#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 "HeadersFAD.h" #include "tools.h" #include "DimDescriptionService.h" #include "EventBuilderWrapper.h" namespace ba = boost::asio; namespace bs = boost::system; using ba::ip::tcp; using namespace std; // ------------------------------------------------------------------------ class ConnectionFAD : public Connection { uint16_t fSlot; // tcp::endpoint fEndpoint; vector fBuffer; protected: FAD::EventHeader fEventHeader; FAD::ChannelHeader fChannelHeader[FAD::kNumChannels]; private: bool fIsVerbose; bool fIsHexOutput; bool fIsDataOutput; bool fBlockTransmission; uint64_t fCounter; FAD::EventHeader fBufEventHeader; vector fTargetRoi; protected: void PrintEventHeader() { Out() << endl << kBold << "Header received (N=" << dec << fCounter << "):" << endl; Out() << fEventHeader; if (fIsHexOutput) Out() << Converter::GetHex(fEventHeader, 16) << endl; } void PrintChannelHeaders() { Out() << dec << endl; for (unsigned int c=0; c(fChannelHeader, 16) << endl; } virtual void UpdateFirstHeader() { } virtual void UpdateEventHeader() { // emit service with trigger counter from header if (fIsVerbose) PrintEventHeader(); } virtual void UpdateChannelHeaders() { // emit service with trigger counter from header if (fIsVerbose) PrintChannelHeaders(); } virtual void UpdateData(const uint16_t *data, size_t sz) { // emit service with trigger counter from header if (fIsVerbose && fIsDataOutput) Out() << Converter::GetHex(data, sz, 16, true) << endl; } private: enum { kReadHeader = 1, kReadData = 2, }; void HandleReceivedData(const bs::error_code& err, size_t bytes_received, int type) { // Do not schedule a new read if the connection failed. if (bytes_received==0 || err) { if (err==ba::error::eof) Warn("Connection closed by remote host (FAD)."); // 107: Transport endpoint is not connected (bs::error_code(107, bs::system_category)) // 125: Operation canceled if (err && err!=ba::error::eof && // Connection closed by remote host err!=ba::error::basic_errors::not_connected && // Connection closed by remote host err!=ba::error::basic_errors::operation_aborted) // Connection closed by us { ostringstream str; str << "Reading from " << URL() << ": " << err.message() << " (" << err << ")";// << endl; Error(str); } PostClose(err!=ba::error::basic_errors::operation_aborted); return; } EventBuilderWrapper::This->debugStream(fSlot*7, fBuffer.data(), bytes_received); if (type==kReadHeader) { if (bytes_received!=sizeof(FAD::EventHeader)) { ostringstream str; str << "Bytes received (" << bytes_received << " don't match header size " << sizeof(FAD::EventHeader); Error(str); PostClose(false); return; } fEventHeader = fBuffer; if (fEventHeader.fStartDelimiter!=FAD::kDelimiterStart) { ostringstream str; str << "Invalid header received: start delimiter wrong, received "; str << hex << fEventHeader.fStartDelimiter << ", expected " << FAD::kDelimiterStart << "."; Error(str); PostClose(false); return; } if (fCounter==0) UpdateFirstHeader(); UpdateEventHeader(); EventBuilderWrapper::This->debugHead(fSlot*7, fEventHeader); fBuffer.resize(fEventHeader.fPackageLength-sizeof(FAD::EventHeader)/2); AsyncRead(ba::buffer(fBuffer), kReadData); AsyncWait(fInTimeout, 2000, &Connection::HandleReadTimeout); return; } fInTimeout.cancel(); if (ntohs(fBuffer.back())!=FAD::kDelimiterEnd) { ostringstream str; str << "Invalid data received: end delimiter wrong, received "; str << hex << ntohs(fBuffer.back()) << ", expected " << FAD::kDelimiterEnd << "."; Error(str); PostClose(false); return; } uint8_t *ptr = reinterpret_cast(fBuffer.data()); uint8_t *end = ptr + fBuffer.size()*2; for (unsigned int i=0; i end) { Error("Channel header exceeds buffer size."); PostClose(false); return; } fChannelHeader[i] = vector((uint16_t*)ptr, (uint16_t*)ptr+sizeof(FAD::ChannelHeader)/2); ptr += sizeof(FAD::ChannelHeader); //UpdateChannelHeader(i); if (ptr+fChannelHeader[i].fRegionOfInterest*2 > end) { Error("Data block exceeds buffer size."); PostClose(false); return; } const uint16_t *data = reinterpret_cast(ptr); UpdateData(data, fChannelHeader[i].fRegionOfInterest*2); ptr += fChannelHeader[i].fRegionOfInterest*2; } if (fIsVerbose) UpdateChannelHeaders(); fCounter++; fBuffer.resize(sizeof(FAD::EventHeader)/2); AsyncRead(ba::buffer(fBuffer), kReadHeader); } void HandleReadTimeout(const bs::error_code &error) { if (error==ba::error::basic_errors::operation_aborted) return; if (error) { ostringstream str; str << "Read timeout of " << URL() << ": " << error.message() << " (" << error << ")";// << endl; Error(str); PostClose(); return; } if (!is_open()) { // For example: Here we could schedule a new accept if we // would not want to allow two connections at the same time. return; } // Check whether the deadline has passed. We compare the deadline // against the current time since a new asynchronous operation // may have moved the deadline before this actor had a chance // to run. if (fInTimeout.expires_at() > ba::deadline_timer::traits_type::now()) return; Error("Timeout reading data from "+URL()); PostClose(); } // This is called when a connection was established void ConnectionEstablished() { fBufEventHeader.clear(); fBufEventHeader.fEventCounter = 1; fBufEventHeader.fStatus = 0xf000| FAD::EventHeader::kDenable| FAD::EventHeader::kDwrite| FAD::EventHeader::kDcmLocked| FAD::EventHeader::kDcmReady| FAD::EventHeader::kSpiSclk; fEventHeader.clear(); for (unsigned int i=0; i cmd) { if (fBlockTransmission || !IsConnected()) return; #ifdef DEBUG_TX ostringstream msg; msg << "Sending command:" << hex; msg << " 0x" << setw(4) << setfill('0') << cmd[0]; msg << " (+ " << cmd.size()-1 << " bytes data)"; Message(msg); #endif transform(cmd.begin(), cmd.end(), cmd.begin(), htons); PostMessage(cmd); } void PostCmd(uint16_t cmd) { if (fBlockTransmission || !IsConnected()) return; #ifdef DEBUG_TX ostringstream msg; msg << "Sending command:" << hex; msg << " 0x" << setw(4) << setfill('0') << cmd; Message(msg); #endif cmd = htons(cmd); PostMessage(&cmd, sizeof(uint16_t)); } void PostCmd(uint16_t cmd, uint16_t data) { if (fBlockTransmission || !IsConnected()) return; #ifdef DEBUG_TX ostringstream msg; msg << "Sending command:" << hex; msg << " 0x" << setw(4) << setfill('0') << cmd; msg << " 0x" << setw(4) << setfill('0') << data; Message(msg); #endif const uint16_t d[2] = { htons(cmd), htons(data) }; PostMessage(d, sizeof(d)); } public: ConnectionFAD(ba::io_service& ioservice, MessageImp &imp, uint16_t slot) : Connection(ioservice, imp()), fSlot(slot), fIsVerbose(false), fIsHexOutput(false), fIsDataOutput(false), fBlockTransmission(false), fCounter(0), fTargetRoi(FAD::kNumChannels) { // Maximum possible needed space: // The full header, all channels with all DRS bins // Two trailing shorts fBuffer.reserve(sizeof(FAD::EventHeader) + FAD::kNumChannels*(sizeof(FAD::ChannelHeader) + FAD::kMaxBins*sizeof(uint16_t)) + 2*sizeof(uint16_t)); SetLogStream(&imp); } void Cmd(FAD::Enable cmd, bool on=true) { switch (cmd) { case FAD::kCmdDrsEnable: fBufEventHeader.Enable(FAD::EventHeader::kDenable, on); break; case FAD::kCmdDwrite: fBufEventHeader.Enable(FAD::EventHeader::kDwrite, on); break; case FAD::kCmdTriggerLine: fBufEventHeader.Enable(FAD::EventHeader::kTriggerLine, on); break; case FAD::kCmdBusyOn: fBufEventHeader.Enable(FAD::EventHeader::kBusyOn, on); break; case FAD::kCmdBusyOff: fBufEventHeader.Enable(FAD::EventHeader::kBusyOff, on); break; case FAD::kCmdContTrigger: fBufEventHeader.Enable(FAD::EventHeader::kContTrigger, on); break; case FAD::kCmdSocket: fBufEventHeader.Enable(FAD::EventHeader::kSock17, !on); break; default: break; } PostCmd(cmd + (on ? 0 : 0x100)); } // ------------------------------ // IMPLEMENT: Abs/Rel void CmdPhaseShift(int16_t val) { vector cmd(abs(val)+2, FAD::kCmdPhaseApply); cmd[0] = FAD::kCmdPhaseReset; cmd[1] = val<0 ? FAD::kCmdPhaseDecrease : FAD::kCmdPhaseIncrease; PostCmd(cmd); } bool CmdSetTriggerRate(int32_t val) { if (val<0 || val>0xffff) return false; fBufEventHeader.fTriggerGeneratorPrescaler = val; PostCmd(FAD::kCmdWriteRate, val);//uint8_t(1000./val/12.5)); //PostCmd(FAD::kCmdWriteExecute); return true; } void CmdSetRunNumber(uint32_t num) { fBufEventHeader.fRunNumber = num; PostCmd(FAD::kCmdWriteRunNumberLSW, num&0xffff); PostCmd(FAD::kCmdWriteRunNumberMSW, num>>16); PostCmd(FAD::kCmdWriteExecute); } void CmdSetRegister(uint8_t addr, uint16_t val) { // Allowed addr: [0, MAX_ADDR] // Allowed value: [0, MAX_VAL] PostCmd(FAD::kCmdWrite + addr, val); PostCmd(FAD::kCmdWriteExecute); } bool CmdSetDacValue(int8_t addr, uint16_t val) { if (addr<0) { for (unsigned int i=0; i<=FAD::kMaxDacAddr; i++) { fBufEventHeader.fDac[i] = val; PostCmd(FAD::kCmdWriteDac + i, val); } PostCmd(FAD::kCmdWriteExecute); return true; } if (uint8_t(addr)>FAD::kMaxDacAddr) // NDAC return false; fBufEventHeader.fDac[addr] = val; PostCmd(FAD::kCmdWriteDac + addr, val); PostCmd(FAD::kCmdWriteExecute); return true; } bool CmdSetRoi(int8_t addr, uint16_t val) { if (val>FAD::kMaxRoiValue) return false; if (addr<0) { for (unsigned int i=0; i<=FAD::kMaxRoiAddr; i++) { fTargetRoi[i] = val; PostCmd(FAD::kCmdWriteRoi + i, val); } PostCmd(FAD::kCmdWriteExecute); return true; } if (uint8_t(addr)>FAD::kMaxRoiAddr) return false; fTargetRoi[addr] = val; PostCmd(FAD::kCmdWriteRoi + addr, val); PostCmd(FAD::kCmdWriteExecute); return true; } bool CmdSetRoi(uint16_t val) { return CmdSetRoi(-1, val); } void AmplitudeCalibration() { // ------------- case baseline ----------------- CmdSetRoi(-1, FAD::kMaxBins); CmdSetDacValue(1, 0); CmdSetDacValue(2, 0); CmdSetDacValue(3, 0); // Take N events /* // ====== Part B: Baseline calibration ===== // Loop over all channels(ch) and time-slices (t) T0 = TriggerCell[chip] Sum[ch][(t+T0) % kMaxBins] += Data[ch][t]; // FIXME: Determine median instead of average Baseline[ch][slice] = MEDIAN( sum[ch][slice] ) */ // --------------- case gain ------------------- // Set new DAC values and start accumulation CmdSetDacValue(1, 50000); CmdSetDacValue(2, 50000); CmdSetDacValue(3, 50000); // Take N events /* // ====== Part C: Gain calibration ===== T0 = TriggerCell[chip] Sum[ch][(t+T0) % kMaxBins] += Data[ch][t]; // FIXME: Determine median instead of average Gain[ch][slice] = MEDIAN( sum[ch][slice] ) - Baseline[ch][slice] */ // --------------- secondary ------------------ // FIXME: Can most probably be done together with the baseline calibration // FIXME: Why does the secondary baseline not influence the baseline? CmdSetDacValue(1, 0); CmdSetDacValue(2, 0); CmdSetDacValue(3, 0); // Take N events /* // ====== Part D: Secondary calibration ===== T0 = TriggerCell[chip] Sum[ch][t] = Data[ch][t] - Baseline[ch][(i-T0) % kMaxBins]; // Determine secondary baseline if integration finished SecondaryBaseline[ch][t] = MEDIAN( Sum[ch][t] ) */ } void SetVerbose(bool b) { fIsVerbose = b; } void SetHexOutput(bool b) { fIsHexOutput = b; } void SetDataOutput(bool b) { fIsDataOutput = b; } void SetBlockTransmission(bool b) { fBlockTransmission = b; } bool IsTransmissionBlocked() const { return fBlockTransmission; } void PrintEvent() { if (fCounter>0) { PrintEventHeader(); PrintChannelHeaders(); } else Out() << "No event received yet." << endl; } bool IsConfigured() const { bool identical = true; for (int i=0; i class StateMachineFAD : public T, public EventBuilderWrapper, public ba::io_service, public ba::io_service::work { private: typedef map BoardList; BoardList fBoards; bool fIsVerbose; bool fIsHexOutput; bool fIsDataOutput; bool fDebugTx; bool CheckEventSize(size_t has, const char *name, size_t size) { if (has==size) return true; ostringstream msg; msg << name << " - Received event has " << has << " bytes, but expected " << size << "."; T::Fatal(msg); return false; } int Cmd(FAD::Enable command) { for (BoardList::iterator i=fBoards.begin(); i!