//void MakeFullBigRIPSTree(char *outfile="bigrips.root"){
void MakeFullBigRIPSTree(char *infile, char *outfile="bigrips.root"){
// signal(SIGINT,stop_interrupt); // CTRL + C , interrupt
gSystem->Load("libXMLParser.so");
gSystem->Load("libanaroot.so");
TArtStoreManager * sman = TArtStoreManager::Instance();
TArtEventStore *estore = new TArtEventStore();
estore->SetInterrupt(&stoploop);
estore->Open(infile);
// estore->Open(2); // bigrips online
TArtBigRIPSParameters *para = TArtBigRIPSParameters::Instance();
para->LoadParameter("db/BigRIPSPPAC.xml");
para->LoadParameter("db/BigRIPSPlastic.xml");
para->LoadParameter("db/BigRIPSIC.xml");
para->LoadParameter("db/FocalPlane.xml");
TArtCalibPID *brcalib = new TArtCalibPID();
TArtCalibCoin *calcoin= new TArtCalibCoin();
TArtRecoPID *brreco = new TArtRecoPID();
// setting up rips parameters
TArtRIPS * rips3to5 = brreco->DefineNewRIPS(3,5,"matrix/mat1.mat",7.5715); // f3 - f5
TArtRIPS * rips5to7 = brreco->DefineNewRIPS(5,7,"matrix/mat2.mat",7.0675); // f5 - f7
// setting up tof
TArtTOF * tof3to7 = brreco->DefineNewTOF("F3pl","F7pl",242.513,5);
// setting up beam id devices
// TArtBeam *beam35 = brreco->DefineNewBeam(rips3to5,tof3to7,"F7IC");
// TArtBeam *beam57 = brreco->DefineNewBeam(rips5to7,tof3to7,"F7IC");
// TArtBeam *beam35ic11 = brreco->DefineNewBeam(rips3to5,tof3to7,"F11IC");
//TArtBeam *beam57ic11 = brreco->DefineNewBeam(rips5to7,tof3to7,"F11IC");
TArtBeam *beam37ic7 = brreco->DefineNewBeam(rips3to5,rips5to7,tof3to7,"F11IC");
// TArtBeam *beam37ic11 = brreco->DefineNewBeam(rips3to5,rips5to7,tof3to7,"F11IC");
TFile *fout = new TFile(outfile,"RECREATE");
TTree *tree = new TTree("tree","tree");
Int_t maxbit;
tree->Branch("maxbit",&maxbit,"maxbit/I");
// define data nodes which are supposed to be dumped to tree
TClonesArray * info_array =
(TClonesArray *)sman->FindDataContainer("EventInfo");
tree->Branch(info_array->GetName(),&info_array);
TClonesArray * ppac_array =
(TClonesArray *)sman->FindDataContainer("BigRIPSPPAC");
tree->Branch(ppac_array->GetName(),&ppac_array);
TClonesArray * pla_array =
(TClonesArray *)sman->FindDataContainer("BigRIPSPlastic");
tree->Branch(pla_array->GetName(),&pla_array);
TClonesArray * ic_array =
(TClonesArray *)sman->FindDataContainer("BigRIPSIC");
tree->Branch(ic_array->GetName(),&ic_array);
TClonesArray * fpl_array =
(TClonesArray *)sman->FindDataContainer("BigRIPSFocalPlane");
tree->Branch(fpl_array->GetName(),&fpl_array);
TClonesArray * tof_array =
(TClonesArray *)sman->FindDataContainer("BigRIPSTOF");
tree->Branch(tof_array->GetName(),&tof_array);
TClonesArray * rips_array =
(TClonesArray *)sman->FindDataContainer("BigRIPSRIPS");
tree->Branch(rips_array->GetName(),&rips_array);
TClonesArray * beam_array =
(TClonesArray *)sman->FindDataContainer("BigRIPSBeam");
tree->Branch(beam_array->GetName(),&beam_array);
TArtBeam *beam = (TArtBeam*)beam_array->At(0);
int neve = 0;
while(estore->GetNextEvent()){
maxbit = 0;
if(neve%1000==0)
cout << "event: " << neve << endl;
calcoin->ClearData();
calcoin->LoadData();
brcalib->ClearData();
brcalib->ReconstructData();
brreco->ClearData();
brreco->ReconstructData();
// beam->SetAoQ(beam->GetAoQ()-0.042);
Int_t tbit = ((TArtEventInfo*)info_array->At(0))->GetTriggerBit();
for(int i=1;;i++){
if(tbit%2 == 1)
maxbit = i;
else break;
tbit = tbit/2;
}
tree->Fill();
neve ++;
}
fout->Write();
fout->Close();
}
// void MakeAllTree(char *infile, char *outfile="run0025.root"){
int main(int argc, char** argv){
if(argc!=2){
cout << "Usage: ./maketree <run_number>" << endl;
exit(-1);
}
// signal(SIGINT,stop_interrupt); // CTRL + C , interrupt
// ========= Define input and output files
Int_t RunNumber = std::atoi(argv[argc-1]);
cout << endl << "---> Start analyzing Run# = " << RunNumber << endl;
char* inputfilename = (char*)Form("./ridf/72Fe/psp14%04d.ridf",RunNumber);
char* outputfilename = (char*)Form("./rootfiles/yama_run%04d.root",RunNumber);
// Create StoreManager both for calibration "TArtCalib..." and treatment "TArtReco..."
