << "Files:" << endl; cout << "files" << endl; cout << endl; */ } /* boost::filesystem::recursive_directory_iterator createRIterator(boost::filesystem::path path) { try { return boost::filesystem::recursive_directory_iterator(path); } catch(boost::filesystem::filesystem_error& fex) { std::cout << fex.what() << std::endl; return boost::filesystem::recursive_directory_iterator(); } } void dump(boost::filesystem::path path, int level) { try { std::cout << (boost::filesystem::is_directory(path) ? 'D' : ' ') << ' '; std::cout << (boost::filesystem::is_symlink(path) ? 'L' : ' ') << ' '; for(int i = 0; i < level; ++i) std::cout << ' '; std::cout << path.filename() << std::endl; } catch(boost::filesystem::filesystem_error& fex) { std::cout << fex.what() << std::endl; } } void plainListTree(boost::filesystem::path path) // 1. { dump(path, 0); boost::filesystem::recursive_directory_iterator it = createRIterator(path); boost::filesystem::recursive_directory_iterator end; while(it != end) // 2. { dump(*it, it.level()); // 3. if (boost::filesystem::is_directory(*it) && boost::filesystem::is_symlink(*it)) // 4. it.no_push(); try { ++it; // 5. } catch(std::exception& ex) { std::cout << ex.what() << std::endl; it.no_push(); // 6. try { ++it; } catch(...) { std::cout << "!!" << std::endl; return; } // 7. } } } */ int main(int argc, const char* argv[]) { Configuration conf(argv[0]); conf.SetPrintUsage(PrintUsage); SetupConfiguration(conf); if (!conf.DoParse(argc, argv, PrintHelp)) return 127; const string name = conf.Get("target"); /* if (!conf.Has("event")) { plainListTree(name); return 0; } */ const uint32_t event = conf.Has("event") ? conf.Get("event") : 0; zfits file(name); if (!file) { cerr << name << ": " << strerror(errno) << endl; return 1; } // Php can only read 32bit ints const uint32_t nRows = file.GetNumRows(); const uint32_t nRoi = file.GetUInt("NROI"); const uint32_t nPix = file.GetUInt("NPIX"); const bool isMC = file.HasKey("ISMC") && file.GetStr("ISMC")=="T"; // Is drs calibration file? const int8_t step = file.HasKey("STEP") ? file.GetUInt("STEP") : -1; const string strbeg = isMC ? "DATE" : "RUN"+to_string(step)+"-BEG"; const string strend = isMC ? "DATE" : "RUN"+to_string(step)+"-END"; const double start = step==-1 && !isMC ? file.GetUInt("TSTARTI")+file.GetFloat("TSTARTF") : Time(file.GetStr(strbeg)).UnixDate(); const double stop = step==-1 && !isMC ? file.GetUInt("TSTOPI")+file.GetFloat("TSTOPF") : Time(file.GetStr(strend)).UnixDate(); const bool isDrsCalib = file.HasKey("DRSCALIB") && file.GetStr("DRSCALIB")=="T"; const int16_t drsStep = isDrsCalib ? file.GetUInt("DRSSTEP") : step; const string runType = step==-1 ? file.GetStr("RUNTYPE") : ""; const uint16_t scale = file.HasKey("SCALE") ? file.GetUInt("SCALE") : (step==-1?0:10); vector run(80); vector data(nRoi*nPix); vector mean(nRoi*nPix); vector unixTimeUTC(2); //uint32_t boardTime[40]; uint32_t eventNum; //uint32_t numBoards; //uint16_t startCellData[1440]; //uint16_t startCellTimeMarker[160]; //uint32_t triggerNum; uint16_t triggerType; if (step==-1) { file.SetRefAddress("EventNum", eventNum); //file.SetRefAddress("TriggerNum", triggerNum); file.SetRefAddress("TriggerType", triggerType); if (!isMC) file.SetVecAddress("UnixTimeUTC", unixTimeUTC); } float energy, impact, phi, theta; if (isMC) { file.SetRefAddress("MMcEvtBasic.fEnergy", energy); file.SetRefAddress("MMcEvtBasic.fImpact", impact); file.SetRefAddress("MMcEvtBasic.fTelescopeTheta", theta); file.SetRefAddress("MMcEvtBasic.fTelescopePhi", phi); } switch (step) { case 0: file.SetVecAddress("BaselineMean", mean); strcpy( run.data(), "DRS (pedestal 1024)"); break; case 1: file.SetVecAddress("GainMean", mean); strcpy( run.data(), "DRS (gain)"); break; case 2: file.SetVecAddress("TriggerOffsetMean", mean); strcpy( run.data(), "DRS (pedestal roi)"); break; default: file.SetVecAddress("Data", data); strncpy(run.data(), runType.c_str(), 79); break; } if (!file.GetRow(step==-1 ? event : 0)) return 2; if (step!=-1) for (uint32_t i=0; i