#include #include "Dim.h" #include "Event.h" #include "Shell.h" #include "StateMachineDim.h" #include "Connection.h" #include "Configuration.h" #include "Console.h" #include "Converter.h" #include "DimServiceInfoList.h" //#include "PixelMap.h" #include "tools.h" #include "LocalControl.h" #include "HeadersFTM.h" namespace ba = boost::asio; namespace bs = boost::system; namespace dummy = ba::placeholders; using namespace std; // ------------------------------------------------------------------------ #include "DimDescriptionService.h" // ------------------------------------------------------------------------ class StateMachineRateControl : public StateMachineDim, public DimInfoHandler { private: enum states_t { kStateDimNetworkNA = 1, kStateDisconnected, kStateConnecting, kStateConnected, kStateSettingGlobalThreshold, kStateGlobalThresholdSet, kStateInProgress, }; DimServiceInfoList fNetwork; pair fStatusDim; pair fStatusFTM; pair fStatusRS; DimStampedInfo fDim; DimStampedInfo fFTM; DimStampedInfo fRates; DimStampedInfo fStatic; DimStampedInfo fRateScan; // DimDescribedService fDimData; // DimDescribedService fDimProc; float fTargetRate; float fTriggerRate; uint16_t fThresholdMin; uint16_t fThresholdReference; bool fTriggerOn; bool fVerbose; bool fEnabled; uint64_t fCounter; pair GetNewState(DimStampedInfo &info) const { const bool disconnected = info.getSize()==0; // Make sure getTimestamp is called _before_ getTimestampMillisecs const int tsec = info.getTimestamp(); const int tms = info.getTimestampMillisecs(); return make_pair(Time(tsec, tms*1000), disconnected ? -2 : info.getQuality()); } bool CheckEventSize(size_t has, const char *name, size_t size) { if (has==size) return true; if (has==0) return false; ostringstream msg; msg << name << " - Received event has " << has << " bytes, but expected " << size << "."; Fatal(msg); return false; } vector fThresholds; void PrintThresholds(const FTM::DimStaticData &sdata) { //if (!fVerbose) // return; if (fThresholds.size()==0) return; Out() << "Min. DAC=" << fThresholdMin << endl; int t=0; for (t=0; t<160; t++) if (sdata.fThreshold[t]!=fThresholds[t]) break; if (t==160) return; for (int j=0; j<10; j++) { for (int k=0; k<4; k++) { for (int i=0; i<4; i++) if (fThresholds[i+k*4+j*16]!=fThresholdMin) Out() << setw(3) << fThresholds[i+k*4+j*16] << " "; else Out() << " - "; Out() << " "; } Out() << endl; } Out() << endl; } void Step(int idx, float step) { uint16_t diff = fThresholds[idx]+int16_t(truncf(step)); if (diff0 ? " += " : " -= "); Out() << step << " (" << diff << ")" << endl; } const uint32_t val[2] = { idx, diff }; DimClient::sendCommandNB("FTM_CONTROL/SET_THRESHOLD", (void*)val, 8); } void ProcessPatches(const FTM::DimTriggerRates &sdata) { // Caluclate Median and deviation vector medb(sdata.fBoardRate, sdata.fBoardRate+40); vector medp(sdata.fPatchRate, sdata.fPatchRate+160); sort(medb.begin(), medb.end()); sort(medp.begin(), medp.end()); vector devb(40); for (int i=0; i<40; i++) devb[i] = fabs(sdata.fBoardRate[i]-medb[i]); vector devp(160); for (int i=0; i<160; i++) devp[i] = fabs(sdata.fPatchRate[i]-medp[i]); sort(devb.begin(), devb.end()); sort(devp.begin(), devp.end()); double mb = (medb[19]+medb[20])/2; double mp = (medp[79]+medp[80])/2; double db = devb[27]; double dp = devp[109]; // If any is zero