//------------------------------------------------------------------------------------
TArtStoreManager * sman = TArtStoreManager::Instance();
// Create EventStore to control the loop and get the EventInfo
//------------------------------------------------------------
/*
TArtEventStore *estore = new TArtEventStore();
estore->SetInterrupt(&stoploop);
estore->Open(infile);
std::cout<<"estore ->"<< infile <<std::endl;
*/
cout << "---> Open file name = " << inputfilename << endl << endl;
TArtEventStore *estore = new TArtEventStore();
estore->SetInterrupt(&stoploop);
int es = estore->Open(inputfilename);
if(es==0){
cout << endl << " === No data file === " << endl << endl;
exit(-1);
}
cout << endl << endl;
// Create BigRIPSParameters to get Plastics, PPACs, ICs and FocalPlanes parameters from ".xml" files
//--------------------------------------------------------------------------------------------------
TArtBigRIPSParameters *para = TArtBigRIPSParameters::Instance();
para->LoadParameter("db/BigRIPSPPAC.xml");
para->LoadParameter("db/BigRIPSPlastic.xml");
para->LoadParameter("db/BigRIPSIC.xml");
para->LoadParameter("db/FocalPlane.xml");
para->SetFocusPosOffset(8,138.5);
// Create CalibPID to get and calibrate raw data ( CalibPID ->
//[CalibPPAC , CalibIC, CalibPlastic , CalibFocalPlane]
TArtCalibPID *brcalib = new TArtCalibPID();
TArtCalibPPAC *ppaccalib = brcalib->GetCalibPPAC();
TArtCalibPlastic *plasticcalib = brcalib->GetCalibPlastic();
// Create RecoPID to get calibrated data and to reconstruct TOF, AoQ, Z, ... (RecoPID ->
//[ RecoTOF , RecoRIPS , RecoBeam] )
TArtRecoPID *recopid = new TArtRecoPID();
//para->PrintListOfPPACPara();
//return;
// Definition of observables we want to reconstruct
std::cout << "Defining bigrips parameters" << std::endl;
//TArtRIPS *rips3to5 = recopid->DefineNewRIPS(3,5,"matrix/mat1.mat",5.45); // F3 - F5
//TArtRIPS *rips5to7 = recopid->DefineNewRIPS(5,7,"matrix/mat2.mat",4.665); // F5 - F7
//TArtRIPS *rips8to9 = recopid->DefineNewRIPS(8,9,"matrix/F8F9_LargeAccAchr.mat",3.831); // F8 - F9
//TArtRIPS *rips9to11 = recopid->DefineNewRIPS(9,11,"matrix/F9F11_LargeAccAchr.mat",3.805); // F9 - F11
TArtRIPS *rips3to5 = recopid->DefineNewRIPS(3, 5,"matrix/mat1.mat","D3"); // F3 - F5
TArtRIPS *rips5to7 = recopid->DefineNewRIPS(5, 7,"matrix/mat2.mat","D5"); // F5 - F7
TArtRIPS *rips8to9 = recopid->DefineNewRIPS(8, 9,"matrix/F8F9_LargeAccAchr.mat","D7"); // F8 - F9
TArtRIPS *rips9to11 = recopid->DefineNewRIPS(9,11,"matrix/F9F11_LargeAccAchr.mat","D8"); // F9 - F11
/*
TArtRIPS *rips3to5 = recopid->DefineNewRIPS(3,5,"matrix/mat1.mat",6.303); // F3 - F5
TArtRIPS *rips5to7 = recopid->DefineNewRIPS(5,7,"matrix/mat2.mat",5.788); // F5 - F7
TArtRIPS *rips8to9 = recopid->DefineNewRIPS(8,9,"matrix/F8F9_LargeAccAchr.mat",4.609); // F8 - F9
