#include "MCosy.h" #include "MCosy.h" #include #include #include #include #include //#include "MLog.h" #include "MLogManip.h" #include "MEnv.h" #include "MTime.h" #include "MPointing.h" #include "MGCosy.h" #include "MDriveCom.h" #include "MStarguider.h" #include "SlaStars.h" #include "MTracking.h" #include "dkc.h" ClassImp(MCosy); using namespace std; typedef struct tm tm_t; //#define EXPERT #undef EXPERT /* ZdAz MCosy::CorrectTarget(const ZdAz &src, const ZdAz &dst) { // CorrectTarget [se] // src [se] // dst [rad] // fAltMax = 70 // fAltMin = -105/110 // fAzMin = -355 // fAzMax = 355 ZdAz source = src * 360.0/16384.0; ZdAz dest = dst * TMath::RadToDeg(); if (dest.Zd()>-3 && dest.Zd()<3) dest.Zd(dest.Zd()<0?-3:3); if (dest.Zd()>-1e-6 && dest.Zd()<1e-6) return dst*(16384.0/k2Pi); const float fZdMin = -67; const float fZdMax = 67; const float fAzMin = -29; const float fAzMax = 423; // // This corrects to target for the shortest distance, not for the fastest move! // ZdAz s = source-dest; float min = s.Sqr(); // // Is it enought to search inside one revolution? // ZdAz ret = dest; for (int i=-5; i<5+1; i++) { const ZdAz p(i%2 ? -dest.Zd() : dest.Zd(), dest.Az() - i*180); // // Range Check // if (p.Zd()fZdMax) continue; if (p.Az()fAzMax) continue; // // Calculate distance // s = source-p; const float dist = s.Sqr(); if (dist > min) continue; // // New shortest distance // ret = p; min = dist; } return ret*(16384.0/360.0); } */ // -------------------------------------------------------------------------- // // GetSePos, reads the Shaftencoder positions from the Can-drivers // for the shaftencoders. The two shaft encoders at the elevation axis // are avaraged. The values are returned as a ZdAz object. // // If one of the two shaftencoders on the elevation axis is missing // the other one's position is returned. // // The positions are alway up-to-date because the shaftencoders are // sending all changes immediatly. // ZdAz MCosy::GetSePos() const { const Double_t pa = fMac1 ? (Double_t)fMac1->GetPdoPos2()/fMac1->GetPosRes() : 0; const Double_t p1 = fMac2 ? (Double_t)fMac2->GetPdoPos2()/fMac2->GetPosRes() : 0; return ZdAz(p1, pa); } // -------------------------------------------------------------------------- // // check for a break-signal (from the msgqueue) and errors. // int MCosy::StopWaitingForSDO() const { return 0/*Break() || HasError()*/; } // -------------------------------------------------------------------------- // // Waits for a movement to become finished. // // First waits for all peding Sdos, then waits until both motors are stopped // or waiting for SDOs was stopped (either by an error or by Break) // void MCosy::WaitForEndMovement() { // FIXME, what when waiting times out (Zombie) if (!fMac1 || !fMac2) return; while ((fMac1->IsPositioning() || fMac2->IsPositioning()) && !(Break() || HasError() || HasZombie())) usleep(1); if (!Break() && !HasError() && !HasZombie()) return; MTime t(-1); gLog << inf << t << " - MCosy::WaitForEndMovement aborted..."; if (Break()) gLog << " Break signal..."; if (HasError()) gLog << " Network has error..."; if (HasZombie()) gLog << " Network has zombie..."; gLog << endl; } // -------------------------------------------------------------------------- // // Check for an error... // // This is ment for usage after the Action: All Motors Stop. // void