////////////////////////////////////////////////////////////////// // Macro to check clusters in the 2 SPD layers // // Provides: // // 2 canvases with // // - cluster loc and glob coordinates (each layer) // // 1 canvas with // // - cluster glob coordinates 2D and 3D // // 1 canvas with // // - correlations of #clusters for sectors // // - correlations of #clusters for half-sectors // // // // Maria.Nicassio@ba.infn.it // // Domenico.Elia@ba.infn.it // ////////////////////////////////////////////////////////////////// #if !defined(__CINT__) || defined(__MAKECINT__) #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include "AliCDBManager.h" #include "AliRunLoader.h" #include "AliESD.h" #include "AliRun.h" #include "AliGeomManager.h" #include "AliITS.h" #include "AliITSgeom.h" #include "AliITSLoader.h" #include #include #include #endif /* $Id$ */ void ShowSPDRecPoints(Int_t RunStart, Int_t RunStop){ // Set data directory Char_t str[256]; Char_t* dir = "/data/alipix/PhysicsEvents/pp/ppProd/pdc07/oldgeom"; // Variables for histo booking and filling Int_t modmin=0; Int_t modmax=240; Int_t totmod=modmax-modmin; Float_t xlim[2]={4.5,8.}; Float_t zlim[2]={15.,15.}; Int_t nClusters[2]; Float_t clustersXCoord[2][200]; Float_t clustersYCoord[2][200]; Float_t clustersZCoord[2][200]; Float_t cluGlo[3]={0.,0.,0.}; Int_t nClustersPerLayerPerSector[2][10]; Int_t nClustersPerLayerPerHalfSector[2][20]; Int_t iSector=0; Int_t iHalfSector=0; // Booking of histograms gStyle->SetPalette(1,0); TH1F* hlayer= new TH1F("hlayer","",6,0.,6.); TH1F** hmod = new TH1F*[2]; TH1F** hxl = new TH1F*[2]; TH1F** hzl = new TH1F*[2]; TH1F** hxg = new TH1F*[2]; TH1F** hyg = new TH1F*[2]; TH1F** hzg = new TH1F*[2]; TH1F** hr = new TH1F*[2]; TH1F** hphi = new TH1F*[2]; TH1F** hMultSPDcl = new TH1F*[2]; TH1F** hType = new TH1F*[2]; // cluster type ? TH2F** hr_phi = new TH2F*[2]; TH2F** hx_y = new TH2F*[2]; TH3F** hx_y_z = new TH3F*[2]; TH2F** hnCl2_nCl1_Sec = new TH2F*[10]; TProfile** hnCl2vsnCl1_Sec = new TProfile*[10]; TH2F** hnCl2_nCl1_HSec = new TH2F*[20]; // TProfile** hnCl2vsnCl1_HSec = new TProfile*[20]; TH2F** hNy_Nz = new TH2F*[2]; // y and z length TH2F** hPhi_Z = new TH2F*[2]; TH2F *hMultSPDcl2_MultSPDcl1 = new TH2F("nCl2_nCl1","# SPD clusters on layer 2 vs # on layer 1",200,0.,200.,200,0.,200.); hMultSPDcl2_MultSPDcl1->GetXaxis()->SetTitle("# clusters (inner layer)"); hMultSPDcl2_MultSPDcl1->GetYaxis()->SetTitle("# clusters (outer layer)"); Char_t name[10]; Char_t title[20]; for (Int_t iLay=0;iLay<2;iLay++) { sprintf(name,"hmod%d",iLay+1); hmod[iLay]=new TH1F(name,"SPD clusters - Module