Plotting/Modules/Setup.C

#include <iostream>
#include <fstream>
#include <TCut.h>
#include <TColor.h>
#include <TStyle.h>

#ifndef SampleClassLoaded
#include "SampleClass.C"
#endif
#define SetupLoaded
#ifndef ResultLibraryClassLoaded
#include "ResultLibraryClass.C"
#endif


using namespace std;


namespace PlottingSetup {

  string directoryname="Jellyfish_tests";
  
  bool RestrictToMassPeak=true; //if you want to switch between offpeak ("false") and onpeak ("true") analysis please use this switch; the masscut below will be adapted automatically when adding samples :-)
  bool FullMCAnalysis=false;
  bool DoBTag=false;
  
  // the 2012 switch is in GeneralToolBox
    
  float luminosity=4980;//4653.74;//p3523.18;//2096.0;//3172.73;//2096.0;//1936;//751.0;//486.0;//468.0//336.;//pb^{-1}
//  float luminosity=3523.18;//2096.0;//3172.73;//2096.0;//1936;//751.0;//486.0;//468.0//336.;//pb^{-1}
//  float luminosity=2096.0;//3172.73;//2096.0;//1936;//751.0;//486.0;//468.0//336.;//pb^{-1}
  float lumiuncert=0.022;//0.045;// to be indicated in [0,1] range, e.g. for 4% write 0.04
  
  float luminosity2012=705;
  float lumiuncert2012=0.022;

//  string jzbvariabledata="jzb[1]+0.06*pt";
//  string jzbvariablemc="jzb[1]+0.04*pt";
  string jzbvariabledata="(jzb[1]+0.06*pt)";
  string jzbvariablemc="(jzb[1]+0.04*pt)";
  float jzbHigh = 400.; // Range for JZB plots

  samplecollection allsamples("completesamplecollection");
  samplecollection qcdsamples("QCDcollection");
  samplecollection signalsamples("signalsamplecollection");
  samplecollection systsamples("systematicssamplecollection");
  samplecollection scansample("scansamplecollection");
  samplecollection raresample("raresamplecollection");
  int data=1;
  int mc=0;
  int mcwithsignal=2;
  TCut leptoncut("(pt1>20&&pt2>20)");
  TCut passtrig("(passed_triggers||!is_data)"&&leptoncut);
  
  TCut openmasscut("mll>20"); // this is the mass cut used in the off peak analysis!
  TCut openGenmasscut("genMll>20");
  TCut opensidebandcut("mll>500&&mll<100"); // this won't let anything thru ...
  
  TCut Restrmasscut("abs(mll-91.2)<20"); // this is the mass cut used in the off peak analysis!
  TCut RestrGenmasscut("abs(genMll-91.2)<20");
  TCut Restrsidebandcut("((mll>55&&mll<70)||(mll>112&&mll<160))");
  
  TCut cutmass(Restrmasscut);
  TCut genMassCut(RestrGenmasscut);
  
  TCut bTagRequirement("pfJetGoodNumBtag>0");
  
  //TCut cutmass("mll>2");
//  TCut basiccut("mll>2"&&leptoncut&&"(bTagProbTHighEff[0]>1.7)&&(bTagProbTHighEff[1]>1.7)");//basically nothing.
  TCut basiccut("mll>2"&&leptoncut);//basically nothing
  TCut basicqualitycut("(pfJetGoodNum>=2&&pfJetGoodID[0]!=0)&&(pfJetGoodNum>=2&&pfJetGoodID[1]!=0)"&&basiccut);//don't use this for the "essential cut", because we want to plot nJets as well as mll in the inclusive case; we thus use it as an addition nJets cut.
  //TCut jetqualitycut("(pfJetGoodNum>=2&&pfJetGoodID[0])&&(pfJetGoodNum>=2&&pfJetGoodID[1])");//now part of the basiccut
  //TCut jetqualitycut("mll>0");
  
