/************************************************************************** * Copyright(c) 1998-1999, ALICE Experiment at CERN, All rights reserved. * * * * Author: The ALICE Off-line Project. * * Contributors are mentioned in the code where appropriate. * * * * Permission to use, copy, modify and distribute this software and its * * documentation strictly for non-commercial purposes is hereby granted * * without fee, provided that the above copyright notice appears in all * * copies and that both the copyright notice and this permission notice * * appear in the supporting documentation. The authors make no claims * * about the suitability of this software for any purpose. It is * * provided "as is" without express or implied warranty. * **************************************************************************/ /* $Id$ */ // The trigger parametrization is computed for background levels 0., 0.5 and 1. // In order to set a background level different from 0 it is necessary to // explicitly force it with: // ForceBkgLevel(BkgLevel). // For intermediate background levels, the trigger response is linearly // interpolated between these values. // There is increased granularity in the pT region below 3 GeV. Although // it does not seem to be necessary it is also possible to interpolate // between pT bins using SetInt(). // Author: Pietro Cortese (Universita' del Piemonte Orientale - Alessandria // and INFN of Torino) #include "AliFastMuonTriggerEff.h" #include "TROOT.h" #include "TFile.h" #include "stdlib.h" #include "TH3.h" #include "TObjString.h" #define PLIN printf("%s: %d: ",__FILE__,__LINE__) ClassImp(AliFastMuonTriggerEff) AliFastMuonTriggerEff::AliFastMuonTriggerEff(): AliFastResponse("Efficiency", "Muon Trigger Efficiency"), fPtMin(0.), fPtMax(0.), fDpt(0.), fnptb(0), fPhiMin(0.), fPhiMax(0.), fDphi(0.), fnphib(0), fThetaMin(0.), fThetaMax(0.), fDtheta(0.), fnthetab(0), fCut(kLow), fZones(0), fhEffAPt(0), fhEffLPt(0), fhEffHPt(0), fhLX(0), fhLY(0), fhLZ(0), fBkg(0.), fTableTitle(0), fDescription(0), fInt(0), fibx(0), fiby(0), fibz(0) { // // Default constructor // } AliFastMuonTriggerEff::AliFastMuonTriggerEff(const char* Name, const char* Title): AliFastResponse(Name, Title), fPtMin(0.), fPtMax(0.), fDpt(0.), fnptb(0), fPhiMin(0.), fPhiMax(0.), fDphi(0.), fnphib(0), fThetaMin(0.), fThetaMax(0.), fDtheta(0.), fnthetab(0), fCut(kLow), fZones(0), fhEffAPt(0), fhEffLPt(0), fhEffHPt(0), fhLX(0), fhLY(0), fhLZ(0), fBkg(0.), fTableTitle(0), fDescription(0), fInt(0), fibx(0), fiby(0), fibz(0) { // Another constructor } AliFastMuonTriggerEff::AliFastMuonTriggerEff(const AliFastMuonTriggerEff& eff) :AliFastResponse(eff), fPtMin(0.), fPtMax(0.), fDpt(0.), fnptb(0), fPhiMin(0.), fPhiMax(0.), fDphi(0.), fnphib(0), fThetaMin(0.), fThetaMax(0.), fDtheta(0.), fnthetab(0), fCut(kLow), fZones(0), fhEffAPt(0), fhEffLPt(0), fhEffHPt(0), fhLX(0), fhLY(0), fhLZ(0), fBkg(0.), fTableTitle(0), fDescription(0), fInt(0), fibx(0), fiby(0), fibz(0) { // Copy constructor eff.Copy(*this); } void AliFastMuonTriggerEff::SetCut(Int_t cut) { // // Set the pt cut if(cut==kLow){ printf("Selecting Low Pt cut\n"); }else if(cut==kHigh){ printf("Selecting High Pt cut\n"); }else if(cut==kAny){ printf("Selecting Lowest Pt cut\n"); }else{ printf("Don't know cut %d! Selecting Low Pt cut\n",cut); cut=kLow; } fCut = cut; } Int_t AliFastMuonTriggerEff::SetBkgLevel(Float_t Bkg) { // // Set the background level // if((Bkg!