number",totmod,modmin,modmax); hmod[iLay]->GetXaxis()->SetTitle("Module number"); hmod[iLay]->GetYaxis()->SetTitle("Entries"); sprintf(name,"hxloc%d",iLay+1); hxl[iLay]=new TH1F(name,"SPD clusters - Local x coordinate",100,-4.,4.); hxl[iLay]->GetXaxis()->SetTitle("Local x [cm]"); hxl[iLay]->GetYaxis()->SetTitle("Entries"); sprintf(name,"hzloc%d",iLay+1); hzl[iLay]=new TH1F(name,"SPD clusters - Local z coordinate",100,-4.,4.); hzl[iLay]->GetXaxis()->SetTitle("Local z [cm]"); hzl[iLay]->GetYaxis()->SetTitle("Entries"); sprintf(name,"hxgl%d",iLay+1); hxg[iLay]=new TH1F(name,"SPD clusters - Global x coordinate",100,-xlim[iLay],xlim[iLay]); hxg[iLay]->GetXaxis()->SetTitle("Global x [cm]"); hxg[iLay]->GetYaxis()->SetTitle("Entries"); sprintf(name,"hygl%d",iLay+1); hyg[iLay]=new TH1F(name,"SPD clusters - Global y coordinate",100,-xlim[iLay],xlim[iLay]); hyg[iLay]->GetXaxis()->SetTitle("Global y [cm]"); hyg[iLay]->GetYaxis()->SetTitle("Entries"); sprintf(name,"hzgl%d",iLay+1); hzg[iLay]=new TH1F(name,"SPD clusters - Global z coordinate",150,-zlim[iLay],zlim[iLay]); hzg[iLay]->GetXaxis()->SetTitle("Global z [cm]"); hzg[iLay]->GetYaxis()->SetTitle("Entries"); sprintf(name,"hr%d",iLay+1); hr[iLay]=new TH1F(name,"SPD clusters - r",100,0.,50.); hr[iLay]->GetXaxis()->SetTitle("r [cm]"); hr[iLay]->GetYaxis()->SetTitle("Entries"); sprintf(name,"hphi%d",iLay+1); hphi[iLay]=new TH1F(name,"SPD clusters - #phi",100,0.,2*TMath::Pi()); hphi[iLay]->GetXaxis()->SetTitle("#phi [rad]"); hphi[iLay]->GetYaxis()->SetTitle("Entries"); sprintf(name,"hType%d",iLay+1); hType[iLay]=new TH1F(name,"SPD clusters - Type",100,0.,100.); hType[iLay]->GetXaxis()->SetTitle("Cluster type"); hType[iLay]->GetYaxis()->SetTitle("Entries"); sprintf(name,"hMultSPDcl%d",iLay+1); hMultSPDcl[iLay]=new TH1F(name,"Cluster multiplicity",200,0.,200.); hMultSPDcl[iLay]->GetXaxis()->SetTitle("Cluster multiplicity"); hMultSPDcl[iLay]->GetYaxis()->SetTitle("Entries"); sprintf(name,"hNy_Nz%d",iLay+1); hNy_Nz[iLay]=new TH2F(name,"SPD clusters - Length",100,0.,100.,100,0.,100.); hNy_Nz[iLay]->GetXaxis()->SetTitle("z length"); hNy_Nz[iLay]->GetYaxis()->SetTitle("y length"); sprintf(name,"hPhi_Z%d",iLay+1); hPhi_Z[iLay]=new TH2F(name,"SPD clusters - #phi vs z",150,-zlim[iLay],zlim[iLay],100,0.,2*TMath::Pi()); hPhi_Z[iLay]->GetXaxis()->SetTitle("Global z [cm]"); hPhi_Z[iLay]->GetYaxis()->SetTitle("#phi [rad]"); sprintf(name,"hr_phi%d",iLay+1); hr_phi[iLay]=new TH2F(name,"SPD clusters - #phi_r",500,0.,50.,100,0.,2*TMath::Pi()); hr_phi[iLay]->GetXaxis()->SetTitle("r [cm]"); hr_phi[iLay]->GetYaxis()->SetTitle("#phi [rad]"); sprintf(name,"hx_y%d",iLay+1); hx_y[iLay]=new