  TCut cutnJets("pfJetGoodNum>=3"&&basicqualitycut);
  TCut cutnJetsJESdown("pfJetGoodNumn1sigma>=3"&&basicqualitycut);
  TCut cutnJetsJESup("pfJetGoodNump1sigma>=3"&&basicqualitycut);
  TCut cutOSOF("(id1!=id2)&&(ch1*ch2<0)");
  TCut cutOSSF("(id1==id2)&&(ch1*ch2<0)");
  TCut sidebandcut(Restrsidebandcut);

  // SUSY scan parameters
  float mglustart=25;float mgluend=1200;float mglustep=25;
  float mLSPstart=25;float mLSPend=1200;float mLSPstep=25;
  
  float m0start=0;  float m0end=3000;  float m0step=20;
  float m12start=0; float m12end=1000;  float m12step=20;

  int ScanXzones=15; // number of zones in x for (mSUGRA) scans
  int ScanYzones=15; // number of zones in y for (mSUGRA) scans
  
  string mSUGRAxsFile="Plotting/Modules/external/msugra_m0_m12_10_0_1_NLO_1.0.txt";
  string SMSReferenceXSFile="Plotting/Modules/external/reference_xSec_SMS-new.root";

  //scan types:
  int mSUGRA=1;
  int SMS=2;
  int GMSB=3;

  TCut essential(passtrig);//add here any cuts you ALWAYS want
  int dogaus=0;
  int doKM=1;
  int dogaus2sigma=2;
  int dogaus3sigma=3;
  int Kostasmethod=-99;
  
  float fitresultconstdata=0;//this is the result when fitting in the 0-30 GeV range
  float fitresultconstmc=0;//this is the result when fitting in the 0-30 GeV range
  
  int method=-1;//Fitting method
  
  //now some style issues:
  float DataMarkerSize=1.2;
  
  //here we save our number of predicted and observed events (with errors)
  vector<float> Nobs;
  vector<float> Npred;
  vector<float> Nprederr;
  
  //here we save our "flipped" number of predicted and observed events (with errors) -- this means that we consider JZB<-X as observed and construct the corresponding prediction
  bool alwaysflip=false;
  bool allowflipping=true;
  vector<float> flippedNobs;
  vector<float> flippedNpred;
  vector<float> flippedNprederr;
  
  int noJES=0;
  int JESdown=1;
  int JESup=2;
  
  // Uncertainties ONPEAK
  float zjetsestimateuncertONPEAK=0.25;
  float emuncertONPEAK=0.25;
  float emsidebanduncertONPEAK=0.25;
  float eemmsidebanduncertONPEAK=0.25;

  // Uncertainties OFFPEAK (iJZB)
  float zjetsestimateuncertOFFPEAK=0.25;
  float emuncertOFFPEAK=0.1;
  float emsidebanduncertOFFPEAK=0.0;
  float eemmsidebanduncertOFFPEAK=0.0;

  
  //some refinement: nicer color gradient
  Double_t stops[5] = { 0.00, 0.34, 0.61, 0.84, 1.00 };
  Double_t red[5]   = { 0.00, 0.00, 0.87, 1.00, 0.51 };
  Double_t green[5] = { 0.00, 0.81, 1.00, 0.20, 0.00 };
  Double_t blue[5]  = { 0.51, 1.00, 0.12, 0.00, 0.00 };
  int fi=TColor::CreateGradientColorTable(5, stops, red, green,blue, 255);
  
  // LIMITS
  int nlimittoys=1000; // how many toys for setting limits
  string limitmethod="cls";//what method to use to set limits
  int limitpatience=20; // for how many minutes should the limit calculation (for one configuration!) be allowed to run before being aborted? this only has an effect when when running on the t3 batch; the value for CRAB is on the next line
  int limitpatienceCRAB=60;
  bool ConsiderSignalContaminationForLimits=true; //whether or not to consider signal contamination when computing limits (standard:true)
  int nuisancemodel=1;
  
  float JZBPeakPositionData=-999;
  float JZBPeakPositionMC=-999;
  float JZBPeakWidthData=-999;
  float JZBPeakWidthMC=-999;

  // two possible future systematics that ATM only take up CPU time in SUSY scans
  bool computeJZBefficiency=false;
  bool computeJZBresponse=false;

  bool requireZ=true;//this is switched to "off" automatically when doing offpeak!
  