=0.)) { printf("%s: Warning: requested Bkg: %f\n", __FILE__,Bkg); fBkg=0.; printf("A consistent treatement of the trigger probability\n"); printf("within the framework of the fast simulation requires\n"); printf("requires background 0\n"); printf("%s: fBkg: set to %f\n", __FILE__,fBkg); } else { fBkg=Bkg; } if(fZones!=0.) { Init(); } return 0; } Int_t AliFastMuonTriggerEff::ForceBkgLevel(Float_t Bkg) { // // Check and enforce consistency of the background level // if((Bkg!=0.)) { printf("%s: Warning: requested Bkg: %f\n", __FILE__,Bkg); printf("A consistent treatement of the trigger probability\n"); printf("within the framework of the fast simulation\n"); printf("requires background 0"); printf("%s: Continue with fBkg: %f\n", __FILE__,Bkg); } fBkg=Bkg; if(fZones!=0.) { Init(); } return 0; } Int_t AliFastMuonTriggerEff::LoadTables(Char_t *namet=""){ // // Load the trigger tables // Char_t hNameA[100],hNameL[100],hNameH[100]; sprintf(hNameA,"hEffAPt%s",namet); sprintf(hNameL,"hEffLPt%s",namet); sprintf(hNameH,"hEffHPt%s",namet); fhEffAPt = (TH3F*)gDirectory->Get(hNameA); fhEffLPt = (TH3F*)gDirectory->Get(hNameL); fhEffHPt = (TH3F*)gDirectory->Get(hNameH); if(!fhEffAPt){ PLIN; printf("%s: histogram %s not found\n",__FILE__,hNameA); return -1; } if(!fhEffLPt){ PLIN; printf("%s: histogram %s not found\n",__FILE__,hNameL); return -2; } if(!fhEffHPt){ PLIN; printf("%s: histogram %s not found\n",__FILE__,hNameH); return -3; } return 0; } void AliFastMuonTriggerEff::Init() { // // Initialization // fZones=0; Char_t file[100]="$(ALICE_ROOT)/FASTSIM/data/MUONtriggerLUT_V2.4nvdn.root"; printf("Initializing %s / %s\n", fName.Data(), fTitle.Data()); printf("using data from file: %s\n",file); printf("AliFastMuonTriggerEff: Initialization with background level: %f\n",fBkg); TFile *f = new TFile(file); if(f->IsZombie()) { PLIN; printf("Cannot open file: %s\n",file); return; } f->ls(); Int_t intb=0; Char_t namet[10]; if(TMath::Abs(fBkg)<0.00001){ sprintf(namet,"00"); }else if(TMath::Abs(fBkg-0.5)<0.00001){ sprintf(namet,"05"); }else if(TMath::Abs(fBkg-1.0)<0.00001){ sprintf(namet,"10"); }else{ PLIN; printf("A table for Bkg level: %f does not exists\n",fBkg); intb=1; } if(intb){ // Interpolation between background levels PLIN; printf("Interpolating Bkg level: %f\n",fBkg); TH3F* ha1,*hl1,*hh1,*ha2,*hl2,*hh2,*ha0,*hl0,*hh0; Char_t name1[10],name2[10]; Float_t b1,b2; if(fBkg>0&&fBkg<0.5){ sprintf(name1,"00"); sprintf(name2,"05"); b1=0.; b2=0.5; }else if(fBkg>0.5){ sprintf(name1,"05"); sprintf(name2,"10"); b1=0.5; b2=1.0; if(fBkg>1.0){ for(Int_t i=0; i<10;i++){ PLIN; printf("WARNING!!!! You are extrapolating above background 1.0\n"); } } }else{ PLIN; printf("Bkg level: %f is not supported\n",fBkg); return; } if(LoadTables(name1)){ PLIN; printf("Error in loading trigger tables\n"); return; } PLIN; printf("We use tables for %f and %f to interpolate %f Bkg level\n",b1,b2,fBkg); ha0=(TH3F*)fhEffAPt->Clone("hEffAPtXX"); ha0->Reset(); hl0=(TH3F*)fhEffLPt->Clone("hEffLPtXX"); hl0->Reset(); hh0=(TH3F*)fhEffHPt->Clone("hEffHPtXX"); hh0->Reset(); ha1=fhEffAPt; hl1=fhEffLPt; hh1=fhEffHPt; if(LoadTables(name2)){ PLIN; printf("Error in loading trigger tables\n"); return; } ha2=fhEffAPt; hl2=fhEffLPt; hh2=fhEffHPt; fhEffAPt=ha0; fhEffLPt=hl0; fhEffHPt=hh0; Int_t nnx=ha0->GetNbinsX()+1; Int_t nny=ha0->GetNbinsY()+1; Int_t nnz=ha0->GetNbinsZ()+1; for(Int_t