there is something wrong if (mb==0 || mp==0 || db==0 || dp==0) return; if (fVerbose) { Out() << "Patch: Median=" << mp << " Dev=" << dp << endl; Out() << "Board: Median=" << mb << " Dev=" << db << endl; } for (int i=0; i<40; i++) { int maxi = -1; const float dif = fabs(sdata.fBoardRate[i]-mb)/db; if (dif>5) { if (fVerbose) Out() << "B" << i << ": " << dif << endl; float max = sdata.fPatchRate[i*4]; maxi = 0; for (int j=1; j<4; j++) if (sdata.fPatchRate[i*4+j]>max) { max = sdata.fPatchRate[i*4+j]; maxi = j; } } for (int j=0; j<4; j++) { // For the noise pixel correct down to median+3*deviation if (maxi==j) { // This is the step which has to be performed to go from // a NSB rate of sdata.fPatchRate[i*4+j] const float step = (log10(sdata.fPatchRate[i*4+j])-log10(mp+5*dp))/0.039; // * (dif-5)/dif Step(i*4+j, step); continue; } // For pixels below the meadian correct also back to median+3*deviation if (sdata.fPatchRate[i*4+j] medb(sdata.fBoardRate, sdata.fBoardRate+40); sort(medb.begin(), medb.end()); vector devb(40); for (int i=0; i<40; i++) devb[i] = fabs(sdata.fBoardRate[i]-medb[i]); sort(devb.begin(), devb.end()); double mb = (medb[19]+medb[20])/2; double db = devb[27]; // If any is zero there is something wrong if (mb==0 || db==0) { Warn("The median or the deviation of all board rates is zero... cannot calibrate."); return; } double avg = 0; int num = 0; for (int i=0; i<40; i++) { if ( fabs(sdata.fBoardRate[i]-mb)<2.5*db) { avg += sdata.fBoardRate[i]; num++; } } fTriggerRate = avg/num * 40; if (fVerbose) { Out() << "Board: Median=" << mb << " Dev=" << db << endl; Out() << "Camera: " << fTriggerRate << " (" << sdata.fTriggerRate << ", n=" << num << ")" << endl; Out() << "Target: " << fTargetRate << endl; } if (sdata.fTriggerRate<0) fTriggerRate = sdata.fTriggerRate; // ---------------------- /* if (avg>0 && avg0 && fTriggerRate0 ? " += " : " -= "); Out() << step << " (" << diff << ")" << endl; } const uint32_t val[2] = { -1, diff }; DimClient::sendCommandNB("FTM_CONTROL/SET_THRESHOLD", (void*)val, 8); fThresholdMin = diff; } void infoHandler() { DimInfo *curr = getInfo(); // get current DimInfo address if (!curr) return; if (curr==&fFTM) { fStatusFTM = GetNewState(fFTM); return; } if (curr==&fDim) { fStatusDim = GetNewState(fDim); fStatusDim.second = curr->getSize()==4 ? curr->getInt() : 0; return; } if (curr==&fRateScan) { fStatusRS = GetNewState(fRateScan); fStatusRS.second = curr->getSize()==4 ? curr->getInt() : 0; return; } static vector counter(160); if (curr==&fStatic) { if (!CheckEventSize(curr->getSize(), "infoHandler[DimStaticData]", sizeof(FTM::DimStaticData))) return; const FTM::DimStaticData &sdata = *static_cast(curr->getData()); fTriggerOn = sdata.HasTrigger(); PrintThresholds(sdata); fThresholds.assign(sdata.fThreshold, sdata.fThreshold+160); return; } if (curr==&fRates) { if (fThresholds.size()==0) return; if (!fTriggerOn && !fEnabled) return; if (fStatusRS.second==5) return; if (!CheckEventSize(curr->getSize(), "infoHandler[DimTriggerRates]", sizeof(FTM::DimTriggerRates))) return; const FTM::DimTriggerRates &sdata = *static_cast(curr->getData()); if (GetCurrentState()==kStateSettingGlobalThreshold) ProcessCamera(sdata); if (GetCurrentState()==kStateInProgress) ProcessPatches(sdata); } } int Calibrate() { if (!fTriggerOn) return