MCosy::CheckForError() { // // Check all Can-Nodes for an Error. If there is no error the motor // status is set to stopped. // if (HasError() || HasZombie()) { SetStatus(MDriveCom::kError); return; } if (fMac1->IsPositioning() || fMac2->IsPositioning()) SetStatus(MDriveCom::kMoving); else SetStatus(MDriveCom::kStopped); // // If there is an error, the error status is set to Error. // /* FIXME: HANDLINGE ERROR // // Now try to handle the error. // fMac1->HandleError(); fMac2->HandleError(); // // If the error couldn't get solved return // if (HasError()) return; // // Set motor status to stopped // SetStatus(MDriveCom::kStopped); */ } Bool_t MCosy::CheckRange(const ZdAz &d) const { // d [rad] if (d.Zd()fMax.Zd()) { gLog << err << "ERROR: Requested Zenith Angle " << d.Zd()*TMath::RadToDeg() << " behind positive endswitch " << fMax.Zd()*TMath::RadToDeg() << endl; return kFALSE; } if (d.Az()fMax.Az()) { gLog << err << "ERROR: Requested Azimuth Angle " << d.Az()*TMath::RadToDeg() << " behind positive endswitch " << fMax.Az()*TMath::RadToDeg() << endl; if (TMath::Abs(d.Zd())<1) gLog << " Remember that there is a small inaccessible region around zenith!" << endl; return kFALSE; } return kTRUE; } ZdAz MCosy::AlignTrackingPos(ZdAz pointing) const { // pointing [rad] // AlignTrackingPos [deg] pointing *= TMath::RadToDeg(); if (pointing.Zd()<0) { pointing.Zd(-pointing.Zd()); pointing.Az(pointing.Az()+180); //gLog << "ZD=-ZD Az+=180" << endl; } const ZdAz se = GetSePos()*TMath::TwoPi(); // [rad] const ZdAz unbendedse = fBending.CorrectBack(se)*TMath::RadToDeg(); // ist pointing //gLog << "Unbended: " << unbendedse.Zd() << " " << unbendedse.Az() << endl; do { const Double_t d = unbendedse.Az() - pointing.Az(); if (d>-180 && d<=180) break; //gLog << "AZ += " << TMath::Sign(360., d) << endl; pointing.Az(pointing.Az()+TMath::Sign(360., d)); } while (1); return pointing/TMath::RadToDeg(); /* const Bool_t rc = CheckRange(pointing); za = pointing/TMath::RadToDeg(); // [rad] if (!rc) gLog << "Error: Aligned position out of Range." << endl; return rc;*/ } /* Double_t MCosy::Starguider(Double_t mjd, ZdAz &dest) const { ifstream fin("pointingpos.txt"); if (!fin) return -1; Double_t mjd0, zd, az; fin >> mjd0 >> zd >> az; mjd0 += 52000; if (mjd0+1./24/60 5 || diff.Az()>5) { cout << "Starguider deviation too large... dZd=" << diff.Zd() <<" dAz="<SetAcceleration(TMath::Nint(0.03*1000000000)); fMac2->SetAcceleration(TMath::Nint(0.09*1000000000)); fMac1->SetRpmMode(FALSE); fMac2->SetRpmMode(FALSE); } // // Wait for the movement to really be finished. // #ifdef EXPERT cout << "Waiting for end of movement..." << endl; #endif WaitForEndMovement(); // // Check whether everything works fine. // CheckForError(); #ifdef EXPERT cout << "Movement stopped." << endl; #endif } bool MCosy::CheckNetwork() { if (!HasConnection()) { gLog << warn << "- No connection to network." << endl; return false; } CheckForError(); if (HasZombie()) { gLog << warn << "- Found Zombies in Network..." << endl; if (!RebootZombies()) return false; } /* FIXME HANDLING ERROR */ if (HasError()) { fMac1->HandleError(); fMac2->HandleError(); if (HasError() || HasZombie()) return false; } CheckForError(); return fMac1->IsOperative() && fMac2->IsOperative(); } Int_t MCosy::Proc(int msg, void *mp) { switch (msg) { case WM_WAIT: gLog << inf2 << "Wait for execution of