ix=0; ix<=nnx; ix++){ for(Int_t iy=0; iy<=nny; iy++){ for(Int_t iz=0; iz<=nnz; iz++){ Double_t y1,y2; Float_t cont; y1=ha1->GetBinContent(ix,iy,iz); y2=ha2->GetBinContent(ix,iy,iz); cont=Float_t(y1+(y2-y1)/(b2-b1)*(fBkg-b1)); if(cont>1)cont=1; if(cont<0)cont=0; fhEffAPt->SetBinContent(ix,iy,iz,cont); y1=hl1->GetBinContent(ix,iy,iz); y2=hl2->GetBinContent(ix,iy,iz); cont=Float_t(y1+(y2-y1)/(b2-b1)*(fBkg-b1)); if(cont>1)cont=1; if(cont<0)cont=0; fhEffLPt->SetBinContent(ix,iy,iz,cont); y1=hh1->GetBinContent(ix,iy,iz); y2=hh2->GetBinContent(ix,iy,iz); cont=Float_t(y1+(y2-y1)/(b2-b1)*(fBkg-b1)); if(cont>1)cont=1; if(cont<0)cont=0; fhEffHPt->SetBinContent(ix,iy,iz,cont); } } } }else{ // Use tables computed for selected backgound levels printf("Loading tables for background level: %f\n",fBkg); if(LoadTables(namet)){ PLIN; printf("Error in loading trigger tables\n"); return; } } fhEffAPt->SetDirectory(0); fhEffLPt->SetDirectory(0); fhEffHPt->SetDirectory(0); fhLX=fhEffLPt->GetXaxis(); fhLY=fhEffLPt->GetYaxis(); fhLZ=fhEffLPt->GetZaxis(); // // if(f->Get("Description")) { fDescription=((TObjString*)f->Get("Description"))->GetString(); printf("%s\n",fDescription.Data()); } fThetaMin = fhEffLPt->GetXaxis()->GetXmin(); fThetaMax = fhEffLPt->GetXaxis()->GetXmax(); fnthetab=fhEffLPt->GetNbinsX(); fDtheta = (fThetaMax-fThetaMin)/fnthetab; fPhiMin = fhEffLPt->GetYaxis()->GetXmin(); fPhiMax = fhEffLPt->GetYaxis()->GetXmax(); fnphib=fhEffLPt->GetNbinsY(); fDphi = (fPhiMax-fPhiMin)/fnphib; fPtMin=fhEffLPt->GetZaxis()->GetXmin(); fPtMax=fhEffLPt->GetZaxis()->GetXmax(); fnptb=fhEffLPt->GetNbinsZ(); fDpt = (fPtMax-fPtMin)/fnptb; printf("***** This version of AliFastMuonTriggerEff can use both *****\n"); printf("***** new and old ALICE reference frames depending on *****\n"); printf("***** which LUT has been loaded. You can find below some *****\n"); printf("***** information on the current parametrization: *****\n"); printf("%4d bins in theta [%f:%f]\n",fnthetab,fThetaMin,fThetaMax); printf("%4d bins in phi [%f:%f]\n",fnphib,fPhiMin,fPhiMax); printf("%4d bins in pt [%f:%f]\n",fnptb,fPtMin,fPtMax); fZones=fnthetab*fnphib; f->Close(); if(fInt==0) { printf("Interpolation of trigger efficiencies is off!\n"); } else { printf("Interpolation of trigger efficiencies is on!\n"); } } void AliFastMuonTriggerEff::Evaluate(Float_t charge, Float_t pt,Float_t theta, Float_t phi, Float_t& effLow, Float_t& effHigh, Float_t& effAny) { // // Trigger efficiency for pt, theta, phi (low, high and "any" cut) // #ifdef MYTRIGDEBUG printf("Evaluate(ch=%2.0f, pt=%10.6f, theta=%7.2f, phi=%8.2f ...)\n",charge,pt,theta,phi); #endif effLow=0.; effHigh=0.; effAny=0; if(fZones==0) { printf("Call to uninitialized object of class: AliFastMuonTriggerEff\n"); return; } if(pt<0) { printf("Warning: pt: %f < 0. GeV/c\n",pt); return; } Int_t iPt = fhLZ->FindBin((Double_t)pt); if(iPt>fnptb)iPt=fnptb; Int_t iPhi = Int_t((phi-fPhiMin)/fDphi); if(phiFindBin((Double_t)theta); #ifdef MYTRIGDEBUG printf("Evaluate(ch=%2.0f, pt=%10.6f, theta=%7.2f, phi=%8.2f ...)