TArtRIPS *rips9to11 = recopid->DefineNewRIPS(9,11,"matrix/F9F11_LargeAccAchr.mat",4.566); // F9 - F11
*/
// Reconstruction of TOF DefineNewTOF(fisrt plane, second plane, time offset)
TArtTOF *tof3to7 = recopid->DefineNewTOF("F3pl","F7pl",302,5); // F3 - F7
//TArtTOF *tof8to11 = recopid->DefineNewTOF("F8pl","F11pl-1",-160.5,9); // F8 - F11
TArtTOF *tof8to11 = recopid->DefineNewTOF("F8pl","F11pl-1",-749.2,9); // F8 - F11
// Reconstruction of IC observables for ID
TArtBeam *beam_br_35 = recopid->DefineNewBeam(rips3to5,rips5to7,tof3to7,"F7IC");
TArtBeam *beam_br_57 = recopid->DefineNewBeam(rips5to7,tof3to7,"F7IC");
TArtBeam *beam_zd_89 = recopid->DefineNewBeam(rips8to9,tof8to11,"F11IC");
TArtBeam *beam_zd_911 = recopid->DefineNewBeam(rips9to11,tof8to11,"F11IC");
//to get trigger pattern
//TArtEventInfo *evtinfo=new TArtEventInfo();
// Create DALIParameters to get ".xml"
//------------------------------------
TArtDALIParameters *dpara = TArtDALIParameters::Instance();
dpara->LoadParameter("db/DALI.xml");
// Create CalibDALI to get and calibrate raw data
//-----------------------------------------------
TArtCalibDALI *dalicalib = new TArtCalibDALI();
//TArtCalibDALI *dalicalib2 = new TArtCalibDALI();
// Create MINOSParameters to get ".xml"
//------------------------------------
TArtMINOSParameters *mpara = new TArtMINOSParameters("MINOSParameters","MINOSParameters");
mpara->LoadParameters("./db/MINOS.xml");
// Parameters for the MINOS ANALYSIS
string ConfigBeam;
double MINOSthresh;
double TimeBinElec; //in ns
double VDrift; //in cm/µs
double Tshaping; // in ns
double DelayTrig; // in ns
double DALIOffset;
ifstream ConfigFile;
ConfigFile.open("./../ConfigFileSetup.txt");
string Header;
ConfigFile >> ConfigBeam;
ConfigFile >> Header >> MINOSthresh;
ConfigFile >> Header >> TimeBinElec;
ConfigFile >> Header >> VDrift;
ConfigFile >> Header >> Tshaping;
ConfigFile >> Header >> DelayTrig;
ConfigFile >> Header >> DALIOffset;
ConfigFile.close();
// Create CalibMINOS to get and calibrate raw data
//-----------------------------------------------
TArtCalibMINOS *minoscalib = new TArtCalibMINOS();
TArtAnalyzedMINOS *minosanalyzed = new TArtAnalyzedMINOS(minoscalib);
TArtTrackMINOS *minostrack = new TArtTrackMINOS();
TArtVertexMINOS *minosvertex = new TArtVertexMINOS();
std::cout<<"para"<<std::endl;
/*
TFile *fout = new TFile(outfile,"RECREATE");
TTree *tree = new TTree("tree","tree");
*/
cout << endl << "---> Output file name = " << outputfilename << endl << endl;
TFile *fout = new TFile(outputfilename,"RECREATE");
TTree *tree = new TTree("tree","tree");
// define data nodes which are supposed to be dumped to tree
//EventInfo is importand for the fBit information to know the trigger!
