#ifndef SimPlotter_h #define SimPlotter_h #include #include #include #include #include #include #include #include #include #include "../Armory/ClassDetGeo.h" #include "../Armory/ClassReactionConfig.h" #include "../Cleopatra/ClassIsotope.h" enum plotID { pEZ, /// 0 pRecoilXY, /// 1 pRecoilXY1, /// 2 pRecoilXY2, /// 3 pRecoilRZ, /// 4 pRecoilRTR, /// 5 pTDiffZ, /// 6 pThetaCM, /// 7 pThetaCM_Z, /// 8 pExCal, /// 9 pRecoilRThetaCM, /// 10 pArrayXY, /// 11 pInfo, /// 12 pElum1XY, /// 13 pEElum1R, /// 14 pElum1RThetaCM, /// 15 pEmpty }; /// 16 class Plotter{ public: Plotter(TTree * tree, short reactionID, std::string reactionName, DetGeo detGeo, ExcitedEnergies exList, TString gate, std::vector padPlotID); ~Plotter(); void SetRanges(double zMin, double zMax, double eMax, double elumMax, double thetaCM_Max){ this->zRange[0] = zMin; this->zRange[1] = zMax; this->eMax = eMax; this->elumMax = elumMax; this->thetaCM_Max = thetaCM_Max; } void SetCanvas( int colSize, int rowSize , int padSize, std::vector padPlotID ){ cCheck = new TCanvas(Form("SimChecker-%d", rID), "Simulation Checker", 200 * rID, 200 * rID, padSize*colSize, padSize*rowSize); if(cCheck->GetShowEditor() ) cCheck->ToggleEditor(); if(cCheck->GetShowToolBar() )cCheck->ToggleToolBar(); cCheck->Divide(colSize,rowSize); numPad = colSize * rowSize; } void Plot(); private: TTree * tree; DetGeo detGeo; std::string reactionName; short rID; ExcitedEnergies exList; int numEx; TString gate; TString gateTrue; std::vector padPlotID; double zRange[2]; double eMax; double recoilOut; double recoilIn; double elumMax; double thetaCM_Max; int numPad; TCanvas * cCheck; TH2F * hez; TH2F * hArrayXY; TH2F * heavyXY; TH2F * hElum1XY; TH1F ** hThetaCM; TH1F * hExCal; TH1F * hHit; TH2F * hRecoilXY1; TH2F * hRecoilXY2; TH2F * hTDiffZ; TH2F * hRecoilRThetaCM; TH2F * hRecoilRZ; TH2F * hEElum1Rho; TH2F * hRecoilRTR; TH2F * hElum1RThetaCM; TH2F * hThetaCM_Z; Isotope heavy; std::vector FindRange(TString branch); }; Plotter::Plotter(TTree * tree, short reactionID, std::string reactionName, DetGeo detGeo, ExcitedEnergies exList, TString gate, std::vector padPlotID){ this->tree = tree; this->rID = reactionID; this->reactionName = reactionName; this->exList = exList; numEx = this->exList.ExList.size(); this->detGeo = detGeo; this->recoilOut = detGeo.aux[rID].outerRadius; this->recoilIn = detGeo.aux[rID].innerRadius; this->gate = gate; this->gateTrue = gate + Form(" && rID == %d", rID); this->padPlotID = padPlotID; cCheck = nullptr; hez = nullptr; hArrayXY = nullptr; heavyXY = nullptr; hElum1XY = nullptr; hThetaCM = nullptr; hExCal = nullptr; hHit = nullptr; hRecoilXY1 = nullptr; hRecoilXY2 = nullptr; hTDiffZ = nullptr; hRecoilRThetaCM = nullptr; hRecoilRZ = nullptr; hEElum1Rho = nullptr; hRecoilRTR = nullptr; hElum1RThetaCM = nullptr; hThetaCM_Z = nullptr; std::size_t