\n",charge,pt,theta,phi); printf(" 0:%1d iPt iTheta iPhi: %d %d %d\n",fInt,iPt,iTheta,iPhi); #endif iPhi=iPhi-2*fnphib*(iPhi/(2*fnphib)); #ifdef MYTRIGDEBUG printf(" 1:%1d iPhi converted to: %d for angle equivalence\n",fInt,iPhi); #endif if(iPhi<0)iPhi=-iPhi-1; if(iPhi>(fnphib-1))iPhi=2*fnphib-1-iPhi; #ifdef MYTRIGDEBUG printf(" 2:%1d iPhi converted to: %d for the symmetry of the spectrometer\n",fInt,iPhi); #endif if(charge==1.){ } else if(charge==-1.) { iPhi=fnphib-1-iPhi; #ifdef MYTRIGDEBUG printf(" 3:%1d iPhi converted to: %d for the charge symmetry\n",fInt,iPhi); #endif } else { printf("Warning: not understand charge: %f\n",charge); return; } if(iTheta<=0||iTheta>fnthetab) { printf("Warning: theta: %f outside acceptance\n",theta); return; } if(iPt<0) { printf("Warning: what do you mean with pt: %f <0?\n",pt); return; } iPhi++; #ifdef MYTRIGDEBUG printf(" 4:%1d Getting: iTheta, iPhi, iPt: %d %d %d\n", fInt,iTheta,iPhi,iPt); #endif effLow =fhEffLPt->GetBinContent(iTheta,iPhi,iPt); effHigh=fhEffHPt->GetBinContent(iTheta,iPhi,iPt); effAny =fhEffAPt->GetBinContent(iTheta,iPhi,iPt); #ifdef MYTRIGDEBUG printf(" 4:%1d Result: charge, iTheta, iPhi, iPt: %f %d %d %d effLow: %f, effHigh: %f, effAny: %f\n", fInt,charge,iTheta,iPhi,iPt,effLow,effHigh,effAny); #endif if(fInt==1) { Float_t angl,angh,anga; Float_t effLowp,effHighp,effAnyp; Float_t ptc=(iPt+0.5)*fDpt; // The center of current bin #ifdef MYTRIGDEBUG printf(" 5:1 The center of current bin iPt: %d is: %f\n",iPt,ptc); #endif if(iPt==fnptb) { #ifdef MYTRIGDEBUG printf(" 6:1 No more points above! No interpolation is needed!\n"); #endif return; }else if(ptc==pt){ #ifdef MYTRIGDEBUG printf(" 6:1 No interpolation is needed!\n"); #endif return; }else if(ptc>pt){ // Looking for previous point if(iPt>1) { effLowp =fhEffLPt->GetBinContent(iTheta,iPhi,iPt-1); effHighp=fhEffHPt->GetBinContent(iTheta,iPhi,iPt-1); effAnyp =fhEffAPt->GetBinContent(iTheta,iPhi,iPt-1); #ifdef MYTRIGDEBUG printf(" 7:1 A simple look to previous point: %d: %f %f\n",iPt-1,effLowp,effHighp); #endif } else { effLowp=0.; effHighp=0.; effAnyp=0; #ifdef MYTRIGDEBUG printf(" 8:1 result is: %f %f %f\n",effLowp,effHighp,effAnyp); #endif } angl=(effLow-effLowp)/fDpt; angh=(effHigh-effHighp)/fDpt; anga=(effAny-effAnyp)/fDpt; }else{ // Looking for next point if(iPtGetBinContent(iTheta,iPhi,iPt+1); effHighp=fhEffHPt->GetBinContent(iTheta,iPhi,iPt+1); effAnyp =fhEffAPt->GetBinContent(iTheta,iPhi,iPt+1); #ifdef MYTRIGDEBUG printf(" 7:1 A simple look to next point: %d: %f %f %f\n",iPt-1,effLowp,effHighp,effAnyp); #endif } else { effLowp=effLow; effHighp=effHigh; effAnyp=effAny; #ifdef MYTRIGDEBUG printf(" 8:1 result is: pt: %f %f %f\n",effLowp,effHighp,effAnyp); #endif } angl=(effLowp-effLow)/fDpt; angh=(effHighp-effHigh)/fDpt; anga=(effAnyp-effAny)/fDpt; } effLow=effLow+angl*(pt-ptc); effHigh=effHigh+angh*(pt-ptc); effAny=effAny+anga*(pt-ptc); #ifdef MYTRIGDEBUG printf(" 9:1 the interpolation coefficients are: %f %f %f\n",angl,angh,anga); #endif } #ifdef MYTRIGDEBUG printf("10:%1d effLow, effHigh=%f %f %f\n",fInt,effLow,effHigh,effAny); #endif return; } Float_t AliFastMuonTriggerEff::Evaluate(Float_t charge, Float_t pt, Float_t theta, Float_t phi) { // // Trigger efficiency for pt, theta, phi depending of fCut // if(fZones==0) { printf("Call to uninitialized object of class: AliFastMuonTriggerEff\n"); return 0.; } Float_t eff; Float_t effLow, effHigh, effAny; Evaluate(charge,pt,theta,phi,effLow,effHigh,effAny); if (fCut == kLow) eff = effLow; else if (fCut == kHigh) eff = effHigh; else if (fCut == kAny) eff = effAny; else eff = 0; return eff; } AliFastMuonTriggerEff& AliFastMuonTriggerEff::operator=(const AliFastMuonTriggerEff& rhs) { // Assignment operator rhs.Copy(*this); return *this; }