TClonesArray * info_array = (TClonesArray *)sman->FindDataContainer("EventInfo");
std::cout<<info_array->GetName()<<std::endl;
tree->Branch(info_array->GetName(),&info_array);
TClonesArray * ppac_array =
(TClonesArray *)sman->FindDataContainer("BigRIPSPPAC");
std::cout<<ppac_array->GetName()<<std::endl;
tree->Branch(ppac_array->GetName(),&ppac_array);
TClonesArray * pla_array =
(TClonesArray *)sman->FindDataContainer("BigRIPSPlastic");
tree->Branch(pla_array->GetName(),&pla_array);
TClonesArray * ic_array =
(TClonesArray *)sman->FindDataContainer("BigRIPSIC");
tree->Branch(ic_array->GetName(),&ic_array);
TClonesArray * fpl_array =
(TClonesArray *)sman->FindDataContainer("BigRIPSFocalPlane");
tree->Branch(fpl_array->GetName(),&fpl_array);
//Dali data
TClonesArray * dali_array=
(TClonesArray *)sman->FindDataContainer("DALINaI");
tree->Branch(dali_array->GetName(),&dali_array);
//PID reconstructed data:
TClonesArray *rips_array =
(TClonesArray *)sman->FindDataContainer("BigRIPSRIPS");
std::cout<<rips_array->GetName()<<std::endl;
tree->Branch(rips_array->GetName(),&rips_array);
TClonesArray *tof_array =
(TClonesArray *)sman->FindDataContainer("BigRIPSTOF");
std::cout<<tof_array->GetName()<<std::endl;
tree->Branch(tof_array->GetName(),&tof_array);
TClonesArray *beam_array =
(TClonesArray *)sman->FindDataContainer("BigRIPSBeam");
std::cout<<beam_array->GetName()<<std::endl;
tree->Branch(beam_array->GetName(),&beam_array);
TClonesArray *analyzedminos_array =
(TClonesArray *)sman->FindDataContainer("AnalyzedMINOS");
std::cout<<analyzedminos_array->GetName()<<std::endl;
tree->Branch(analyzedminos_array->GetName(),&analyzedminos_array);
TClonesArray *trackminos_array =
(TClonesArray *)sman->FindDataContainer("TrackMINOS");
std::cout<<trackminos_array->GetName()<<std::endl;
tree->Branch(trackminos_array->GetName(),&trackminos_array);
/*
//minos
anaminos_array =(TClonesArray *)sman->FindDataContainer("AnalyzedMINOS");
tree->Branch(anaminos_array->GetName(),&anaminos_array);
trackminos_array =(TClonesArray *)sman->FindDataContainer("TrackMINOS");
tree->Branch(trackminos_array->GetName(),&trackminos_array);
*/
//_________________________________________________________________________
//Making new branches
//%%%%%%%%%%%%%%%%%%%%%%
//BigRIPS
Double_t fF8PPACX[4] = {-999.};
Double_t fF8PPACY[4] = {-999.};
Double_t fF8PPACZ[4] = {-999.};
Double_t fF8PosX[2] = {-999.};
Double_t fF8PosY[2] = {-999.};
Double_t fF8PosZ[2] = {-999.};
Double_t fXTar = -999.;
Double_t fYTar = -999.;
Int_t fGoodPPACFocus[12] = {0};
Int_t fGoodPPACFocusOr[12] = {0};
tree->Branch("xtar",&fXTar,"fXTar/D");
tree->Branch("ytar",&fYTar,"fYTar/D");
//tree->Branch("f8ppacx",fF8PPACX,"fF8PPACX[6]/D");
//tree->Branch("f8ppacy",fF8PPACY,"fF8PPACY[6]/D");
//tree->Branch("f8posx",fF8PosX,"fF8PosX[3]/D");