=fBoards.end(); i++) i->second->Cmd(command); return T::GetCurrentState(); } int SendCmd(const EventImp &evt) { if (!CheckEventSize(evt.GetSize(), "SendCmd", 4)) return T::kSM_FatalError; if (evt.GetUInt()>0xffff) { T::Warn("Command value out of range (0-65535)."); return T::GetCurrentState(); } for (BoardList::iterator i=fBoards.begin(); i!=fBoards.end(); i++) i->second->PostCmd(evt.GetUInt()); return T::GetCurrentState(); } int SendCmdData(const EventImp &evt) { if (!CheckEventSize(evt.GetSize(), "SendCmdData", 8)) return T::kSM_FatalError; const uint32_t *ptr = evt.Ptr(); if (ptr[0]>0xffff) { T::Warn("Command value out of range (0-65535)."); return T::GetCurrentState(); } if (ptr[1]>0xffff) { T::Warn("Data value out of range (0-65535)."); return T::GetCurrentState(); } for (BoardList::iterator i=fBoards.begin(); i!=fBoards.end(); i++) i->second->PostCmd(ptr[0], ptr[1]); return T::GetCurrentState(); } int CmdEnable(const EventImp &evt, FAD::Enable command) { if (!CheckEventSize(evt.GetSize(), "CmdEnable", 1)) return T::kSM_FatalError; for (BoardList::iterator i=fBoards.begin(); i!=fBoards.end(); i++) i->second->Cmd(command, evt.GetBool()); return T::GetCurrentState(); } bool Check(const uint32_t *dat, uint32_t maxaddr, uint32_t maxval) { if (dat[0]>maxaddr) { ostringstream msg; msg << hex << "Address " << dat[0] << " out of range, max=" << maxaddr << "."; T::Error(msg); return false; } if (dat[1]>maxval) { ostringstream msg; msg << hex << "Value " << dat[1] << " out of range, max=" << maxval << "."; T::Error(msg); return false; } return true; } int SetRegister(const EventImp &evt) { if (!CheckEventSize(evt.GetSize(), "SetRegister", 8)) return T::kSM_FatalError; const uint32_t *dat = evt.Ptr(); if (!Check(dat, FAD::kMaxRegAddr, FAD::kMaxRegValue)) return T::GetCurrentState(); for (BoardList::iterator i=fBoards.begin(); i!=fBoards.end(); i++) i->second->CmdSetRegister(dat[0], dat[1]); return T::GetCurrentState(); } int SetRoi(const EventImp &evt) { if (!CheckEventSize(evt.GetSize(), "SetRoi", 8)) return T::kSM_FatalError; const int32_t *dat = evt.Ptr(); for (BoardList::iterator i=fBoards.begin(); i!=fBoards.end(); i++) if (!i->second->CmdSetRoi(dat[0], dat[1])) { ostringstream msg; msg << hex << "Channel " << dat[0] << " or Value " << dat[1] << " out of range."; T::Error(msg); return false; } return T::GetCurrentState(); } int SetDac(const EventImp &evt) { if (!CheckEventSize(evt.GetSize(), "SetDac", 8)) return T::kSM_FatalError; const int32_t *dat = evt.Ptr(); for (BoardList::iterator i=fBoards.begin(); i!=fBoards.end(); i++) if (!i->second->CmdSetDacValue(dat[0], dat[1])) { ostringstream msg; msg << hex << "Channel " << dat[0] << " or Value " << dat[1] << " out of range."; T::Error(msg); return false; } return T::GetCurrentState(); } int Trigger(int n) { for (int nn=0; nnsecond->Cmd(FAD::kCmdSingleTrigger); return T::GetCurrentState(); } int SendTriggers(const EventImp &evt) { if (!CheckEventSize(evt.GetSize(), "SendTriggers", 4)) return T::kSM_FatalError; Trigger(evt.GetUInt()); return T::GetCurrentState(); } int StartRun(const EventImp &evt, bool start) { if (!CheckEventSize(evt.GetSize(), "StartRun", 0)) return T::kSM_FatalError; for (BoardList::iterator i=fBoards.begin(); i!=fBoards.end(); i++) i->second->Cmd(FAD::kCmdRun, start); return T::GetCurrentState(); } int PhaseShift(const EventImp &evt) { if (!CheckEventSize(evt.GetSize(), "PhaseShift", 2)) return T::kSM_FatalError; for (BoardList::iterator i=fBoards.begin(); i!=fBoards.end(); i++) i->second->CmdPhaseShift(evt.GetShort()); return T::GetCurrentState(); } int SetTriggerRate(const EventImp &evt) { if (!CheckEventSize(evt.GetSize(), "SetTriggerRate", 4)) return T::kSM_FatalError; if (evt.GetUInt()>0xffff) { ostringstream msg; msg << hex << "Value " << evt.GetUShort() << " out of range, max=" << 0xffff << "(?)"; T::Error(msg); return false; } for (BoardList::iterator i=fBoards.begin(); i!=fBoards.end(); i++) i->second->CmdSetTriggerRate(evt.GetUInt()); return T::GetCurrentState(); } int SetRunNumber(const EventImp &evt) { if (!CheckEventSize(evt.GetSize(), "SetRunNumber", 8)) return T::kSM_FatalError; const uint64_t num = evt.GetUXtra(); if (num>FAD::kMaxRunNumber) { ostringstream msg; msg << hex << "Value " << num << " out of range, max=" << FAD::kMaxRunNumber; T::Error(msg); return false; } for (BoardList::iterator i=fBoards.begin(); i!=fBoards.end(); i++) i->second->CmdSetRunNumber(num); return T::GetCurrentState(); } int SetMaxMemoryBuffer(const EventImp &evt) { if (!CheckEventSize(evt.GetSize(), "SetMaxMemoryBuffer", 2)) return T::kSM_FatalError; const int16_t mem = evt.GetShort(); if (mem<=0) { ostringstream msg; msg << hex << "Value " << mem << " out of range."; T::Error(msg); return false; } SetMaxMemory(mem); return T::GetCurrentState(); } int SetFileFormat(const EventImp &evt) { if (!CheckEventSize(evt.GetSize(), "SetFileFormat", 2)) return T::kSM_FatalError; const uint16_t fmt = evt.GetUShort(); switch (fmt) { case 0: SetOutputFormat(kNone); break; case 1: SetOutputFormat(kDebug); break; case 2: SetOutputFormat(kFits); break; case 3: SetOutputFormat(kRaw); break; case 4: SetOutputFormat(kCalib); break; default: T::Error("File format unknonw."); return false; } return T::GetCurrentState(); } int Test(const EventImp &evt) { if (!CheckEventSize(evt.GetSize(), "Test", 2)) return T::kSM_FatalError; SetMode(evt.GetShort()); return T::GetCurrentState(); } int SetVerbosity(const EventImp &evt) { if (!CheckEventSize(evt.GetSize(), "SetVerbosity", 1)) return T::kSM_FatalError; for (BoardList::iterator i=fBoards.begin(); i!=fBoards.end(); i++) i->second->SetVerbose(evt.GetBool()); return T::GetCurrentState(); } int SetHexOutput(const EventImp &evt) { if (!CheckEventSize(evt.GetSize(), "SetHexOutput", 1)) return T::kSM_FatalError; for (BoardList::iterator i=fBoards.begin(); i!=fBoards.end(); i++) i->second->SetHexOutput(evt.GetBool()); return T::GetCurrentState(); } int SetDataOutput(const EventImp &evt) { if (!CheckEventSize(evt.GetSize(), "SetDataOutput", 1)) return T::kSM_FatalError; for (BoardList::iterator i=fBoards.begin(); i!