  string ScanSampleDirectory="SMS_T5zzh_newslots";//DileptonmSUGRAScan__pieces

//  string ScanSampleDirectory="DileptonScan__pieces"; // possibilities (atm) : SMS_T5zz/, SMS_T5zzl/, SMS_T5zzh/, GMSB/, mSUGRA/     note: this string needs to either contain "SMS", "GMSB", or "mSUGRA"
//  string ScanSampleDirectory="SMS_T1lh"; // possibilities (atm) : SMS_T5zz/, SMS_T5zzl/, SMS_T5zzh/, GMSB/, mSUGRA/     note: this string needs to either contain "SMS", "GMSB", or "mSUGRA"

  string FilterEfficiencyFile = "/shome/buchmann/JellyfishCBAF/DistributedModelCalculations/Limits/FilterEfficiencyv3.root";
  string CMSSW_dir = "/shome/buchmann/final_production_2011/CMSSW_4_2_8/src/";

  ResultLibrary allresults;
}
Revision:	1.19
Committed:	Wed May 23 15:11:57 2012 UTC (12 years, 11 months ago) by buchmann
Content type:	text/plain
Branch:	MAIN
Changes since 1.18:	+9 -4 lines
Log Message:	Added some new variables so we can switch between 2012 and 2011 data - please remove this stuff once we've completely moved to 2012
#	User	Rev	Content
1	buchmann	1.1	#include <iostream>
2			#include <fstream>
3			#include <TCut.h>
4			#include <TColor.h>
5			#include <TStyle.h>
6
7			#ifndef SampleClassLoaded
8			#include "SampleClass.C"
9			#endif
10			#define SetupLoaded
11			#ifndef ResultLibraryClassLoaded
12			#include "ResultLibraryClass.C"
13			#endif
14
15
16			using namespace std;
17
18
19			namespace PlottingSetup {
20
21	buchmann	1.4	string directoryname="Jellyfish_tests";
22	buchmann	1.1
23	buchmann	1.19	bool RestrictToMassPeak=true; //if you want to switch between offpeak ("false") and onpeak ("true") analysis please use this switch; the masscut below will be adapted automatically when adding samples :-)
24	buchmann	1.17	bool FullMCAnalysis=false;
25	buchmann	1.18	bool DoBTag=false;
26	buchmann	1.1
27	buchmann	1.19	// the 2012 switch is in GeneralToolBox
28
29	buchmann	1.10	float luminosity=4980;//4653.74;//p3523.18;//2096.0;//3172.73;//2096.0;//1936;//751.0;//486.0;//468.0//336.;//pb^{-1}
30	buchmann	1.1	// float luminosity=3523.18;//2096.0;//3172.73;//2096.0;//1936;//751.0;//486.0;//468.0//336.;//pb^{-1}
31			// float luminosity=2096.0;//3172.73;//2096.0;//1936;//751.0;//486.0;//468.0//336.;//pb^{-1}
32	buchmann	1.10	float lumiuncert=0.022;//0.045;// to be indicated in [0,1] range, e.g. for 4% write 0.04
33	buchmann	1.19
34			float luminosity2012=705;
35			float lumiuncert2012=0.022;
36	buchmann	1.1
37	buchmann	1.7	// string jzbvariabledata="jzb[1]+0.06*pt";
38			// string jzbvariablemc="jzb[1]+0.04*pt";
39	buchmann	1.19	string jzbvariabledata="(jzb[1]+0.06*pt)";
40			string jzbvariablemc="(jzb[1]+0.04*pt)";
41	buchmann	1.1	float jzbHigh = 400.; // Range for JZB plots
42
43			samplecollection allsamples("completesamplecollection");
44	buchmann	1.5	samplecollection qcdsamples("QCDcollection");
45	buchmann	1.1	samplecollection signalsamples("signalsamplecollection");
46			samplecollection systsamples("systematicssamplecollection");
47			samplecollection scansample("scansamplecollection");
48			samplecollection raresample("raresamplecollection");
49			int data=1;
50			int mc=0;
51			int mcwithsignal=2;