//tree->Branch("f8posy",fF8PosY,"fF8PosY[3]/D");
tree->Branch("fgoodppacfocus",fGoodPPACFocus,"fGoodPPACFocus[12]/I");
tree->Branch("fgoodppacfocusor",fGoodPPACFocusOr,"fGoodPPACFocusOr[12]/I");
//%%%%%%%%%%%%%%%%%%%%%%
//DALI
Int_t dalimultwotime = 0;
Int_t dalimult = 0;
Int_t dalitimetruemult = 0;
Int_t dalimultthres = 0;
Int_t dalitimetruemultthres = 0;
tree->Branch("dalimultwotime",&dalimultwotime,"dalimultwotime/I");
tree->Branch("dalimult",&dalimult,"dalimult/I");
tree->Branch("dalitimetruemult",&dalitimetruemult,"dalitimetruemult/I");
tree->Branch("dalimultthres",&dalimultthres,"dalimultthres/I");
tree->Branch("dalitimetruemultthres",&dalitimetruemultthres,"dalitimetruemultthres/I");
//%%%%%%%%%%%%%%%%%%%%%%
//MINOS
Double_t z_vertex=0.;
tree->Branch("z_vertex",&z_vertex,"z_vertex/D");
Double_t beta_vertex=0.;
tree->Branch("beta_vertex",&beta_vertex,"beta_vertex/D");
int neve = 0;
while(estore->GetNextEvent()){
if(neve%1000==0)
std::cout << "event: " << neve << std::endl;
//%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%
//Making the BigRIPS tree calibration
brcalib->ClearData();
brcalib->ReconstructData();
//Reconstructiong the PID
recopid->ClearData();
recopid->ReconstructData();
//Reconstructing the scattering angle:
//Beam spot on target reconstruction
fXTar=-999.;
fYTar=-999.;
for(int i=0;i<4;i++){
fF8PPACX[i] = -999.;
fF8PPACY[i] = -999.;
fF8PPACZ[i] = -999.;
}
for(int i=0;i<2;i++){
fF8PosX[i] = -999.;
fF8PosY[i] = -999.;
fF8PosZ[i] = -999.;
}
for(int i=0;i<12;i++) {
fGoodPPACFocus[i] = 0;
fGoodPPACFocusOr[i] = 0;
}
bool fired[14] = {false};
bool posRec = false;
TArtPPAC *fppac[12];
fppac[0] = ppaccalib->FindPPAC("F8PPAC-1A");
fppac[1] = ppaccalib->FindPPAC("F8PPAC-1B");
fppac[2] = ppaccalib->FindPPAC("F8PPAC-2A");
fppac[3] = ppaccalib->FindPPAC("F8PPAC-2B");
fppac[4] = ppaccalib->FindPPAC("F9PPAC-1A");
fppac[5] = ppaccalib->FindPPAC("F9PPAC-1B");
fppac[6] = ppaccalib->FindPPAC("F9PPAC-2A");
fppac[7] = ppaccalib->FindPPAC("F9PPAC-2B");
fppac[8] = ppaccalib->FindPPAC("F11PPAC-1A");
fppac[9] = ppaccalib->FindPPAC("F11PPAC-1B");
fppac[10] = ppaccalib->FindPPAC("F11PPAC-2A");
fppac[11] = ppaccalib->FindPPAC("F11PPAC-2B");
for(int i=0;i<12;i++){
if(fppac[i]!=0){
if(fppac[i]->IsFiredX()&&fppac[i]->IsFiredY()) fired[i] = true;
}
}
if(fppac[0]!=0&&fppac[1]!=0&&fppac[2]!=0&&fppac[3]!=0){
if(fppac[0]->IsFiredX()&&fppac[1]->IsFiredX()&&fppac[2]->IsFiredX()&&fppac[3]->IsFiredX()) fGoodPPACFocus[8] = 1;
if((fppac[0]->IsFiredX()||fppac[1]->IsFiredX())&&(fppac[2]->IsFiredX()||fppac[3]->IsFiredX()))
fGoodPPACFocusOr[8] = 1;
}
if(fppac[4]!=0&&fppac[5]!=0&&fppac[6]!=0&&fppac[7]!=0){
if(fppac[4]->IsFiredX()&&fppac[5]->IsFiredX()&&fppac[6]->IsFiredX()&&fppac[7]->IsFiredX()) fGoodPPACFocus[9] = 1;