=fBoards.end(); i++) i->second->SetDataOutput(evt.GetBool()); return T::GetCurrentState(); } int SetDebugTx(const EventImp &evt) { if (!CheckEventSize(evt.GetSize(), "SetDebugTx", 1)) return T::kSM_FatalError; for (BoardList::iterator i=fBoards.begin(); i!=fBoards.end(); i++) i->second->SetDebugTx(evt.GetBool()); return T::GetCurrentState(); } int SetDebugEb(const EventImp &evt) { if (!CheckEventSize(evt.GetSize(), "SetDebugEb", 1)) return T::kSM_FatalError; SetDebugLog(evt.GetBool()); return T::GetCurrentState(); } const BoardList::iterator GetSlot(uint16_t slot) { const BoardList::iterator it=fBoards.find(slot); if (it==fBoards.end()) { ostringstream str; str << "Slot " << slot << " not found."; T::Warn(str); } return it; } int PrintEvent(const EventImp &evt) { if (!CheckEventSize(evt.GetSize(), "PrintEvent", 2)) return T::kSM_FatalError; const int16_t slot = evt.Get(); if (slot<0) { for (BoardList::iterator i=fBoards.begin(); i!=fBoards.end(); i++) i->second->PrintEvent(); } else { const BoardList::iterator it=GetSlot(slot); if (it!=fBoards.end()) it->second->PrintEvent(); } return T::GetCurrentState(); } int SetBlockTransmission(const EventImp &evt) { if (!CheckEventSize(evt.GetSize(), "SetBlockTransmission", 3)) return T::kSM_FatalError; const int16_t slot = evt.Get(); const BoardList::iterator it=GetSlot(slot); if (it!=fBoards.end()) it->second->SetBlockTransmission(evt.Get(2)); return T::GetCurrentState(); } int SetBlockTransmissionRange(const EventImp &evt) { if (!CheckEventSize(evt.GetSize(), "SetBlockTransmissionRange", 5)) return T::kSM_FatalError; const int16_t *slot = evt.Ptr(); const bool block = evt.Get(4); for (int i=slot[0]; i<=slot[1]; i++) { const BoardList::iterator it=GetSlot(i); if (it!=fBoards.end()) it->second->SetBlockTransmission(block); } return T::GetCurrentState(); } int SetIgnoreSlot(const EventImp &evt) { if (!CheckEventSize(evt.GetSize(), "SetIgnoreSlot", 3)) return T::kSM_FatalError; const uint16_t slot = evt.Get(); if (slot>39) { T::Warn("Slot out of range (0-39)."); return T::GetCurrentState(); } SetIgnore(slot, evt.Get(2)); return T::GetCurrentState(); } int SetIgnoreSlots(const EventImp &evt) { if (!CheckEventSize(evt.GetSize(), "SetIgnoreSlots", 5)) return T::kSM_FatalError; const int16_t *slot = evt.Ptr(); const bool block = evt.Get(4); if (slot[0]<0 || slot[1]>39 || slot[0]>slot[1]) { T::Warn("Slot out of range."); return T::GetCurrentState(); } for (int i=slot[0]; i<=slot[1]; i++) SetIgnore(i, block); return T::GetCurrentState(); } int SetDumpStream(const EventImp &evt) { if (!CheckEventSize(evt.GetSize(), "SetDumpStream", 1)) return T::kSM_FatalError; SetDebugStream(evt.Get()); return T::GetCurrentState(); } int SetDumpRecv(const EventImp &evt) { if (!CheckEventSize(evt.GetSize(), "SetDumpRecv", 1)) return T::kSM_FatalError; SetDebugRead(evt.Get()); return T::GetCurrentState(); } int StartConfigure(const EventImp &evt) { const string name = evt.Ptr(16); fTargetConfig = fConfigs.find(name); if (fTargetConfig==fConfigs.end()) { T::Error("StartConfigure - Run-type '"+name+"' not found."); return T::GetCurrentState(); } const uint32_t runno = StartNewRun(evt.Get(), evt.Get(8), fTargetConfig->second); ostringstream str; str << "Starting configuration for run " << runno << " (" << name << ")"; T::Message(str.str()); const FAD::Configuration &conf = fTargetConfig->second; for (BoardList::iterator it=fBoards.begin(); it!=fBoards.end(); it++) { ConnectionFAD &fad = *it->second; fad.Cmd(FAD::kCmdBusyOn, true); // continously on fad.Cmd(FAD::kCmdTriggerLine, false); fad.Cmd(FAD::kCmdContTrigger, false); fad.Cmd(FAD::kCmdSocket, true); fad.Cmd(FAD::kCmdBusyOff, false); // normal when BusyOn==0 fad.Cmd(FAD::kCmdDwrite, conf.fDwrite); fad.Cmd(FAD::kCmdDrsEnable, conf.fDenable); for (int i=0; i TODO: Insert/update run configuration in database!"); fConfigTimer = Time(); return FAD::kConfiguring1; } int ResetConfig() { return FAD::kConnected; } int AddAddress(const EventImp &evt) { const string addr = Tools::Trim(evt.GetText()); const tcp::endpoint endpoint = GetEndpoint(addr); if (endpoint==tcp::endpoint()) return T::GetCurrentState(); for (BoardList::const_iterator i=fBoards.begin(); i!=fBoards.end(); i++) { if (i->second->GetEndpoint()==endpoint) { T::Warn("Address "+addr+" already known.... ignored."); return T::GetCurrentState(); } } AddEndpoint(endpoint); return T::GetCurrentState(); } int RemoveSlot(const EventImp &evt) { if (!CheckEventSize(evt.GetSize(), "RemoveSlot", 2)) return T::kSM_FatalError; const int16_t slot = evt.GetShort(); const BoardList::iterator it = GetSlot(slot); if (it==fBoards.end()) return T::GetCurrentState(); ConnectSlot(slot, tcp::endpoint()); delete it->second; fBoards.erase(it); return T::GetCurrentState(); } int ListSlots() { for (BoardList::iterator i=fBoards.begin(); i!=fBoards.end(); i++) { const int &idx = i->first; const ConnectionFAD *fad = i->second; ostringstream str; str << "Slot " << setw(2) << idx << ": " << fad->GetEndpoint(); if (fad->IsConnecting()) str << " (0:connecting, "; else { if (fad->IsClosed()) str << " (0:disconnected, "; if (fad->IsConnected()) str << " (0:connected, "; } switch (fStatus2[idx]) { case 0: str << "1-7:not connected)"; break; case 8: str << "1-7:connected)"; break; default: str << "1-7:connecting [" << (int)(fStatus2[idx]-1) << "])"; break; } if (fad->IsTransmissionBlocked()) str << " [cmd_blocked]"; if (fStatus2[idx]==8 && IsIgnored(idx)) str << " [data_ignored]"; if (fStatusC[idx]) str << " [configured]"; T::Out() << str.str() << endl; } T::Out() << "Event builder thread:"; if (!IsThreadRunning()) T::Out() << " not"; T::Out() << " running" << endl; // FIXME: Output state return T::GetCurrentState(); } void EnableConnection(ConnectionFAD *ptr, bool enable=true) { if (!enable) { ptr->PostClose(false); return; } if (!ptr->IsDisconnected()) { ostringstream str; str << ptr->GetEndpoint(); T::Warn("Connection to "+str.str()+" already in progress."); return; } ptr->StartConnect(); } void EnableAll(bool enable=true) { for (BoardList::iterator i=fBoards.begin(); i!