kStateGlobalThresholdSet; const int32_t val[2] = { -1, fThresholdReference }; Dim::SendCommand("FTM_CONTROL/SET_THRESHOLD", val); fThresholds.assign(160, fThresholdReference); fThresholdMin = fThresholdReference; fTriggerRate = -1; fEnabled = true; fCounter = 0; return kStateSettingGlobalThreshold; } int StartRC() { fEnabled = true; return GetCurrentState(); } int StopRC() { fEnabled = false; return GetCurrentState(); } int SetEnabled(const EventImp &evt) { if (!CheckEventSize(evt.GetSize(), "SetEnabled", 1)) return kSM_FatalError; fEnabled = evt.GetBool(); return GetCurrentState(); } int SetMinThreshold(const EventImp &evt) { if (!CheckEventSize(evt.GetSize(), "SetMinThreshold", 4)) return kSM_FatalError; // FIXME: Check missing fThresholdReference = evt.GetUShort(); return GetCurrentState(); } int SetTargetRate(const EventImp &evt) { if (!CheckEventSize(evt.GetSize(), "SetTargetRate", 4)) return kSM_FatalError; fTargetRate = evt.GetFloat(); return GetCurrentState(); } void PrintState(const pair &state, const char *server) { const State rc = fNetwork.GetState(server, state.second); Out() << state.first.GetAsStr("%H:%M:%S.%f").substr(0, 12) << " - "; Out() << kBold << server << ": "; Out() << rc.name << "[" << rc.index << "]"; Out() << kReset << " - " << kBlue << rc.comment << endl; } int Print() { Out() << fStatusDim.first.GetAsStr("%H:%M:%S.%f").substr(0, 12) << " - "; Out() << kBold << "DIM_DNS: "; if (fStatusDim.second==0) Out() << "Offline" << endl; else Out() << "V" << fStatusDim.second/100 << 'r' << fStatusDim.second%100 << endl; PrintState(fStatusFTM, "FTM_CONTROL"); return GetCurrentState(); } int SetVerbosity(const EventImp &evt) { if (!CheckEventSize(evt.GetSize(), "SetVerbosity", 1)) return kSM_FatalError; fVerbose = evt.GetBool(); return GetCurrentState(); } int Execute() { // Dispatch (execute) at most one handler from the queue. In contrary // to run_one(), it doesn't wait until a handler is available // which can be dispatched, so poll_one() might return with 0 // handlers dispatched. The handlers are always dispatched/executed // synchronously, i.e. within the call to poll_one() //poll_one(); if (fStatusDim.second==0) return kStateDimNetworkNA; // All subsystems are not connected if (fStatusFTM.secondfTargetRate) return kStateSettingGlobalThreshold; return kStateGlobalThresholdSet; } if (GetCurrentState()==kStateGlobalThresholdSet) { if (!fTriggerOn) return kStateGlobalThresholdSet; //return kStateInProgress; } // At least one subsystem is not connected // if (fStatusFTM.second>=FTM::kConnected) return fTriggerOn && fEnabled && fStatusRS.second!=5 ? kStateInProgress : kStateConnected; } public: StateMachineRateControl(ostream &out=cout) : StateMachineDim(out, "RATE_CONTROL"), fStatusDim(make_pair(Time(), -2)), fStatusFTM(make_pair(Time(), -2)), fDim("DIS_DNS/VERSION_NUMBER", (void*)NULL, 0, this), fFTM("FTM_CONTROL/STATE", (void*)NULL, 0, this), fRates("FTM_CONTROL/TRIGGER_RATES", (void*)NULL, 0, this), fStatic("FTM_CONTROL/STATIC_DATA", (void*)NULL, 0, this)/*, fDimData("RATE_SCAN/DATA", "I:1;F:1;F:1;F:1;F:40;F:160", ""), fDimProc("RATE_SCAN/PROCESS_DATA", "I:1;I:1;I:1", "Rate scan process data" "|min[DAC]:Value at which scan was started" "|max[DAC]:Value at which scan will end" "|step[DAC]:Step size for scan")*/, fTriggerOn(false) { // ba::io_service::work