/* ======================================================================== *\ ! ! * ! * This file is part of CheObs, the Modular 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 appears 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, 1/2009 ! ! Copyright: CheObs Software Development, 2000-2009 ! ! \* ======================================================================== */ ////////////////////////////////////////////////////////////////////////////// // // MReflector // ////////////////////////////////////////////////////////////////////////////// #include "MReflector.h" #include #include #include // atof (Ubuntu 8.10) #include #include #include #include "MQuaternion.h" #include "MMirror.h" #include "MLog.h" #include "MLogManip.h" #include "MH.h" ClassImp(MReflector); using namespace std; // -------------------------------------------------------------------------- // // Default constructor // MReflector::MReflector(const char *name, const char *title) { fName = name ? name : "MReflector"; fTitle = title ? title : "Parameter container storing a collection of several mirrors (reflector)"; fMirrors.SetOwner(); } // -------------------------------------------------------------------------- // // Set the SigmaPSF of all mirrors currently stored. // void MReflector::SetSigmaPSF(Double_t psf) { fMirrors.R__FOR_EACH(MMirror, SetSigmaPSF)(psf); } // -------------------------------------------------------------------------- // // Calculate the maximum radius of th ereflector. This is not meant as // a precise number but as a rough estimate e.g. to bin a histogram. // void MReflector::InitMaxR() { fMaxR = 0; TIter Next(&fMirrors); MMirror *m = 0; while ((m=static_cast(Next()))) { // Take into account the maximum incident angle 8eg 10deg) and // the theta-angle of the mirror and the z-distance. const Double_t r = m->GetDist()+1.5*m->GetMaxR(); if (r > fMaxR) fMaxR = r; } } // -------------------------------------------------------------------------- // // Return the total Area of all mirrors. Note, that it is recalculated // with any call. // Double_t MReflector::GetA() const { Double_t A = 0; TIter Next(&fMirrors); MMirror *m = 0; while ((m=static_cast(Next()))) A += m->GetA(); return A; } // -------------------------------------------------------------------------- // // Get the pointer to the first mirror. This is a very dangerous way of // access, but the fastest possible. because it is the most often called // function in ExecuteReflector we have to have a very fast access. // const MMirror **MReflector::GetFirstPtr() const { return (const MMirror**)fMirrors.GetObjectRef(0); } // -------------------------------------------------------------------------- // // Get number of mirrors. There should be no holes in the array! // const UInt_t MReflector::GetNumMirrors() const { return fMirrors.GetEntriesFast(); } // -------------------------------------------------------------------------- // // Check with a rough estimate whether a photon can hit the reflector. // Bool_t MReflector::CanHit(const MQuaternion &p) const { // p is given in the reflectory coordinate frame. This is meant as a // fast check without lengthy calculations to omit all photons which // cannot hit the reflector at all return p.R2()GetName()), atof(arr[1]->GetName()), atof(arr[2]->GetName())); const TVector3 norm(atof(arr[3]->GetName()), atof(arr[4]->GetName()), atof(arr[5]->GetName())); UInt_t n = 6; TString six = arr[n]->GetName(); Char_t shape = 'S'; if (!six.IsFloat()) { shape = six[0]; n++; } const Double_t F = atof(arr[n++]->GetName()); const TString val = arr[n++]->GetName(); const Double_t psf = val.IsFloat() ? val.Atof() : -1; n += val.IsFloat() ? 1 : 0; TString type = arr[n-1]->GetName(); type.Prepend("MMirror"); for (UInt_t i=0; iInheritsFrom(MMirror::Class())) { *fLog << err << "ERROR - Cannot create new instance of class " << type << ": " << endl; *fLog << "Class doesn't inherit from MMirror." << endl; return 0; } MMirror *m = static_cast(cls->New()); if (!m) { *fLog << err << "ERROR - Cannot create new instance of class " << type << ": " << endl; *fLog << " - Class has no default constructor." << endl; *fLog << " - An abstract member functions of a base class is not overwritten." << endl; return 0; } m->SetPosition(pos); m->SetNorm(norm); m->SetShape(shape); m->SetFocalLength(F); m->SetSigmaPSF(psf>=0 ? psf : defpsf); if (m->ReadM(arr)>=0) return m; *fLog << err << "ERROR - " << type << "::ReadM failed." << endl; delete m; return 0; } // -------------------------------------------------------------------------- // // Read a reflector setup from a file. This needs improvemtn. // // The file structur is like: // // x y z nx ny nz F [psf] Type ... // // x: x-coordinate of the mirror's center // y: y-coordinate of the mirror's center // z: z-coordinate of the mirror's center // nx: x-component of the normal vecor in the mirror center // ny: y-component of the normal vecor in the mirror center // nz: z-component of the normal vecor in the mirror center // [shape]: S for spherical , P for parabolic // F: Focal distance of a spherical mirror // [psf]: This number is the psf given in the units of x,y,z and // defined at the focal distance F. It can be used to overwrite // the second argument given in ReadFile for individual mirrors. // Type: A instance of a mirrot of the class Type MMirrorType is created // (Type can be, for example, Hex for for MMirrorHex). // ...: Additional arguments as defined in MMirrorType::ReadM // // // Coordinate System: // The coordinate system is local in the reflectors frame. // It is defined viewing from the back side of the reflector // towards the camera. (x "right", y "up", z from reflector to camera) // Note, that it is left-handed! // Bool_t MReflector::ReadFile(TString fname, Double_t defpsf) { SetTitle(fname); fMirrors.Delete(); gSystem->ExpandPathName(fname); ifstream fin(fname); if (!fin) { *fLog << err << "Cannot open file " << fname << ": "; *fLog << (errno!=0?strerror(errno):"Insufficient memory for decompression") << endl; return kFALSE; } /* Int_t idx[964]; Int_t srt[964]; for (int i=0; i<964; i++) srt[i] = gRandom->Integer(964); TMath::Sort(964, srt, idx); */ Int_t cnt = 0; while (1) { TString line; line.ReadLine(fin); if (!fin) break; // Count lines cnt++; // Skip comments if (line.BeginsWith("#")) continue; // Remove leading and trailing whitespaces line=line.Strip(TString::kBoth); // Skip empty lines if (line.IsNull()) continue; // Tokenize line TObjArray *arr = line.Tokenize(' '); // Evaluate tokens MMirror *m = EvalTokens(*arr, defpsf); // Delete now obsolete array delete arr; // Check if a new mirror could be created successfully if (!m) { *fLog << err << "Error in line " << cnt << ": " << line << endl; return kFALSE; } // Add new mirror to array fMirrors.Add(m); } InitMaxR(); return kTRUE; // fMirrors.Sort(); /* for (int i=0; i<964; i++) { MMirror &ref = (MMirror&)*fMirrors[i]; TArrayD dist(964); for (int j=0; j<964; j++) { const MMirror &mir = (MMirror&)*fMirrors[j]; dist[j] = (ref-mir).Mod(); } TArrayI idx(964); TMath::Sort(964, dist.GetArray(), idx.GetArray(), kFALSE); for (int j=0; j<964; j++) { ref.fNeighbors.Add(fMirrors[idx[j]]); } }*/ } // -------------------------------------------------------------------------- // // Print the collection of mirrors // void MReflector::Print(Option_t *o) const { *fLog << all << GetDescriptor() << " (" << GetNumMirrors() << "): " << endl; fMirrors.Print(o); } // -------------------------------------------------------------------------- // // Paint the collection of mirrors // void MReflector::Paint(Option_t *o) { if (!TString(o).Contains("same", TString::kIgnoreCase)) MH::SetPadRange(-fMaxR*1.01, -fMaxR*1.01, fMaxR*1.01, fMaxR*1.01); fMirrors.Paint(o); TEllipse e; e.SetFillStyle(0); e.SetLineColor(17); e.PaintEllipse(0, 0, fMaxR, fMaxR, 0, 360, 0); } // -------------------------------------------------------------------------- // // SigmaPSF: -1 // FileName: reflector.txt // // SigmaPSF can be used to set a default for the psf of the mirrors // read from the file. Note, that this can be overwritten for individual // mirrors in the file. The SigmaPSF is the sigma of a 1D-Gauss fitted // to the radial profile of the light distribution. // // For details on the file structure see MReflector::ReadFile // Int_t MReflector::ReadEnv(const TEnv &env, TString prefix, Bool_t print) { Bool_t rc = kFALSE; Double_t psf = -1; if (IsEnvDefined(env, prefix, "SetSigmaPSF", print)) { rc = kTRUE; psf = GetEnvValue(env, prefix, "SetSigmaPSF", -1); } if (IsEnvDefined(env, prefix, "FileName", print)) { rc = kTRUE; if (!ReadFile(GetEnvValue(env, prefix, "FileName", ""), psf)) return kERROR; } return rc; }