Proc(WM_*, ): done." << endl; return 0; case WM_STOP: //cout << "MCosy::Proc: Stop." << endl; if (!CheckNetwork()) return 0xebb0; StopMovement(); return 0; case WM_TPOINT: { //cout << "WM_TPoint: start." << endl; SlaStars sla(fObservatory); sla.Now(); RaDec rd = *((RaDec*)mp); cout << "TPoint Star: " << rd.Ra()/15 << "h " << rd.Dec() << "°" << endl; AltAz za=sla.CalcAltAz(rd*TMath::DegToRad())*TMath::RadToDeg(); if (!fOutTp) { // // open tpoint file // const TString name = GetFileName("tpoint", "old-tpoint", "txt"); cout << "TPoint-Cosy File ********* " << name << " ********** " << endl; fOutTp = new ofstream(name); *fOutTp << "Magic Model TPOINT data file" << endl; *fOutTp << ": ALTAZ" << endl; *fOutTp << "49 48 0 "; *fOutTp << sla.GetTime().Year() << " " << sla.GetTime().Month() << " " << sla.GetTime().Day() << " "; *fOutTp << /*"20 1013.25 300 0.5 0.55 0.0065" <<*/ endl; // temp(°C) pressure(mB) height(m) humidity(1) wavelength(microm) troplapserate(K/m) } cout << " Alt/Az: " << za.Alt() << "° " << za.Az() << "°" << endl; *fOutTp << setprecision(7) << za.Az() << " " << za.Alt() << " "; ZdAz sepos = GetSePos()*TMath::TwoPi(); za.Set(TMath::Pi()/2-sepos.Zd(), sepos.Az()); za *= TMath::RadToDeg(); cout << " SE-Pos: " << za.Alt() << "° " << za.Az() << "°" << endl; *fOutTp << fmod(za.Az()+360, 360) << " " << za.Alt() << " "; if (fStarguider) { XY tp = fStarguider->GetCoordinates(); *fOutTp << 90-tp.X() << " " << tp.Y() << " "; } *fOutTp << rd.Ra()/15 << " " << rd.Dec() << " " << setprecision(11) << sla.GetMjd() << endl; //cout << "WM_TPoint: done. (return 0xaffe)" << endl; } return 0xca1b; case WM_STARGTPOINT: if (fStarguider) fStarguider->StartTPoint((char*)mp); return 0xca1c; case WM_STARGMODE: if (fStarguider) fStarguider->StartStarguider(*((bool*)mp)); return 0xca1c; case WM_TRACKPOS: //cout << "WM_TrackPosition: start." << endl; { if (!CheckNetwork()) return 0xebb0; ZdAz dest = *((ZdAz*)mp) * TMath::DegToRad(); //if (!SetPosition(dest, kTRUE)) // return 0x1234; SlaStars sla(fObservatory); sla.Now(); RaDec rd = sla.CalcRaDec(dest); TrackPosition(rd); } //cout << "WM_TrackPosition: done. (return 0xabcd)" << endl; return 0xabcd; case WM_ARM: //cout << "WM_Position: start." << endl; { if (!CheckNetwork()) return 0xebb0; const bool arm = mp ? *((bool*)mp) : true; if (arm) { fMac1->Arm(); fMac2->Arm(); } else { fMac1->Disarm(); fMac2->Disarm(); } } //cout << "WM_Position: done. (return 0x7777)" << endl; return 0x9999; case WM_POSITION: //cout << "WM_Position: start." << endl; { if (!CheckNetwork()) return 0xebb0; ZdAz dest = *((ZdAz*)mp); SetPosition(dest*TMath::DegToRad()); } //cout << "WM_Position: done. (return 0x7777)" << endl; return 0x7777; case WM_POSITION1: //cout << "WM_Position1: start." << endl; { if (!CheckNetwork()) return 0xebb0; ZdAz dest = *((ZdAz*)mp); SetPosition(dest*TMath::DegToRad(), kTRUE); } //cout << "WM_Position: done. (return 0x7777)" << endl; return 0x7777; case WM_PREPS: //cout << "WM_Track: START" << endl; { if (!CheckNetwork()) return 0xebb0; const char *preps = (const char*)mp; cout << "Preposition command to " << preps << " received." << endl; ifstream fin(fFilePrepos); if (!fin) { cout << "ERROR: cannot open " << fFilePrepos << endl; return 0xebb1; } while (1) { Double_t zd, az; fin >> zd >> az; TString str; str.ReadLine(fin); if (!fin) break; str.ToLower(); if (str.Strip(TString::kBoth)==preps) { ZdAz