=fBoards.end(); i++) EnableConnection(i->second, enable); } int CloseOpenFiles() { EventBuilderWrapper::CloseOpenFiles(); return T::GetCurrentState(); } int EnableSlot(const EventImp &evt, bool enable) { if (!CheckEventSize(evt.GetSize(), "EnableSlot", 2)) return T::kSM_FatalError; const int16_t slot = evt.GetShort(); const BoardList::iterator it = GetSlot(slot); if (it==fBoards.end()) return T::GetCurrentState(); EnableConnection(it->second, enable); ConnectSlot(it->first, enable ? it->second->GetEndpoint() : tcp::endpoint()); return T::GetCurrentState(); } int ToggleSlot(const EventImp &evt) { if (!CheckEventSize(evt.GetSize(), "ToggleSlot", 2)) return T::kSM_FatalError; const int16_t slot = evt.GetShort(); const BoardList::iterator it = GetSlot(slot); if (it==fBoards.end()) return T::GetCurrentState(); const bool enable = it->second->IsDisconnected(); EnableConnection(it->second, enable); ConnectSlot(it->first, enable ? it->second->GetEndpoint() : tcp::endpoint()); return T::GetCurrentState(); } int StartConnection() { vector addr(40); for (BoardList::iterator i=fBoards.begin(); i!=fBoards.end(); i++) addr[i->first] = i->second->GetEndpoint(); StartThread(addr); EnableAll(true); return T::GetCurrentState(); } int StopConnection() { Exit(); EnableAll(false); return T::GetCurrentState(); } int AbortConnection() { Abort(); EnableAll(false); return T::GetCurrentState(); } int Reset(bool soft) { ResetThread(soft); return T::GetCurrentState(); } vector fStatus1; vector fStatus2; vector fStatusC; bool fStatusT; 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(); // ===== Evaluate connection status ===== uint16_t nclosed1 = 0; uint16_t nconnecting1 = 0; uint16_t nconnecting2 = 0; uint16_t nconnected1 = 0; uint16_t nconnected2 = 0; uint16_t nconfigured = 0; vector stat1(40); vector stat2(40); vector statC(40); int cnt = 0; // counter for enabled board const bool runs = IsThreadRunning(); for (int idx=0; idx<40; idx++) { // ----- Command socket ----- const BoardList::const_iterator &slot = fBoards.find(idx); if (slot!=fBoards.end()) { const ConnectionFAD *c = slot->second; if (c->IsDisconnected()) { stat1[idx] = 0; nclosed1++; //DisconnectSlot(idx); } if (c->IsConnecting()) { stat1[idx] = 1; nconnecting1++; } if (c->IsConnected()) { stat1[idx] = 2; nconnected1++; if (c->IsConfigured()) { statC[idx] = 1; nconfigured++; } } cnt++; } // ----- Event builder ----- if (!runs) continue; stat2[idx] = GetNumConnected(idx); if (runs && IsConnecting(idx)) { nconnecting2++; stat2[idx]++; } if (IsConnected(idx)) { stat2[idx]++; nconnected2++; } } // ===== Send connection status via dim ===== if (fStatus1!=stat1 || fStatus2!=stat2 || fStatusT!=runs) { fStatus1 = stat1; fStatus2 = stat2; fStatusT = runs; UpdateConnectionStatus(stat1, stat2, runs); } // ===== Return connection status ===== // fadctrl: Always connecting if not disabled // event builder: if (nconnecting1==0 && nconnected1>0 && nconnected2==nconnected1) { if (T::GetCurrentState()==FAD::kConfiguring1) { // We need some delay so that the FAD is not busy anymore // and really sees the software trigger // FIXME: Do we need this to be configurable? if (Time()-fConfigTimersecond->Cmd(FAD::kCmdSingleTrigger); return FAD::kConfiguring2; } // If all boards are configured and we are configuring // go on and start the FADs if (T::GetCurrentState()==FAD::kConfiguring2) { // If not all boards have yet received the proper // configuration if (nconfigured!=nconnected1) return FAD::kConfiguring2; // FIXME: Distinguish between not all boards have received // the configuration and the configuration is not consistent for (BoardList::iterator it=fBoards.begin(); it!=fBoards.end(); it++) { ConnectionFAD &fad = *it->second; // Make sure that after switching on the trigger line // there needs to be some waiting before all boards // can be assumed to be listening fad.Cmd(FAD::kCmdResetEventCounter); fad.Cmd(FAD::kCmdSocket, false); fad.Cmd(FAD::kCmdTriggerLine, true); if (fTargetConfig->second.fContinousTrigger) fad.Cmd(FAD::kCmdContTrigger, true); fad.Cmd(FAD::kCmdBusyOn, false); // continously on // FIXME: How do we find out when the FADs // successfully enabled the trigger lines? } return FAD::kConfigured; } if (T::GetCurrentState()==FAD::kConfigured) { // Stay in Configured as long as we have a valid // configuration and the run has not yet been started // (means the the event builder has received its // first event) if (!IsRunStarted() && nconfigured==nconnected1) return FAD::kConfigured; } return FAD::kConnected; } if (nconnecting1>0 || nconnecting2>0 || nconnected1!=nconnected2) return FAD::kConnecting; // nconnected1 == nconnected2 == 0 return runs ? FAD::kDisconnected : FAD::kOffline; } void AddEndpoint(const tcp::endpoint &addr) { int i=0; while (i<40) { if (fBoards.find(i)==fBoards.end()) break; i++; } if (i==40) { T::Warn("Not more than 40 slots allowed."); return; } ConnectionFAD *fad = new ConnectionFAD(*this, *this, i); fad->SetEndpoint(addr); fad->SetVerbose(fIsVerbose); fad->SetHexOutput(fIsHexOutput); fad->SetDataOutput(fIsDataOutput); fad->SetDebugTx(fDebugTx); fBoards[i] = fad; } DimDescribedService fDimStartRun; DimDescribedService fDimConnection; void UpdateConnectionStatus(const vector &stat1, const vector &stat2, bool thread) { vector stat(41); for (int i=0; i<40; i++) stat[i] = stat1[i]|(stat2[i]<<3); stat[40] = thread; fDimConnection.setData(stat.data(), 41); fDimConnection.updateService(); } public: StateMachineFAD(ostream &out=cout) : T(out, "FAD_CONTROL"), EventBuilderWrapper(*static_cast(this)), ba::io_service::work(static_cast(*this)), fStatus1(40), fStatus2(40), fStatusC(40), fStatusT(false), fDimStartRun("FAD_CONTROL/START_RUN", "X:1", ""), fDimConnection("FAD_CONTROL/CONNECTIONS", "C:40;C:1", "") { // 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. fDimStartRun.Update(int64_t(-1)); // State names T::AddStateName(FAD::kOffline, "Disengaged", "All enabled FAD boards are disconnected and the