52	buchmann	1.6	TCut leptoncut("(pt1>20&&pt2>20)");
53	buchmann	1.9	TCut passtrig("(passed_triggers\|\|!is_data)"&&leptoncut);
54	buchmann	1.7
55	buchmann	1.13	TCut openmasscut("mll>20"); // this is the mass cut used in the off peak analysis!
56			TCut openGenmasscut("genMll>20");
57	buchmann	1.7	TCut opensidebandcut("mll>500&&mll<100"); // this won't let anything thru ...
58
59			TCut Restrmasscut("abs(mll-91.2)<20"); // this is the mass cut used in the off peak analysis!
60			TCut RestrGenmasscut("abs(genMll-91.2)<20");
61			TCut Restrsidebandcut("((mll>55&&mll<70)\|\|(mll>112&&mll<160))");
62
63			TCut cutmass(Restrmasscut);
64			TCut genMassCut(RestrGenmasscut);
65
66	buchmann	1.19	TCut bTagRequirement("pfJetGoodNumBtag>0");
67	buchmann	1.7
68	buchmann	1.1	//TCut cutmass("mll>2");
69	buchmann	1.13	// TCut basiccut("mll>2"&&leptoncut&&"(bTagProbTHighEff[0]>1.7)&&(bTagProbTHighEff[1]>1.7)");//basically nothing.
70			TCut basiccut("mll>2"&&leptoncut);//basically nothing
71	buchmann	1.7	TCut basicqualitycut("(pfJetGoodNum>=2&&pfJetGoodID[0]!=0)&&(pfJetGoodNum>=2&&pfJetGoodID[1]!=0)"&&basiccut);//don't use this for the "essential cut", because we want to plot nJets as well as mll in the inclusive case; we thus use it as an addition nJets cut.
72	buchmann	1.1	//TCut jetqualitycut("(pfJetGoodNum>=2&&pfJetGoodID[0])&&(pfJetGoodNum>=2&&pfJetGoodID[1])");//now part of the basiccut
73			//TCut jetqualitycut("mll>0");
74
75			TCut cutnJets("pfJetGoodNum>=3"&&basicqualitycut);
76	buchmann	1.14	TCut cutnJetsJESdown("pfJetGoodNumn1sigma>=3"&&basicqualitycut);
77	buchmann	1.13	TCut cutnJetsJESup("pfJetGoodNump1sigma>=3"&&basicqualitycut);
78	buchmann	1.1	TCut cutOSOF("(id1!=id2)&&(ch1*ch2<0)");
79			TCut cutOSSF("(id1==id2)&&(ch1*ch2<0)");
80	buchmann	1.7	TCut sidebandcut(Restrsidebandcut);
81	buchmann	1.1
82			// SUSY scan parameters
83			float mglustart=25;float mgluend=1200;float mglustep=25;
84			float mLSPstart=25;float mLSPend=1200;float mLSPstep=25;
85
86	buchmann	1.7	float m0start=0; float m0end=3000; float m0step=20;
87			float m12start=0; float m12end=1000; float m12step=20;
88	buchmann	1.2
89	buchmann	1.7	int ScanXzones=15; // number of zones in x for (mSUGRA) scans
90			int ScanYzones=15; // number of zones in y for (mSUGRA) scans
91	buchmann	1.8
92	buchmann	1.16	string mSUGRAxsFile="Plotting/Modules/external/msugra_m0_m12_10_0_1_NLO_1.0.txt";
93	buchmann	1.15	string SMSReferenceXSFile="Plotting/Modules/external/reference_xSec_SMS-new.root";
94	buchmann	1.1
95			//scan types:
96			int mSUGRA=1;
97			int SMS=2;
98			int GMSB=3;
99
100			TCut essential(passtrig);//add here any cuts you ALWAYS want
101			int dogaus=0;
102			int doKM=1;
103			int dogaus2sigma=2;
104			int dogaus3sigma=3;
105			int Kostasmethod=-99;
106
107			float fitresultconstdata=0;//this is the result when fitting in the 0-30 GeV range
108			float fitresultconstmc=0;//this is the result when fitting in the 0-30 GeV range
109
110			int method=-1;//Fitting method
111
112			//now some style issues:
113			float DataMarkerSize=1.2;
114
115			//here we save our number of predicted and observed events (with errors)
116			vector<float> Nobs;