dest(zd, az); SetPosition(dest*TMath::DegToRad()); return 0x7979; } cout << "ERROR - Requested preposition not found in file..." << endl; } } //cout << "WM_Track: done. (return 0x8888)" << endl; return 0x7878; /* case WM_TESTSE: //cout << "WM_TestSe: start." << endl; fBackground = mp ? kBgdSeTest : kBgdNone; //cout << "WM_TestSe: done. (return 0x1e51)" << endl; return 0x1e51; case WM_GEAR: //cout << "WM_Gear: start." << endl; fBackground = mp ? kBgdGear : kBgdNone; //cout << "WM_Gear: done. (return 0xfeaf)" << endl; return 0xfeaf; case WM_DISPLAY: //cout << "WM_Display: start." << endl; fTriggerDisplay = kTRUE; //cout << "WM_Disply: done. (return 0xd1e1)" << endl; return 0xd1e1; */ case WM_TRACK: case WM_GRB: //cout << "WM_Track/GRB: START" << endl; { RaDec dest = ((RaDec*)mp)[0]; if (fStarguider) fStarguider->SetPointingPosition(((RaDec*)mp)[1]); if (!CheckNetwork()) return 0xebb0; if (msg==WM_TRACK) TrackPosition(dest*TMath::DegToRad()); else TrackPositionGRB(dest*TMath::DegToRad()); } //cout << "WM_Track/GRB: done. (return 0x8888)" << endl; return 0x8888; case WM_NEWTRACK: //cout << "WM_NewTrack: START" << endl; fRaDec = *((RaDec*)mp); //cout << "WM_NewTrack: done. (return 0x9999)" << endl; return 0x9999; case WM_LOADBENDING: //cout << "WM_LoadBending: START" << endl; fBending.Load("bending.txt"); //cout << "WM_LoadBending: done. (return 0xbe0d)" << endl; return 0xbe0d; case WM_RESETBENDING: //cout << "WM_ResetBending: START" << endl; fBending.Reset(); //cout << "WM_ResetBending: done. (return 0xbe0e)" << endl; return 0xbe0e; case WM_CALCALTAZ: { cout << endl; SlaStars sla(fObservatory); sla.Now(); XY xy = *((XY*)mp); RaDec rd(xy.X()*15., xy.Y()); // [deg] ZdAz a1 = sla.CalcZdAz(rd*TMath::DegToRad()); // [rad] cout << "Ra/Dec source: " << xy.X() << "h " << xy.Y() << "°" << endl; cout << "Zd/Az target: " << a1.Zd()*TMath::RadToDeg() << "° " << a1.Az()*TMath::RadToDeg() << "°" << endl; if (fMac1 && fMac2) a1 = AlignTrackingPos(a1); a1 = fBending(a1); CheckRange(a1); a1 *= TMath::RadToDeg(); const ZdAz a2 = a1/360; cout << "Zd/Az bended: " << a1.Zd() << "° " << a1.Az() << "°" << endl; cout << "SE bended: " << a2.Zd() << " " << a2.Az() << endl; } return 0xa17a; case WM_ENDSWITCH: { ZdAz pos = GetSePos()*TMath::TwoPi(); pos = fBending.SubtractOffsets(pos)*TMath::RadToDeg(); cout << "Endswitch Position: Zd=" << pos.Zd() << "° Az="; cout << pos.Az() << "°" << endl; } return 0x1010; case WM_QUIT: cout << "WM_Quit: now." << endl; if (!CheckNetwork()) { gLog << err << "ERROR: Cannot shutdown network." << endl; gLog << " Please shutdown the drive system manually" << endl; } TerminateApp(); cout << "WM_Quit: done." << endl; return 0xaaaa; } cout << "MCosy::Proc: Unknown message 0x" << msg << endl; return 0xffffffff; } void MCosy::ReadConfig(MEnv &env) { gLog << inf2 << "Reading telescope range..." << flush; const Double_t amin = env.GetValue("Az_Min[deg]", -95.0); const Double_t zmin = env.GetValue("Zd_Min[deg]", -75.0); fMin.Set(zmin, amin); const Double_t amax = env.GetValue("Az_Max[deg]", 305.0); const Double_t zmax = env.GetValue("Zd_Max[deg]", 98.25); fMax.Set(zmax, amax); gLog << "done." << endl; gLog << all << flush; gLog << " * Min: " << zmin << "deg " << amin << "deg" << endl; gLog << " * Max: " << zmax << "deg " << amax << "deg" << endl; fMin = fBending.AddOffsets(fMin*TMath::DegToRad()); fMax = fBending.AddOffsets(fMax*TMath::DegToRad()); gLog << " * Min': " << fMin.Zd()*TMath::RadToDeg() << "deg " << fMin.Az()*TMath::RadToDeg() << "deg" << endl; gLog << " * Max': " << fMax.Zd()*TMath::RadToDeg() << "deg " << fMax.Az()*TMath::RadToDeg() << "deg" << endl; } ZdAz MCosy::GetPointingPos() const { if (fMac1->IsZombieNode() || fMac2->IsZombieNode()) return ZdAz(0, 0); // GetPointingPos [deg] const ZdAz seist = GetSePos()*TMath::TwoPi(); // [rad] return fBending.CorrectBack(seist)*TMath::RadToDeg(); } Bool_t MCosy::HandleTimer(TTimer *t) { const Int_t rc = fMutexGui.TryLock(); if (rc==13) gLog << warn << "MCosy::HandleTimer - mutex is already locked by this thread" << endl; if (rc) { gLog << warn << "* GUI update skipped due to locked mutex." << endl; return kTRUE; } // // Update Gui, foremer MTGui. // if (fMac1) fMac1->DisplayVal(); if (fMac2) fMac2->DisplayVal(); /* Byte_t avail = 0; avail |= (fMac1 && !fMac1->IsZombieNode()) ? 0x01 : 0; avail |= (fMac2 && !fMac2->IsZombieNode()) ? 0x02 : 0; // avail |= (!(fStatus&MDriveCom::kError) && 1 ? 0x40 : 0; */ Bool_t armed = kTRUE; armed &= fMac1 && fMac1->IsArmed(); armed &= fMac2 && fMac2->IsArmed(); if (HasError()) SetStatus(MDriveCom::kError); const TString stataz = fMac1 ? fMac1->GetStatusDKC() : ""; const TString statzd = fMac2 ? fMac2->GetStatusDKC() : ""; const UInt_t stat1 = fMac1 ? fMac1->GetStatusPdo3() : 0; const UInt_t stat2 = fMac2 ? fMac2->GetStatusPdo3() : 0; ZdAz bendist = GetPointingPos(); //cout << (fStatus&MDriveCom::kTracking?"TRA: ":"POS: ") << bendist.Zd() << " " << bendist.Az() << endl; static MTimeout tout(0); if (tout.HasTimedOut()) { tout.Start(999); fCom->SendReport(fStatus, fRaDec, fZdAzSoll, bendist, fTrackingError, armed, fStarguider ? fStarguider->GetStarguiderMode() : 0); } fWin->UpdateWeather(*fCom); fWin->Update(bendist, fTrackingError, /*fVelocity, fOffset,*/ fRaDec, fZdAzSoll, fStatus, (stat1<<8)|stat2, HasConnection(), armed, statzd, stataz); gLog.UpdateGui(); if (fMutexGui.UnLock()==13) gLog << warn << "MCosy::HandleTimer - tried to unlock mutex locked by other thread." << endl; return kTRUE; } // -------------------------------------------------------------------------- // // Start the work of the application: // // Start the Can-Network. // Start the MCosy::TalkThread thread. // turn on the gui update // void MCosy::Start(MEnv &env) { // Don't call this function twice! Network::Start(); CheckForError(); ReadConfig(env); gLog << inf << "- Starting GUI update." << endl; fUpdateGui->TurnOn(); } // -------------------------------------------------------------------------- // // Start the work of the application: // // Turn of the gui update // stop the MCosy::TalkThread thread. // Stop the network // void MCosy::Stop() { gLog << inf << "- Stopping GUI update." << endl; fUpdateGui->TurnOff(); gLog << inf << "- GUI Update stopped." << endl; gLog << inf << "- Stopping CAN network." << endl; Network::Stop(); gLog << inf << "- CAN network stopped." << endl; gLog << inf << "- Stopping message queue." << endl; CancelThread(); gLog << inf << "- Message queue stopped." << endl; } TString MCosy::GetFileName(const char *path, const char *name, const char *ext) { // FIXME: Timeout missing while (1) { MTime time(-1); // This is the full qualified date which is part of the name const TString clock = time.GetStringFmt("%Y%m%d_%H%M%S"); // This gives the night in which the date belongs to time.SetMjd(TMath::Nint(time.GetMjd())); const TString night = time.GetStringFmt("%Y_%m_%d"); const TString dir = Form("%s/%s", path, night.Data()); const TString fname = Form("%s_%s.