pos1 = reactionName.find(")") + 1; std::size_t pos2 = reactionName.find(" ", pos1); std::string result = reactionName.substr(pos1, pos2 - pos1); pos1 = result.find("{") + 1; pos2 = result.find("}", pos1); std::string massHeavy = result.substr(pos1, pos2-pos1); std::string symHeavy = result.substr(pos2+1); heavy.SetIsoByName(massHeavy + symHeavy); } Plotter::~Plotter(){ if( cCheck ) delete cCheck; if( hez ) delete hez; if( hArrayXY ) delete hArrayXY; if( heavyXY ) delete heavyXY; if( hElum1XY ) delete hElum1XY; if( hExCal ) delete hExCal; if( hRecoilXY1 ) delete hRecoilXY1; if( hRecoilXY2 ) delete hRecoilXY2; if( hTDiffZ ) delete hTDiffZ; if( hRecoilRThetaCM ) delete hRecoilRThetaCM; if( hRecoilRZ ) delete hRecoilRZ; if( hEElum1Rho ) delete hEElum1Rho; if( hRecoilRTR ) delete hRecoilRTR; if( hElum1RThetaCM ) delete hElum1RThetaCM; if( hThetaCM_Z ) delete hThetaCM_Z; if(hThetaCM ){ for( int i = 0; i < numEx; i++) delete [] hThetaCM[i]; delete [] hThetaCM; } } inline void Plotter::Plot(){ for( int i = 1; i <= numPad; i++ ){ cCheck->cd(i); plotID pID = padPlotID[i-1]; //&======================================= 0 if( pID == pEZ){ hez = new TH2F(Form("hez%d",rID), //need unqie name in root. Form("e-z [gated] @ %5.0f mm; z [mm]; e [MeV]", detGeo.array[rID].firstPos), 400, zRange[0], zRange[1], 400, 0, eMax); tree->Draw(Form("e:z>>hez%d", rID), gateTrue , "colz"); } //&======================================= 1 if( pID == pRecoilXY ){ heavyXY = new TH2F(Form("heavyXY%d",rID), Form("RecoilXY [gated] @ %4.0f mm; X [mm]; Y [mm]", detGeo.aux[rID].detPos ), 400, -recoilOut, recoilOut, 400, -recoilOut, recoilOut); tree->Draw(Form("yRecoil:xRecoil>>heavyXY%d", rID), gateTrue, "colz"); // printf("%f, %f\n", recoilOut, recoilIn); TArc * detArc1 = new TArc(0, 0, recoilOut); detArc1->SetLineColor(kBlue-8); detArc1->SetFillStyle(0); detArc1->Draw("same"); TArc * detArc2 = new TArc(0, 0, recoilIn); detArc2->SetLineColor(kBlue-8); detArc2->SetFillStyle(0); detArc2->Draw("same"); // if( reactionConfig.beamX != 0. || reactionConfig.beamY != 0. ){ // TArc * arc = new TArc(reactionConfig.beamX, reactionConfig.beamY, 1); // arc->SetLineColor(2); // detArc1->SetFillStyle(0); // arc->Draw("same"); // } } //&======================================= 2 if( pID == pThetaCM ){ hThetaCM = new TH1F *[numEx]; TLegend * legend = new TLegend(0.8,0.2,0.99,0.8); double maxCount = 0; for( int h = 0; h < numEx; h++){ hThetaCM[h] = new TH1F(Form("hThetaCM%d-%d", rID, h), Form("thetaCM [gated] (ExID=%d); thetaCM [deg]; count", h), 200, 0, thetaCM_Max); hThetaCM[h]->SetLineColor(h+1); hThetaCM[h]->SetFillColor(h+1); hThetaCM[h]->SetFillStyle(3000+h); tree->Draw(Form("thetaCM>>hThetaCM%d-%d", rID, h), gateTrue + Form("&& ExID==%d", h), ""); legend->AddEntry(hThetaCM[h], Form("Ex=%5.1f MeV", exList.ExList[h].Ex)); double max = hThetaCM[h]->GetMaximum(); if( max > maxCount ) maxCount = max; } for( int h = 0; h < numEx; h++){ hThetaCM[h]->GetYaxis()->SetRangeUser(1, maxCount * 1.2); if( h == 0 ) { hThetaCM[h]->Draw(); }else{ hThetaCM[h]->Draw("same"); } } legend->Draw(); } //&======================================= 3 if( pID == pExCal ){ double exMin = 9999; double exMax = -1; for( size_t k = 0 ; k < exList.ExList.size(); k++){ double kuku = exList.ExList[k].Ex; if( kuku > exMax ) exMax = kuku; if( kuku < exMin ) exMin = kuku; } double exPadding = (exMax - exMin) < 1 ? 1 : (exMax - exMin) * 0.3; exMin = exMin - exPadding ; exMax = exMax + exPadding ; hExCal = new TH1F(Form("hExCal%d",rID), Form("calculated Ex [gated]; Ex [MeV]; count / %.2f keV", (exMax-exMin)/400.*1000), 400, exMin, exMax); tree->Draw(Form("ExCal>>hExCal%d", rID), gateTrue, ""); double Sn = heavy.CalSp(0,1); double Sp = heavy.CalSp(1,0); double Sa = heavy.CalSp2(4,2); double S2n = heavy.CalSp(0, 2); printf("======= Heavy recoil: %s \n", heavy.Name.c_str()); printf("Sn : %6.2f MeV/u \n", Sn); printf("Sp : %6.2f MeV/u \n", Sp); printf("Sa : %6.2f MeV/u \n", Sa); printf("S2n : %6.2f MeV/u \n", S2n); double yMax = hExCal->GetMaximum(); TLatex * text = new TLatex(); text->SetTextFont(82); text->SetTextSize(0.06); if( Sn < exMax ) {TLine * lineSn = new TLine(Sn, 0, Sn, yMax); lineSn->SetLineColor(2); lineSn->Draw(""); text->SetTextColor(2); text->DrawLatex(Sn, yMax*0.9, "S_{n}");} if( Sp < exMax ) {TLine * lineSp = new TLine(Sp, 0, Sp, yMax); lineSp->SetLineColor(4); lineSp->Draw("same"); text->SetTextColor(4); text->DrawLatex(Sp, yMax*0.9, "S_{p}");} if( Sa < exMax ) {TLine * lineSa = new TLine(Sa, 0, Sa, yMax); lineSa->SetLineColor(6); lineSa->Draw("same"); text->SetTextColor(6); text->DrawLatex(Sa, yMax*0.9, "S_{a}");} if( S2n < exMax ) {TLine * lineS2n = new TLine(S2n, 0, S2n, yMax); lineS2n->SetLineColor(8); lineS2n->Draw("same"); text->SetTextColor(8); text->DrawLatex(S2n, yMax*0.9, "S_{2n}");} } //&======================================= 4 if( pID == pArrayXY ){ hArrayXY = new TH2F(Form("hArrayXY%d", rID), "Array-XY [gated]; X [mm]; Y [mm]", 400, -detGeo.array[rID].detPerpDist*1.5, detGeo.array[rID].detPerpDist*1.5, 400, -detGeo.array[rID].detPerpDist*1.5, detGeo.array[rID].detPerpDist*1.5); tree->Draw(Form("yArray:xArray>>hArrayXY%d", rID), gateTrue, "colz"); } //&======================================= 5 if( pID == pInfo ){ TLatex text; text.SetNDC(); text.SetTextFont(82); text.SetTextSize(0.06); text.SetTextColor(2); text.DrawLatex(0., 0.9, reactionName.c_str()); text.DrawLatex(0., 0.8, detGeo.Bfield > 0 ? "out of plan" : "into plan"); text.SetTextColor(1); text.DrawLatex(0., 0.7, "gate:"); text.SetTextColor(2); //check gate text length, if > 30, break by "&&" int ll = gate.Length(); if( ll > 30 ) { std::vector strList = AnalysisLib::SplitStr( (std::string) gate.Data(), "&&"); for( int i = 0; i < strList.size(); i++){ text.DrawLatex(0., 0.6 - 0.05*i, (TString) strList[i]); } }else{ text.DrawLatex(0., 0.6, gate); } // if( reactionConfig.beamX != 0.0 || reactionConfig.beamY != 0.0 ){ // text.DrawLatex(0.0, 0.1, Form("Bema pos: (%4.1f, %4.1f) mm", reactionConfig.beamX, reactionConfig.beamY)); // } } //&======================================= 6 if( pID == pElum1XY ){ hElum1XY = new TH2F(Form("hElum1XY%d", rID), Form("Elum-1 XY [gated] @ %.0f mm ; X [mm]; Y [mm]", detGeo.aux[rID].elumPos1), 400, -elumMax, elumMax, 400, -elumMax, elumMax); tree->Draw(Form("yElum1:xElum1>>hElum1XY%d", rID), gateTrue, "colz"); double count = hElum1XY->GetEntries(); if( count < 2000. ) { hElum1XY->SetMarkerStyle(7); if( count < 500. ) hElum1XY->SetMarkerStyle(3); hElum1XY->Draw("scat"); } } //&======================================= 7 if( pID == pRecoilXY1 ){ TH2F * hRecoilXY1 = new TH2F(Form("hRecoilXY1-%d", rID), Form("RecoilXY-1 [gated] @ %4.0f mm; X [mm]; Y [mm]", detGeo.aux[rID].detPos1 ), 400, -detGeo.aux[rID].outerRadius, detGeo.aux[rID].outerRadius, 400, -detGeo.aux[rID].outerRadius, detGeo.aux[rID].outerRadius); tree->Draw(Form("yRecoil1:xRecoil1>>hRecoilXY1-%d", rID), gateTrue, "colz"); } //&======================================= 8 if( pID == pRecoilXY2 ){ hRecoilXY2 = new TH2F(Form("hRecoilXY2=%d", rID), Form("RecoilXY-2 [gated] @ %4.0f mm; X [mm]; Y [mm]", detGeo.aux[rID].detPos2 ), 400, -detGeo.aux[rID].outerRadius, detGeo.aux[rID].outerRadius, 400, -detGeo.aux[rID].outerRadius, detGeo.aux[rID].outerRadius); tree->Draw(Form("yRecoil2:xRecoil2>>hRecoilXY2-%d", rID), gate, "colz"); } //&======================================= 9 if( pID == pTDiffZ ){ std::vector tDiffRange = FindRange("t-tB"); hTDiffZ = new TH2F(Form("hTDiffZ%d", rID), "time(Array) - time(Recoil) vs Z [gated]; z [mm]; time diff [ns]", 400, zRange[0], zRange[1], 400, tDiffRange[0], tDiffRange[1]); tree->Draw(Form("t - tB : z >> hTDiffZ%d", rID), gateTrue, "colz"); } //&======================================= 10 if( pID == pRecoilRThetaCM ){ hRecoilRThetaCM = new TH2F(Form("hRecoilRThetaCM%d", rID), "RecoilR - thetaCM [gated]; thetaCM [deg]; RecoilR [mm]", 400, 0, 60, 400, 0, detGeo.aux[rID].outerRadius); tree->Draw(Form("rhoRecoil:thetaCM>>hRecoilRThetaCM%d", rID), gateTrue, "colz"); } //&======================================= 11 if( pID == pRecoilRZ ){ hRecoilRZ = new TH2F(Form("hRecoilRZ%d", rID), "RecoilR - Z [gated]; z [mm]; RecoilR [mm]", 400, zRange[0], zRange[1], 400,0, detGeo.aux[rID].outerRadius); tree->Draw(Form("rhoRecoil:z>>hRecoilRZ%d", rID), gateTrue, "colz"); } //&======================================= 12 if( pID == pEElum1R ){ hEElum1Rho = new TH2F(Form("hEElum1Rho%d", rID), "Elum-1 E-R [gated]; R[mm]; Energy[MeV]", 400, 0, elumMax, 400, 