117			vector<float> Npred;
118			vector<float> Nprederr;
119
120			//here we save our "flipped" number of predicted and observed events (with errors) -- this means that we consider JZB<-X as observed and construct the corresponding prediction
121			bool alwaysflip=false;
122	buchmann	1.10	bool allowflipping=true;
123	buchmann	1.1	vector<float> flippedNobs;
124			vector<float> flippedNpred;
125			vector<float> flippedNprederr;
126
127			int noJES=0;
128			int JESdown=1;
129			int JESup=2;
130
131	buchmann	1.14	// Uncertainties ONPEAK
132			float zjetsestimateuncertONPEAK=0.25;
133			float emuncertONPEAK=0.25;
134			float emsidebanduncertONPEAK=0.25;
135			float eemmsidebanduncertONPEAK=0.25;
136
137			// Uncertainties OFFPEAK (iJZB)
138			float zjetsestimateuncertOFFPEAK=0.25;
139			float emuncertOFFPEAK=0.1;
140			float emsidebanduncertOFFPEAK=0.0;
141			float eemmsidebanduncertOFFPEAK=0.0;
142
143
144	buchmann	1.1	//some refinement: nicer color gradient
145			Double_t stops[5] = { 0.00, 0.34, 0.61, 0.84, 1.00 };
146			Double_t red[5] = { 0.00, 0.00, 0.87, 1.00, 0.51 };
147			Double_t green[5] = { 0.00, 0.81, 1.00, 0.20, 0.00 };
148			Double_t blue[5] = { 0.51, 1.00, 0.12, 0.00, 0.00 };
149			int fi=TColor::CreateGradientColorTable(5, stops, red, green,blue, 255);
150
151			// LIMITS
152			int nlimittoys=1000; // how many toys for setting limits
153			string limitmethod="cls";//what method to use to set limits
154	buchmann	1.12	int limitpatience=20; // for how many minutes should the limit calculation (for one configuration!) be allowed to run before being aborted? this only has an effect when when running on the t3 batch; the value for CRAB is on the next line
155	buchmann	1.1	int limitpatienceCRAB=60;
156			bool ConsiderSignalContaminationForLimits=true; //whether or not to consider signal contamination when computing limits (standard:true)
157			int nuisancemodel=1;
158
159			float JZBPeakPositionData=-999;
160			float JZBPeakPositionMC=-999;
161			float JZBPeakWidthData=-999;
162			float JZBPeakWidthMC=-999;
163
164			// two possible future systematics that ATM only take up CPU time in SUSY scans
165			bool computeJZBefficiency=false;
166			bool computeJZBresponse=false;
167
168	buchmann	1.7	bool requireZ=true;//this is switched to "off" automatically when doing offpeak!
169	buchmann	1.16
170	buchmann	1.17	string ScanSampleDirectory="SMS_T5zzh_newslots";//DileptonmSUGRAScan__pieces
171	buchmann	1.1
172	buchmann	1.13	// string ScanSampleDirectory="DileptonScan__pieces"; // possibilities (atm) : SMS_T5zz/, SMS_T5zzl/, SMS_T5zzh/, GMSB/, mSUGRA/ note: this string needs to either contain "SMS", "GMSB", or "mSUGRA"
173	buchmann	1.16	// string ScanSampleDirectory="SMS_T1lh"; // possibilities (atm) : SMS_T5zz/, SMS_T5zzl/, SMS_T5zzh/, GMSB/, mSUGRA/ note: this string needs to either contain "SMS", "GMSB", or "mSUGRA"
174	buchmann	1.11
175			string FilterEfficiencyFile = "/shome/buchmann/JellyfishCBAF/DistributedModelCalculations/Limits/FilterEfficiencyv3.root";
176	buchmann	1.13	string CMSSW_dir = "/shome/buchmann/final_production_2011/CMSSW_4_2_8/src/";
177	buchmann	1.1
178			ResultLibrary allresults;
179			}