TH2F(name,"SPD clusters - y_x",200,-10.,10.,200,-10.,10.); hx_y[iLay]->GetXaxis()->SetTitle("x [cm]"); hx_y[iLay]->GetYaxis()->SetTitle("y [cm]"); sprintf(name,"hx_y_z%d",iLay+1); hx_y_z[iLay]=new TH3F(name,"SPD clusters - y_x",200,-10.,10.,200,-10.,10.,150,-15.,15.); hx_y_z[iLay]->GetXaxis()->SetTitle("z [cm]"); hx_y_z[iLay]->GetYaxis()->SetTitle("x [cm]"); hx_y_z[iLay]->GetZaxis()->SetTitle("y [cm]"); } for (Int_t iSec=0; iSec<10; iSec++) { sprintf(name,"hnCl2_nCl1_Sector%d",iSec); sprintf(title,"Sector %d",iSec+1); hnCl2_nCl1_Sec[iSec]=new TH2F(name,title,200,0.,200.,200,0.,200.); hnCl2_nCl1_Sec[iSec]->GetXaxis()->SetTitle("# clusters (inner layer)"); hnCl2_nCl1_Sec[iSec]->GetYaxis()->SetTitle("# clusters (outer layer)"); sprintf(name,"hnCl2vsnCl1_Sector%d",iSec); sprintf(title,"Sector %d",iSec+1); hnCl2vsnCl1_Sec[iSec]=new TProfile(name,title,200,0.,200.,0.,200.); hnCl2vsnCl1_Sec[iSec]->GetXaxis()->SetTitle("# clusters (inner layer)"); hnCl2vsnCl1_Sec[iSec]->GetYaxis()->SetTitle("# clusters (outer layer)"); } for (Int_t iHalfSec=0; iHalfSec<20; iHalfSec++) { sprintf(name,"hnCl2_nCl1_HalfSector%d",iHalfSec); sprintf(title,"Half-Sector %d",iHalfSec+1); hnCl2_nCl1_HSec[iHalfSec]=new TH2F(name,title,200,0.,200.,200,0.,200.); hnCl2_nCl1_HSec[iHalfSec]->GetXaxis()->SetTitle("# clusters (inner layer)"); hnCl2_nCl1_HSec[iHalfSec]->GetYaxis()->SetTitle("# clusters (outer layer)"); } // Loop over runs for (Int_t run=RunStart; run " << run << endl; if (gClassTable->GetID("AliRun") < 0) { gInterpreter->ExecuteMacro("loadlibs.C"); } else { if (gAlice){ delete AliRunLoader::Instance(); delete gAlice; gAlice=0; } } // Set OfflineConditionsDataBase if needed AliCDBManager* man = AliCDBManager::Instance(); if (!man->IsDefaultStorageSet()) { printf("Setting a local default storage and run number 0\n"); man->SetDefaultStorage("local://$ALICE_ROOT/OCDB"); man->SetRun(0); } else { printf("Using deafult storage \n"); } // retrives geometry if (!gGeoManager) { sprintf(str,"%s/ppMinBias%04d/geometry.root",dir,run); AliGeomManager::LoadGeometry(str); } sprintf(str,"%s/ppMinBias%04d/galice.root",dir,run); AliRunLoader* rl = AliRunLoader::Open(str); if (rl == 0x0){ cerr<<"Can not open session RL=NULL"<< endl; return; } Int_t retval = rl->LoadgAlice(); if (retval){ cerr<<"LoadgAlice returned error"<GetAliRun(); retval = rl->LoadHeader(); if (retval){ cerr<<"LoadHeader returned error"<GetLoader("ITSLoader"); if (!ITSloader){ cerr<<"ITS loader not found"<LoadRecPoints("read"); AliITS *ITS = (AliITS*)gAlice->GetModule("ITS"); ITS->SetTreeAddress(); AliITSgeom *geom = ITS->GetITSgeom(); if (!geom) { cout << " Can't get the ITS geometry!" << endl; return ; } AliITSDetTypeRec* detTypeRec = new AliITSDetTypeRec(); detTypeRec->SetITSgeom(ITSloader->GetITSgeom()); detTypeRec->SetDefaults(); Int_t nEvents=rl->GetNumberOfEvents(); printf("Total Number of events = %d\n",nEvents); for (Int_t iev=0;ievGetEvent(iev); TTree *TR = ITSloader->TreeR(); TClonesArray* ITSClusters; ITSClusters = detTypeRec->RecPoints(); TBranch *branch = 0; if (TR && ITSClusters) { branch = ITSloader->TreeR()->GetBranch("ITSRecPoints"); if (branch) branch->SetAddress(&ITSClusters); } // Int_t nparticles = rl->GetHeader()->GetNtrack(); // cout<<"Event # "<GetGlobalXYZ(cluGlo); Float_t rad=TMath::Sqrt(cluGlo[0]*cluGlo[0]+cluGlo[1]*cluGlo[1]); Float_t phi= TMath::Pi() + TMath::ATan2(-cluGlo[1],-cluGlo[0]); hlayer->Fill(lay); hmod[lay]->Fill(mod); hzl[lay]->Fill(recp->GetDetLocalZ()); hxl[lay]->Fill(recp->GetDetLocalX()); hzg[lay]->Fill(cluGlo[2]); hyg[lay]->Fill(cluGlo[1]); hxg[lay]->Fill(cluGlo[0]); hr[lay]->Fill(rad); hphi[lay]->Fill(phi); hPhi_Z[lay]->Fill(cluGlo[2],phi); hr_phi[lay]->Fill(rad,phi); hx_y[lay]->Fill(cluGlo[0],cluGlo[1]); hx_y_z[lay]->Fill(cluGlo[2],cluGlo[0],cluGlo[1]); clustersXCoord[lay][nClusters[lay]]=cluGlo[0]; clustersYCoord[lay][nClusters[lay]]=cluGlo[1]; clustersZCoord[lay][nClusters[lay]]=cluGlo[2]; nClusters[lay]++; hType[lay]->Fill(recp->GetType()); // cout<<"Clusters type"<GetType()<Fill(recp->GetNz(),recp->GetNy()); // Set Sector number and increase the counter if (lay==0) { for (Int_t nRange=0; nRange<10; nRange++) { if ((mod>=nRange*8) && (mod<=(nRange*8+7))) { iSector = nRange; nClustersPerLayerPerSector[lay][iSector]++; break; } } } if (lay==1) { for (Int_t nRange=0; nRange<10; nRange++) { if ((mod>=80+nRange*16) && (mod<=(80+nRange*16+15))) { iSector = nRange; nClustersPerLayerPerSector[lay][iSector]++; break; } } } // Set HalfSector number and increase the counter if (lay==0) { for (Int_t nRange=0; nRange<20; nRange++) { if ((mod>=nRange*4) && (mod<=(nRange*4+3))) { iHalfSector = nRange; nClustersPerLayerPerHalfSector[lay][iHalfSector]++; break; } } } else { for (Int_t nRange=0; nRange<20; nRange++) { if ((mod>=80+nRange*4) && (mod<=(80+nRange*4+3))) { iHalfSector = nRange; nClustersPerLayerPerHalfSector[lay][iHalfSector]++; break; } } } } } } for (Int_t iLay=0; iLay<2; iLay++) hMultSPDcl[iLay]->Fill(nClusters[iLay]); for (Int_t iSec=0; iSec<10; iSec++) { hnCl2_nCl1_Sec[iSec]->Fill(nClustersPerLayerPerSector[0][iSec],nClustersPerLayerPerSector[1][iSec]); hnCl2vsnCl1_Sec[iSec]->Fill(nClustersPerLayerPerSector[0][iSec],nClustersPerLayerPerSector[1][iSec]); } for (Int_t iHSec=0; iHSec<20; iHSec++) { hnCl2_nCl1_HSec[iHSec]->Fill(nClustersPerLayerPerHalfSector[0][iHSec],nClustersPerLayerPerHalfSector[1][iHSec]); } hMultSPDcl2_MultSPDcl1->Fill(nClusters[0],nClusters[1]); } //end loop over events rl->UnloadAll(); delete rl; } //end loop over runs // Draw and Write histos TFile* fout = new TFile("out_ShowSPDRecPoints.root","RECREATE"); hlayer->Write(); // cev0->Write(); TCanvas **c=new TCanvas*[2]; Char_t ctit[30]; for(Int_t iLay=0;iLay<2;iLay++){ hNy_Nz[iLay]->Write(); sprintf(name,"can%d",iLay+1); sprintf(ctit,"Layer %d",iLay+1); c[iLay]=new TCanvas(name,ctit,1200,900); c[iLay]->Divide(3,3); c[iLay]->cd(1); hmod[iLay]->Draw(); hmod[iLay]->Write(); c[iLay]->cd(2); hxl[iLay]->Draw(); hxl[iLay]->Write(); c[iLay]->cd(3); hzl[iLay]->Draw(); hzl[iLay]->Write(); c[iLay]->cd(4); hxg[iLay]->Draw(); hxg[iLay]->Write(); c[iLay]->cd(5); hyg[iLay]->Draw(); hyg[iLay]->Write(); c[iLay]->cd(6); hzg[iLay]->Draw(); hzg[iLay]->Write(); c[iLay]->cd(7); hr[iLay]->Draw(); hr[iLay]->Write(); c[iLay]->cd(8); hphi[iLay]->Draw(); hphi[iLay]->Write(); c[iLay]->cd(9); hPhi_Z[iLay]->Draw("colz"); hPhi_Z[iLay]->Write(); hr_phi[iLay]->Write(); hx_y[iLay]->Write(); hx_y_z[iLay]->Write(); } TCanvas *cCoord=new TCanvas("cCoord","Cluster coordinates",1200,900); cCoord->Divide(2,2); for (Int_t iLay=0;iLay<2;iLay++) { cCoord->cd(1); hx_y[iLay]->SetMarkerStyle(22); hx_y[iLay]->SetMarkerSize(0.3); hx_y[iLay]->SetMarkerColor(iLay+1); if (iLay==0) hx_y[iLay]->Draw("p"); else hx_y[iLay]->Draw("p,same"); cCoord->cd(2); hx_y_z[iLay]->SetMarkerStyle(23); hx_y_z[iLay]->SetMarkerSize(0.3); hx_y_z[iLay]->SetMarkerColor(iLay+1); hx_y_z[iLay]->Draw("p,same"); cCoord->cd(3); hr_phi[iLay]->SetMarkerColor(iLay+1); hr_phi[iLay]->Draw("p,same"); } TCanvas *cCorrelations_Sectors=new TCanvas("cCorrelations_S","SPD cluster correlations (Sectors)",1200,900); cCorrelations_Sectors->Divide(3,5); cCorrelations_Sectors->cd(1); hMultSPDcl2_MultSPDcl1->Draw(); hMultSPDcl2_MultSPDcl1->Write(); cCorrelations_Sectors->cd(2); hMultSPDcl[0]->Draw(); hMultSPDcl[0]->Write(); cCorrelations_Sectors->cd(3); hMultSPDcl[1]->Draw(); hMultSPDcl[1]->Write(); for (Int_t iS=0; iS<10; ++iS) { cCorrelations_Sectors->cd(iS+4); hnCl2_nCl1_Sec[iS]->Draw(); hnCl2_nCl1_Sec[iS]->Write(); hnCl2vsnCl1_Sec[iS]->Write(); } TCanvas *cCorrelations_HSectors=new TCanvas("cCorrelations_HS","SPD cluster correlations (Half-Sectors)",1200,900); cCorrelations_HSectors->Divide(5,4); for (Int_t iHS=0; iHS<20; ++iHS) { cCorrelations_HSectors->cd(iHS+1); hnCl2_nCl1_HSec[iHS]->Write(); hnCl2_nCl1_HSec[iHS]->Draw(); } fout->Close(); }