event-builer thread is not running."); T::AddStateName(FAD::kDisconnected, "Disconnected", "All enabled FAD boards are disconnected, but the event-builder thread is running."); T::AddStateName(FAD::kConnecting, "Connecting", "Only some enabled FAD boards are connected."); T::AddStateName(FAD::kConnected, "Connected", "All enabled FAD boards are connected.."); T::AddStateName(FAD::kConfiguring1, "Configuring1", "."); T::AddStateName(FAD::kConfiguring2, "Configuring2", "."); T::AddStateName(FAD::kConfigured, "Configured", "The last header received through the command socket fits the requested configureation and has EventCounter==0."); // FAD Commands T::AddEvent("SEND_CMD", "I:1", FAD::kConnecting, FAD::kConnected) (bind(&StateMachineFAD::SendCmd, this, placeholders::_1)) ("Send a command to the FADs. Values between 0 and 0xffff are allowed." "|command[uint16]:Command to be transmittted."); T::AddEvent("SEND_DATA", "I:2", FAD::kConnecting, FAD::kConnected) (bind(&StateMachineFAD::SendCmdData, this, placeholders::_1)) ("Send a command with data to the FADs. Values between 0 and 0xffff are allowed." "|command[uint16]:Command to be transmittted." "|data[uint16]:Data to be sent with the command."); T::AddEvent("ENABLE_SRCLK", "B:1", FAD::kConnecting, FAD::kConnected) (bind(&StateMachineFAD::CmdEnable, this, placeholders::_1, FAD::kCmdSrclk)) ("Set SRCLK"); T::AddEvent("ENABLE_BUSY_OFF", "B:1", FAD::kConnecting, FAD::kConnected) (bind(&StateMachineFAD::CmdEnable, this, placeholders::_1, FAD::kCmdBusyOff)) ("Set BUSY continously low"); T::AddEvent("ENABLE_BUSY_ON", "B:1", FAD::kConnecting, FAD::kConnected) (bind(&StateMachineFAD::CmdEnable, this, placeholders::_1, FAD::kCmdBusyOn)) ("Set BUSY constantly high (has priority over BUSY_OFF)"); T::AddEvent("ENABLE_SCLK", "B:1", FAD::kConnecting, FAD::kConnected) (bind(&StateMachineFAD::CmdEnable, this, placeholders::_1, FAD::kCmdSclk)) ("Set SCLK"); T::AddEvent("ENABLE_DRS", "B:1", FAD::kConnecting, FAD::kConnected) (bind(&StateMachineFAD::CmdEnable, this, placeholders::_1, FAD::kCmdDrsEnable)) ("Switch Domino wave"); T::AddEvent("ENABLE_DWRITE", "B:1", FAD::kConnecting, FAD::kConnected) (bind(&StateMachineFAD::CmdEnable, this, placeholders::_1, FAD::kCmdDwrite)) ("Set Dwrite (possibly high / always low)"); T::AddEvent("ENABLE_CONTINOUS_TRIGGER", "B:1", FAD::kConnecting, FAD::kConnected) (bind(&StateMachineFAD::CmdEnable, this, placeholders::_1, FAD::kCmdContTrigger)) ("Enable continous (internal) trigger."); T::AddEvent("ENABLE_TRIGGER_LINE", "B:1", FAD::kConnecting, FAD::kConnected) (bind(&StateMachineFAD::CmdEnable, this, placeholders::_1, FAD::kCmdTriggerLine)) ("Incoming triggers can be accepted/will not be accepted"); T::AddEvent("ENABLE_COMMAND_SOCKET_MODE", "B:1", FAD::kConnecting, FAD::kConnected) (bind(&StateMachineFAD::CmdEnable, this, placeholders::_1, FAD::kCmdSocket)) ("Set debug mode (yes: dump events through command socket, no=dump events through other sockets)"); T::AddEvent("SET_TRIGGER_RATE", "I:1", FAD::kConnecting, FAD::kConnected) (bind(&StateMachineFAD::SetTriggerRate, this, placeholders::_1)) ("Enable continous trigger"); T::AddEvent("SEND_SINGLE_TRIGGER", FAD::kConnecting, FAD::kConnected) (bind(&StateMachineFAD::Trigger, this, 1)) ("Issue software triggers"); T::AddEvent("SEND_N_TRIGGERS", "I", FAD::kConnecting, FAD::kConnected) (bind(&StateMachineFAD::SendTriggers, this, placeholders::_1)) ("Issue software triggers"); T::AddEvent("START_RUN", "", FAD::kConnecting, FAD::kConnected) (bind(&StateMachineFAD::StartRun, this, placeholders::_1, true)) ("Set FAD DAQ mode. when started, no configurations must be send."); T::AddEvent("STOP_RUN", FAD::kConnecting, FAD::kConnected) (bind(&StateMachineFAD::StartRun, this, placeholders::_1, false)) (""); T::AddEvent("PHASE_SHIFT", "S:1", FAD::kConnecting, FAD::kConnected) (bind(&StateMachineFAD::PhaseShift, this, placeholders::_1)) ("Adjust ADC phase (in 'steps')"); T::AddEvent("RESET_EVENT_COUNTER", FAD::kConnecting, FAD::kConnected) (bind(&StateMachineFAD::Cmd, this, FAD::kCmdResetEventCounter)) (""); T::AddEvent("SET_RUN_NUMBER", "X:1", FAD::kConnecting, FAD::kConnected) (bind(&StateMachineFAD::SetRunNumber, this, placeholders::_1)) (""); T::AddEvent("SET_MAX_MEMORY", "S:1") (bind(&StateMachineFAD::SetMaxMemoryBuffer, this, placeholders::_1)) ("Set maximum memory buffer size allowed to be consumed by the EventBuilder to buffer events." "|memory[short]:Buffer size in Mega-bytes."); T::AddEvent("SET_REGISTER", "I:2", FAD::kConnecting, FAD::kConnected) (bind(&StateMachineFAD::SetRegister, this, placeholders::_1)) ("set register to value" "|addr[short]:Address of register" "|val[short]:Value to be set"); // FIXME: Maybe add a mask which channels should be set? T::AddEvent("SET_REGION_OF_INTEREST", "I:2", FAD::kConnecting, FAD::kConnected) (bind(&StateMachineFAD::SetRoi, this, placeholders::_1)) ("Set region-of-interest to value" "|addr[short]:Address of register" "|val[short]:Value to be set"); // FIXME: Maybe add a mask which channels should be set? T::AddEvent("SET_DAC_VALUE", "I:2", FAD::kConnecting, FAD::kConnected) (bind(&StateMachineFAD::SetDac, this, placeholders::_1)) ("Set DAC numbers in range to value" "|addr[short]:Address of register (-1 for all)" "|val[short]:Value to be set"); T::AddEvent("CONFIGURE", "X:2;C", FAD::kConnected, FAD::kConfigured) (bind(&StateMachineFAD::StartConfigure, this, placeholders::_1)) (""); T::AddEvent("RESET_CONFIGURE", FAD::kConfiguring1, FAD::kConfiguring2, FAD::kConfigured) (bind(&StateMachineFAD::ResetConfig, this)) (""); // Verbosity commands T::AddEvent("SET_VERBOSE", "B:1") (bind(&StateMachineFAD::SetVerbosity, this, placeholders::_1)) ("Set verbosity state" "|verbosity[bool]:disable or enable verbosity for received data (yes/no), except dynamic data"); T::AddEvent("SET_HEX_OUTPUT", "B:1") (bind(&StateMachineFAD::SetHexOutput, this, placeholders::_1)) ("Enable or disable hex output for received data" "|hexout[bool]:disable or enable