if((fppac[4]->IsFiredX()||fppac[5]->IsFiredX())&&(fppac[6]->IsFiredX()||fppac[7]->IsFiredX()))
fGoodPPACFocusOr[9] = 1;
}
if(fppac[8]!=0&&fppac[9]!=0&&fppac[10]!=0&&fppac[11]!=0){
if(fppac[8]->IsFiredX()&&fppac[9]->IsFiredX()&&fppac[10]->IsFiredX()&&fppac[11]->IsFiredX()) fGoodPPACFocus[11] = 1;
if((fppac[8]->IsFiredX()||fppac[9]->IsFiredX())&&(fppac[10]->IsFiredX()||fppac[11]->IsFiredX()))
fGoodPPACFocusOr[11] = 1;
}
for(int i=0;i<4;i++){
if(fired[i]==false) continue;
fF8PPACX[i] = fppac[i]->GetX();
fF8PPACY[i] = fppac[i]->GetY();
fF8PPACZ[i] = fppac[i]->GetXZPos();
}
//For the F8 scattering angle:
for(int i=0;i<2;i++){
if(fired[2*i]==true&&fired[2*i+1]==true) {
fF8PosX[i] = (fppac[2*i]->GetX()+fppac[2*i+1]->GetX())/2;
fF8PosY[i] = (fppac[2*i]->GetY()+fppac[2*i+1]->GetY())/2;
fF8PosZ[i] = (fppac[2*i]->GetXZPos()+fppac[2*i+1]->GetXZPos())/2;
//posRec = true;
}
else if (fired[2*i]==true||fired[2*i+1]==true){
int j;
posRec = true;
if (fired[2*i]==true) j = 2*i;
else j = 2*i+1;
fF8PosX[i] = fppac[j]->GetX();
fF8PosY[i] = fppac[j]->GetY();
fF8PosZ[i] = fppac[j]->GetXZPos();
}
else continue;
//cout<<"posX: "<<posX[i]<<endl;
}
if( (fired[0]==true||fired[1]==true) &&
(fired[2]==true||fired[3]==true)) posRec = true;
if(posRec) {
double mX = (fF8PosX[1]-fF8PosX[0])/(fF8PosZ[1]-fF8PosZ[0]);
double mY = (fF8PosY[1]-fF8PosY[0])/(fF8PosZ[1]-fF8PosZ[0]);
fXTar = fF8PosX[1] + mX * 880;
fYTar = fF8PosY[1] + mY * 880;
}
//%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%
//Making MINOS
minoscalib->ClearData();
minosanalyzed->ClearData();
minostrack->ClearData();
minosvertex->ClearData();
minoscalib->ReconstructData();
minosanalyzed->ReconstructData();
minostrack->ReconstructData();
minosvertex->ReconstructVertex();
// Convert the reconstructed vertex in z (mm)
z_vertex = minosvertex->GetZvCal(1e-3*VDrift, TimeBinElec, DelayTrig); //time bin*(ns/us)*vdrift(cm/us) == z_vertex in cm
beta_vertex = minosvertex->GetBetaV();
//%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%
//Making DALI
dalicalib->ClearData();
//dalicalib->SetPlTime(plasticcalib->FindPlastic("F8pl")->GetTime());
//dalicalib->SetVertex(z_vertex-DALIOffset/10.);
//dalicalib->SetBeta(beta_vertex);
/*
dalicalib2->ClearData();
//dalicalib2->SetPlTime(plasticcalib->FindPlastic("F8pl")->GetTime());
//dalicalib2->SetVertex(z_vertex-DALIOffset/10.);
//dalicalib2->SetBeta(beta_vertex);
*/
//Add above to remove F8plastic tof.
dalicalib->ReconstructData();
//dalicalib2->ReconstructData();
dalimultwotime = dalicalib->GetMultWithoutT();
dalimult = dalicalib->GetMult();
dalitimetruemult = dalicalib->GetTimeTrueMult();
dalimultthres = dalicalib->GetMultThres();
dalitimetruemultthres = dalicalib->GetTimeTrueMultThres();
tree->Fill();
neve++;
}
cout<<"Writing the tree."<<endl;
fout->Write();
fout->Close();
}