is a kind of keep_alive for the loop. // It prevents the io_service to go to stopped state, which // would prevent any consecutive calls to run() // or poll() to do nothing. reset() could also revoke to the // previous state but this might introduce some overhead of // deletion and creation of threads and more. // State names AddStateName(kStateDimNetworkNA, "DimNetworkNotAvailable", "The Dim DNS is not reachable."); AddStateName(kStateDisconnected, "Disconnected", "The Dim DNS is reachable, but the required subsystems are not available."); AddStateName(kStateConnected, "Connected", "All needed subsystems are connected to their hardware, no action is performed."); AddStateName(kStateSettingGlobalThreshold, "Calibrating", ""); AddStateName(kStateGlobalThresholdSet, "GlobalThresholdSet", ""); AddStateName(kStateInProgress, "InProgress", "Rate scan in progress."); AddEvent("CALIBRATE") (bind(&StateMachineRateControl::Calibrate, this)) (""); AddEvent("START", "") (bind(&StateMachineRateControl::StartRC, this)) (""); AddEvent("STOP", "") (bind(&StateMachineRateControl::StopRC, this)) (""); AddEvent("SET_MIN_THRESHOLD", "I:1") (bind(&StateMachineRateControl::SetMinThreshold, this, placeholders::_1)) (""); AddEvent("SET_TARGET_RATE", "F:1") (bind(&StateMachineRateControl::SetTargetRate, this, placeholders::_1)) (""); AddEvent("PRINT") (bind(&StateMachineRateControl::Print, this)) (""); AddEvent("SET_VERBOSE", "B") (bind(&StateMachineRateControl::SetVerbosity, this, placeholders::_1)) ("set verbosity state" "|verbosity[bool]:disable or enable verbosity for received data (yes/no), except dynamic data"); } int EvalOptions(Configuration &conf) { fVerbose = !conf.Get("quiet"); fThresholdReference = 300; fTargetRate = 75; return -1; } }; // ------------------------------------------------------------------------ #include "Main.h" template int RunShell(Configuration &conf) { return Main::execute(conf); } void SetupConfiguration(Configuration &conf) { po::options_description control("Rate scan options"); control.add_options() ("quiet,q", po_bool(), "Disable printing more informations during rate control.") //("max-wait", var(150), "The maximum number of seconds to wait to get the anticipated resolution for a point.") // ("resolution", var(0.05) , "The minimum resolution required for a single data point.") ; conf.AddOptions(control); } /* 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 << "The ratescan program is a tool for automation of rate scans.\n" "\n" "Usage: ratescan [-c type] [OPTIONS]\n" " or: ratescan [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; */ } int main(int argc, const char* argv[]) { Configuration conf(argv[0]); conf.SetPrintUsage(PrintUsage); Main::SetupConfiguration(conf); SetupConfiguration(conf); if (!conf.DoParse(argc, argv, PrintHelp)) return -1; //try { // No console access at all if (!conf.Has("console")) { // if (conf.Get("no-dim")) // return RunShell(conf); // else return RunShell(conf); } // Cosole access w/ and w/o Dim /* if (conf.Get("no-dim")) { if (conf.Get("console")==0) return RunShell(conf); else return RunShell(conf); } else */ { if (conf.Get("console")==0) return RunShell(conf); else return RunShell(conf); } } /*catch (std::exception& e) { cerr << "Exception: " << e.what() << endl; return -1; }*/ return 0; }