hex output for received data (yes/no)"); T::AddEvent("SET_DATA_OUTPUT", "B:1") (bind(&StateMachineFAD::SetDataOutput, this, placeholders::_1)) (""); T::AddEvent("SET_DEBUG_TX", "B:1") (bind(&StateMachineFAD::SetDebugTx, this, placeholders::_1)) ("Enable or disable the output of messages in case of successfull data transmission to the boards." "|debug[bool]:disable or enable debug output for transmitted data (yes/no)"); T::AddEvent("SET_DEBUG_EVENT_BUILDER_OUT", "B:1") (bind(&StateMachineFAD::SetDebugEb, this, placeholders::_1)) (""); T::AddEvent("PRINT_EVENT", "S:1") (bind(&StateMachineFAD::PrintEvent, this, placeholders::_1)) ("Print (last) event" "|board[short]:slot from which the event should be printed (-1 for all)"); T::AddEvent("DUMP_STREAM", "B:1") (bind(&StateMachineFAD::SetDumpStream, this, placeholders::_1)) ("For debugging purpose: the binary data stream read from the sockets 0-7 can be dumped to files." "|switch[bool]:Enable (yes) or disable (no)"); T::AddEvent("DUMP_RECV", "B:1") (bind(&StateMachineFAD::SetDumpRecv, this, placeholders::_1)) ("For debugging purpose: the times when data has been receives are dumped to a file." "|switch[bool]:Enable (yes) or disable (no)"); T::AddEvent("BLOCK_TRANSMISSION", "S:1;B:1") (bind(&StateMachineFAD::SetBlockTransmission, this, placeholders::_1)) ("Blocks the transmission of commands to the given slot. Use with care! For debugging pupose only!" "|slot[short]:Slot to which the command transmission should be blocked (0-39)" "|enable[bool]:Whether the command transmission should be blockes (yes) or allowed (no)"); T::AddEvent("BLOCK_TRANSMISSION_RANGE", "S:2;B:1") (bind(&StateMachineFAD::SetBlockTransmissionRange, this, placeholders::_1)) ("Blocks the transmission of commands to the given range of slots. Use with care! For debugging pupose only!" "|first[short]:First slot to which the command transmission should be blocked (0-39)" "|last[short]:Last slot to which the command transmission should be blocked (0-39)" "|enable[bool]:Whether the command transmission should be blockes (yes) or allowed (no)"); T::AddEvent("IGNORE_EVENTS", "S:1;B:1") (bind(&StateMachineFAD::SetIgnoreSlot, this, placeholders::_1)) ("Instructs the event-builder to ignore events from the given slot but still read the data from the socket." "|slot[short]:Slot from which the data should be ignored when building events" "|enable[bool]:Whether the event builder should ignore data from this slot (yes) or allowed (no)"); T::AddEvent("IGNORE_EVENTS_RANGE", "S:2;B:1") (bind(&StateMachineFAD::SetIgnoreSlots, this, placeholders::_1)) ("Instructs the event-builder to ignore events from the given slot but still read the data from the socket." "|first[short]:First slot from which the data should be ignored when building events" "|last[short]:Last slot from which the data should be ignored when building events" "|enable[bool]:Whether the event builder should ignore data from this slot (yes) or allowed (no)"); T::AddEvent("CLOSE_OPEN_FILES", FAD::kDisconnected, FAD::kConnecting, FAD::kConnected) (bind(&StateMachineFAD::CloseOpenFiles, this)) ("Close all run files opened by the EventBuilder."); T::AddEvent("TEST", "S:1") (bind(&StateMachineFAD::Test, this, placeholders::_1)) (""); // Conenction commands T::AddEvent("START", FAD::kOffline) (bind(&StateMachineFAD::StartConnection, this)) ("Start EventBuilder thread and connect all valid slots."); T::AddEvent("STOP", FAD::kDisconnected, FAD::kConnecting, FAD::kConnected) (bind(&StateMachineFAD::StopConnection, this)) ("Stop EventBuilder thread (still write buffered events) and disconnect all slots."); T::AddEvent("ABORT", FAD::kDisconnected, FAD::kConnecting, FAD::kConnected) (bind(&StateMachineFAD::AbortConnection, this)) ("Immediately abort EventBuilder thread and disconnect all slots."); T::AddEvent("SOFT_RESET", FAD::kConnected) (bind(&StateMachineFAD::Reset, this, true)) ("Wait for buffers to drain, close all files and reinitialize event builder thread."); T::AddEvent("HARD_RESET", FAD::kConnected) (bind(&StateMachineFAD::Reset, this, false)) ("Free all buffers, close all files and reinitialize event builder thread."); T::AddEvent("CONNECT", "S:1", FAD::kDisconnected, FAD::kConnecting, FAD::kConnected) (bind(&StateMachineFAD::EnableSlot, this, placeholders::_1, true)) ("Connect a disconnected slot."); T::AddEvent("DISCONNECT", "S:1", FAD::kConnecting, FAD::kConnected) (bind(&StateMachineFAD::EnableSlot, this, placeholders::_1, false)) ("Disconnect a connected slot."); T::AddEvent("TOGGLE", "S:1", FAD::kDisconnected, FAD::kConnecting, FAD::kConnected) (bind(&StateMachineFAD::ToggleSlot, this, placeholders::_1)) (""); T::AddEvent("SET_FILE_FORMAT", "S:1") (bind(&StateMachineFAD::SetFileFormat, this, placeholders::_1)) (""); T::AddEvent("ADD_ADDRESS", "C", FAD::kOffline) (bind(&StateMachineFAD::AddAddress, this, placeholders::_1)) ("Add the address of a DRS4 board to the first free slot" "|IP[string]:address in the format "); T::AddEvent("REMOVE_SLOT", "S:1", FAD::kOffline) (bind(&StateMachineFAD::RemoveSlot, this, placeholders::_1)) ("Remove the Iaddress in slot n. For a list see LIST" "|slot[short]:Remove the address in slot n from the list"); T::AddEvent("LIST_SLOTS") (bind(&StateMachineFAD::ListSlots, this)) ("Print a list of all available board addressesa and whether they are enabled"); } ~StateMachineFAD() { for (BoardList::const_iterator i=fBoards.begin(); i!=fBoards.end(); i++) delete i->second; fBoards.clear(); } tcp::endpoint GetEndpoint(const string &base) { const size_t p0 = base.find_first_of(':'); const size_t p1 = base.find_last_of(':'); if (p0==string::npos || p0!