%s", name, clock.Data(), ext); const TString full = Form("%s/%s", dir.Data(), fname.Data()); gSystem->mkdir(dir, kTRUE); if (gSystem->AccessPathName(full, kFileExists)) return full; break;// !!!!!!!!!!!!!!!!!!!!!!! usleep(1000); } return ""; } MCosy::MCosy(MEnv &env, MDriveCom *com) : Network(), fObservatory(MObservatory::kMagic1), fStarguider(NULL), fMac1(0), fMac2(0), fStatus(MDriveCom::kStopped), fOutTp(0), fOutRep(0) { const Int_t id1 = env.GetValue("Az_Id", 1); const Int_t id2 = env.GetValue("Zd_Id", 3); fFilePrepos = env.GetValue("FilePredefinedPositions", "prepos.txt"); TString name = GetFileName("rep", "cosy", "rep"); gLog << inf << "Open Repfile: " << name << endl; fOutRep = new MLog(name, kTRUE); *fOutRep << all << "[Drive Report File]" << endl; *fOutRep << "Version " << endl; *fOutRep << "Date " << MTime(-1) << endl; *fOutRep << "[Reports]" << endl; const TString pointing = env.GetValue("PointingModel", "bending.txt"); gLog << all << "Reading pointing model from " << pointing << "..." << endl; if (fBending.Load(pointing)) gLog << all << "Reading pointing model from " << pointing << " successfull." << endl; else gLog << err << "ERROR - Reading pointing model from " << pointing << endl; // // Create Nodes // gLog << inf << "- Setting up network." << endl; fMac1=new Dkc(id1, "DKC/Az"); fMac2=new Dkc(id2, "DKC/Zd"); fMac1->SetReport(fOutRep); fMac2->SetReport(fOutRep); gLog << inf << "- Connecting devices to network." << endl; // // Connect the devices to the network // SetNode(fMac1); SetNode(fMac2); // // Create Gui Event timer and Gui // gLog << inf << "- Initializing GUI Timer." << endl; fUpdateGui = new TTimer(this, 100); // 100ms gLog << all << "- Starting GUI." << endl; fWin=new MGCosy(fObservatory, fFilePrepos, this); gLog.SetOutputGui(fWin->GetLog(), kTRUE); fMac2->SetDisplay(fWin->GetLabel2()); fMac1->SetDisplay(fWin->GetLabel1()); fCom = com;//new MDriveCom(this, addr, tx, rx, fOutRep); fCom->SetOutRep(fOutRep); // fCom->Start(); } void MCosy::TerminateApp() { gLog << inf2 << "MCosy::TerminateApp()" << endl; /* Int_t rc; TGMessageBox msg(this, gClient->GetRoot(), "Information", "Cosy is shutting down the system - this may take wa while!", kMBIconExclamation, kMBOK, //kMBClose &rc, 0); */ gLog.DisableOutputDevice(MLog::eGui); // FIXME: WHY DOES THIS CRASH THE APPLICATIOn WHILE TRAKING? // gLog.SetOutputGui(NULL, kFALSE); gApplication->Terminate(0); } MCosy::~MCosy() { if(fCom) { fCom->SetMsgQueue(NULL); fCom->SetOutRep(NULL); } gLog << inf2 << "Deleting GUI timer." << endl; // FIXME: Wait until last Update was finished!!! delete fUpdateGui; //fMutexGui.Lock(); // Now the files can safely be closed gLog << inf2 << "Closing output files." << endl; if (fOutTp) { *fOutTp << "END" << endl; delete fOutTp; } delete fOutRep; //gLog << inf2 << "Deleting CC communication." << endl; //delete fCom; gLog << inf2 << "Deleting Nodes." << endl; fMac1->SetReport(0); fMac2->SetReport(0); delete fMac1; delete fMac2; gLog << inf2 << "Deleting MGCosy." << endl; gLog.DisableOutputDevice(MLog::eGui); delete fWin; gLog << inf2 << "MGCosy destructed." << endl; }