0, eMax); tree->Draw(Form("Tb:rhoElum1>>hEElum1Rho%d", rID), gateTrue, "colz"); } //&======================================= 13 if( pID == pRecoilRTR ){ std::vector recoilERange = FindRange("TB"); hRecoilRTR = new TH2F(Form("hRecoilRTR%d", rID), "RecoilR - recoilE [gated]; recoil Energy [MeV]; RecoilR [mm]", 500, recoilERange[0], recoilERange[1], 500, 0, detGeo.aux[rID].outerRadius); tree->Draw(Form("rhoRecoil:TB>>hRecoilRTR%d", rID), gateTrue, "colz"); } //&======================================= 14 if( pID == pThetaCM_Z ){ hThetaCM_Z = new TH2F(Form("hThetaCM_Z%d", rID), "ThetaCM vs Z ; Z [mm]; thetaCM [deg]", 400, zRange[0], zRange[1], 400, 0, thetaCM_Max); tree->Draw(Form("thetaCM:z>>hThetaCM_Z%d", rID), gateTrue,"col"); } //&======================================= 15 if( pID == pElum1RThetaCM){ int angBin = 400; hElum1RThetaCM = new TH2F(Form("hElum1RThetaCM%d", rID), "Elum-1 rho vs ThetaCM [gated]; thatCM [deg]; Elum- rho [mm]", angBin, 0, thetaCM_Max, 400, 0, elumMax); tree->Draw(Form("rhoElum1:thetaCM>>hElum1RThetaCM%d", rID), gateTrue, "colz"); TH1F * htemp = (TH1F *) hElum1RThetaCM->ProjectionX("htemp"); double rel = (thetaCM_Max)*1.0/angBin; printf("angular resolution : %f deg \n", rel); std::vector xList; double old_y = 0; for( int i = 1; i <= angBin; i++){ double y = htemp->GetBinContent(i); if( old_y == 0 && y > 0) xList.push_back(htemp->GetBinCenter(i)); if( old_y > 0 && y == 0 ) xList.push_back(htemp->GetBinCenter(i)); old_y = y; } printf("list of gaps :\n"); for( int i = 0; i < (int) xList.size(); i+=2){ printf("%d | %.3f - %.3f deg\n", i, xList[i], xList[i+1]); } TF1 f1("f1", "sin(x)"); double acceptance = 0; double err1 = 0; double err2 = 0; for( int i = 0; i < (int) xList.size(); i += 2 ){ acceptance += f1.Integral(xList[i] * TMath::DegToRad(), xList[i+1] * TMath::DegToRad() ) * TMath::TwoPi(); err1 += f1.Integral((xList[i]-rel) * TMath::DegToRad(), (xList[i+1] + rel) * TMath::DegToRad() ) * TMath::TwoPi(); err2 += f1.Integral((xList[i]+rel) * TMath::DegToRad(), (xList[i+1] - rel) * TMath::DegToRad() ) * TMath::TwoPi(); } printf("acceptance = %f sr +- %f \n", acceptance, (err1-err2)/2); TLatex text; text.SetTextFont(82); text.SetTextSize(0.06); text.SetTextColor(2); text.SetTextAngle(90); for( int i = 0; i < (int) xList.size(); i++){ text.DrawLatex(xList[i], elumMax/2, Form("%.2f", xList[i])); } text.SetNDC(); text.SetTextAngle(0); text.DrawLatex(0.15, 0.15, Form("accp. = %.2f(%.2f) msr", acceptance * 1000., (err1-err2)*1000./2)); delete htemp; } }///===== end of pad loop } std::vector Plotter::FindRange(TString branch){ tree->Draw(Form("%s>>temp1", branch.Data()), gateTrue); TH1F * temp1 = (TH1F *) gROOT->FindObjectAny("temp1"); std::vector output; output.push_back( temp1->GetXaxis()->GetXmax() ); output.push_back( temp1->GetXaxis()->GetXmin() ); delete temp1; return output; } #endif