=p1) { T::Out() << kRed << "GetEndpoint - Wrong format ('host:port' expected)" << endl; return tcp::endpoint(); } tcp::resolver resolver(get_io_service()); boost::system::error_code ec; const tcp::resolver::query query(base.substr(0, p0), base.substr(p0+1)); const tcp::resolver::iterator iterator = resolver.resolve(query, ec); if (ec) { T::Out() << kRed << "GetEndpoint - Couldn't resolve endpoint '" << base << "': " << ec.message(); return tcp::endpoint(); } return *iterator; } typedef map Configs; Configs fConfigs; Configs::const_iterator fTargetConfig; Time fConfigTimer; template bool CheckConfigVal(Configuration &conf, V max, const string &name, const string &sub) { if (!conf.HasDef(name, sub)) { T::Error("Neither "+name+"default nor "+name+sub+" found."); return false; } const V val = conf.GetDef(name, sub); if (val<=max) return true; ostringstream str; str << name << sub << "=" << val << " exceeds allowed maximum of " << max << "!"; T::Error(str); return false; } int EvalOptions(Configuration &conf) { // ---------- General setup --------- fIsVerbose = !conf.Get("quiet"); fIsHexOutput = conf.Get("hex-out"); fIsDataOutput = conf.Get("data-out"); fDebugTx = conf.Get("debug-tx"); // ---------- Setup event builder --------- SetMaxMemory(conf.Get("max-mem")); // ---------- Setup run types --------- const vector types = conf.Vec("run-type"); if (types.size()==0) T::Warn("No run-types defined."); else T::Message("Defining run-types"); for (vector::const_iterator it=types.begin(); it!=types.end(); it++) { T::Message(" -> "+ *it); if (fConfigs.count(*it)>0) { T::Error("Run-type "+*it+" defined twice."); return 1; } FAD::Configuration target; if (!CheckConfigVal(conf, true, "enable-drs.", *it) || !CheckConfigVal(conf, true, "enable-dwrite.", *it) || !CheckConfigVal(conf, true, "enable-continous-trigger.", *it)) return 2; target.fDenable = conf.GetDef("enable-drs.", *it); target.fDwrite = conf.GetDef("enable-dwrite.", *it); target.fContinousTrigger = conf.GetDef("enable-continous-trigger.", *it); target.fTriggerRate = 0; //if (target.fContinousTrigger) { if (!CheckConfigVal(conf, 0xffff, "trigger-rate.", *it)) return 3; target.fTriggerRate = conf.GetDef("trigger-rate.", *it); } for (int i=0; i(conf, FAD::kMaxRoiValue, "roi.", *it) && !CheckConfigVal(conf, FAD::kMaxRoiValue, str.str(), *it)) return 4; target.fRoi[i] = conf.HasDef(str.str(), *it) ? conf.GetDef(str.str(), *it) : conf.GetDef("roi.", *it); } for (int i=0; i(conf, FAD::kMaxDacValue, "dac.", *it) && !CheckConfigVal(conf, FAD::kMaxDacValue, str.str(), *it)) return 5; target.fDac[i] = conf.HasDef(str.str(), *it) ? conf.GetDef(str.str(), *it) : conf.GetDef("dac.", *it); } fConfigs[*it] = target; } // FIXME: Add a check about unsused configurations // ---------- Setup board addresses for fake-fad --------- if (conf.Has("debug-addr")) { const string addr = conf.Get("debug-addr"); const int num = conf.Get("debug-num"); const tcp::endpoint endpoint = GetEndpoint(addr); if (endpoint==tcp::endpoint()) return 1; for (int i=0; i("base-addr"); if (base=="def" || base =="default") base = "10.0.128.128:31919"; const tcp::endpoint endpoint = GetEndpoint(base); if (endpoint==tcp::endpoint()) return 10; const ba::ip::address_v4::bytes_type ip = endpoint.address().to_v4().to_bytes(); if (ip[2]>250 || ip[3]>244) { T::Out() << kRed << "EvalConfiguration - IP address given by --base-addr out-of-range." << endl; return 11; } for (int crate=0; crate<4; crate++) for (int board=0; board<10; board++) { ba::ip::address_v4::bytes_type target = endpoint.address().to_v4().to_bytes(); target[2] += crate; target[3] += board; AddEndpoint(tcp::endpoint(ba::ip::address_v4(target), endpoint.port())); } StartConnection(); return -1; } // ---------- Setup board addresses one by one --------- if (conf.Has("addr")) { const vector addrs = conf.Get>("addr"); for (vector::const_iterator i=addrs.begin(); i int RunShell(Configuration &conf) { return Main::execute>(conf); } void SetupConfiguration(Configuration &conf) { po::options_description control("FAD control options"); control.add_options() ("quiet,q", po_bool(), "Disable printing contents of all received messages in clear text.") ("hex-out", po_bool(), "Enable printing contents of all printed messages also as hex data.") ("data-out", po_bool(), "Enable printing received event data.") ("debug-tx", po_bool(), "Enable debugging of ethernet transmission.") ; po::options_description connect("FAD connection options"); connect.add_options() ("addr", vars(), "Network address of FAD") ("base-addr", var(), "Base address of all FAD") ("debug-num,n", var(40), "Sets the number of fake boards to be connected locally") ("debug-addr", var(), "") ; po::options_description builder("Event builder options"); builder.add_options() ("max-mem,m", var(100), "Maximum memory the event builder thread is allowed to consume for its event buffer") ; po::options_description runtype("Run type configuration"); runtype.add_options() ("run-type", vars(), "") ("enable-dwrite.*", var(), "") ("enable-drs.*", var(), "") ("enable-continous-trigger.*", var(), "") ("trigger-rate.*", var(), "") ("dac.*", var(), "") ("dac-0.*", var(), "") ("dac-1.*", var(), "") ("dac-2.*", var(), "") ("dac-3.*", var(), "") ("dac-4.*", var(), "") ("dac-5.*", var(), "") ("dac-6.*", var(), "") ("dac-7.*", var(), "") ("roi.*", var(), "") ("roi-ch0.*", var(), "") ("roi-ch1.*", var(), "") ("roi-ch2.*", var(), "") ("roi-ch3.*", var(), "") ("roi-ch4.*", var(), "") ("roi-ch5.*", var(), "") ("roi-ch6.*", var(), "") ("roi-ch7.*", var(), "") ("roi-ch8.*", var(), "") ; conf.AddEnv("dns", "DIM_DNS_NODE"); conf.AddEnv("host", "DIM_HOST_NODE"); conf.AddOptions(control); conf.AddOptions(connect); conf.AddOptions(builder); conf.AddOptions(runtype); } void PrintUsage() { cout << "The fadctrl controls the FAD boards.\n" "\n" "The default is that the program is started without user intercation. " "All actions are supposed to arrive as DimCommands. Using the -c " "option, a local shell can be initialized. With h or help a short " "help message about the usuage can be brought to the screen.\n" "\n" "Usage: fadctrl [-c type] [OPTIONS]\n" " or: fadctrl [OPTIONS]\n"; cout << endl; } void PrintHelp() { /* Additional help text which is printed after the configuration options goes here */ } 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; }