Nus18SystsNeutronLoad.C
Go to the documentation of this file.
1 /////////////////////////////////////////////////////////////////////
2 // Neutron systematics for Nus18
3 //
4 // Author: Sijith Edayath
5 // Modified by Mike Wallbank (wallbank@fnal.gov)
6 /////////////////////////////////////////////////////////////////////
7 
9 #include "CAFAna/Core/Loaders.h"
10 #include "CAFAna/Core/SystShifts.h"
11 #include "CAFAna/Core/Utilities.h"
12 #include "CAFAna/Cuts/Cuts.h"
13 #include "NuXAna/Cuts/NusCuts18.h"
15 #include "CAFAna/Cuts/SpillCuts.h"
23 #include "CAFAna/Systs/BeamSysts.h"
24 #include "CAFAna/Systs/Systs.h"
26 #include "CAFAna/Vars/HistAxes.h"
27 #include "NuXAna/Vars/HistAxes.h"
29 
32 
33 using namespace ana;
34 
35 /// Run systematics for Neutrons
36 void Nus18SystsNeutronLoad(TString opt) {
37 
38  TH1::AddDirectory(0);
39  const Var kReweight = kXSecCVWgt2018*kPPFXFluxCVWgt;
40 
41  // Get options
42  ECAFType cafType;
43  Loaders::FluxType fluxType;
44  bool extrap = false;
45  if (opt.Contains("caf", TString::kIgnoreCase))
46  cafType = ECAFType::kFullCAF;
47  else if (opt.Contains("concat", TString::kIgnoreCase))
48  cafType = ECAFType::kNusConcat;
49  else {
50  std::cout << "ECAFType required: caf or concat" << std::endl;
51  abort();
52  }
53  if (opt.Contains("fhc", TString::kIgnoreCase))
54  fluxType = Loaders::FluxType::kFHC;
55  else if (opt.Contains("rhc", TString::kIgnoreCase))
56  fluxType = Loaders::FluxType::kRHC;
57  else {
58  std::cout << "FluxType required: fhc or rhc" << std::endl;
59  abort();
60  }
61  if (opt.Contains("extrap", TString::kIgnoreCase))
62  extrap = true;
63 
64  // Set up the loaders
65  Loaders* loaders = new Prod4NomLoaders(cafType, fluxType);
67 
68  // Vector of sigmas, levels to set each systematic
69  const std::vector<int> sigmas{-2, -1, +1, +2};
70 
71  // Get the labels for all Beam Transport systematics
72  std::map<std::string, SystShifts> shiftLabels;
73  shiftLabels["NeutronPrimaries"] = SystShifts::Nominal();
74 
75  // Define map of systematic objects, indexed by same labels as previous map
76  std::map<std::string, std::map<int, SystShifts*> > systematics;
77  for (const auto& shiftLabel : shiftLabels)
78  for (const auto& sigma : sigmas)
79  systematics[shiftLabel.first][sigma] = new SystShifts(&kNeutronVisEScalePrimariesSyst2018, sigma);
80 
81  // Define a map of samples and cuts/axes to set them up
82  // Each sample, essentially, is a way to set up the analysis
83  HistAxis AxisRecoE = kNus18AxisE;
84  std::map<std::string, std::pair<HistAxis*, std::pair<Cut*, Cut*> > > cut_samples;
85  cut_samples["Nus18"] = std::make_pair(&AxisRecoE, std::make_pair(new Cut(kNus18ND), new Cut(kNus18FD)));
86 
87  // Set up maps to the decompositions/predictions (each flavor component)
88  // Nominal maps are indexed purely by sample label
89  // Shifted maps are indexed by sample label, systematic label, then sigma of the shift
90  std::map<std::string, NDPredictionSterile*> predsND_nominal;
91  std::map<std::string, FDPredictionSterile*> predsFD_nominal;
92  std::map<std::string, PredictionSterile*> predsExtrap_nominal;
93  std::map<std::string, std::map<std::string, std::map<int, NDPredictionSterile*> > > predsND_shifted;
94  std::map<std::string, std::map<std::string, std::map<int, FDPredictionSterile*> > > predsFD_shifted;
95  std::map<std::string, std::map<std::string, std::map<int, PredictionSterile*> > > predsExtrap_shifted;
96 
97  // Set up the actual decompositions/predictions
98  // sample.first = the sample label
99  // shiftLabel.first = the systematic shift label
100  // sample.second.first = the sample HistAxis
101  // sample.second.second = the sample Cut
102  // syst.first = the integer number of sigmas for the shift
103  // syst.second = the systematic being shifted
104  for (const auto& sample : cut_samples) {
105 
106  const NDPredictionGenerator gennd(*sample.second.first, *sample.second.second.first, kNoShift, kReweight);
107  const FDPredictionGenerator genfd(*sample.second.first, *sample.second.second.second, kNoShift, kReweight);
108  SterileGenerator* genExtrap;
109  if (extrap)
110  genExtrap = new SterileGenerator(*sample.second.first, kNus18BinsNumuCCAxis,
111  *sample.second.second.second, *sample.second.second.first,
112  kNumuCutND2018, kNoShift, kReweight);
113 
114  // Set up the nominal decompositions
115  // Only one is needed per sample
116  predsND_nominal[sample.first] = (NDPredictionSterile*)gennd.Generate(*loaders).release();
117  predsFD_nominal[sample.first] = (FDPredictionSterile*)genfd.Generate(*loaders).release();
118  if (extrap)
119  predsExtrap_nominal[sample.first] = (PredictionSterile*)genExtrap->Generate(*loaders).release();
120 
121  // Set up the shifted decompositions
122  // One is needed for every sample, systematic, and sigma level
123  for(const auto& shiftLabel : shiftLabels) {
124  for(const auto& syst : systematics[shiftLabel.first]) {
125  predsND_shifted[sample.first][shiftLabel.first][syst.first]
126  = (NDPredictionSterile*)gennd.Generate(*loaders, *syst.second).release();
127  predsFD_shifted[sample.first][shiftLabel.first][syst.first]
128  = (FDPredictionSterile*)genfd.Generate(*loaders, *syst.second).release();
129  if (extrap)
130  predsExtrap_shifted[sample.first][shiftLabel.first][syst.first]
131  = (PredictionSterile*)genExtrap->Generate(*loaders, *syst.second).release();
132  }
133  }
134 
135  if (extrap)
136  delete genExtrap;
137 
138  }
139 
140  loaders->Go();
141 
142  std::string folder = "./";
143  std::string filenm = "SystsNeutron18";
144 
145  std::string fullLocation = folder + filenm + ".root";
146  TFile* rootF = new TFile(fullLocation.c_str(), "RECREATE");
147  SaveMaps(rootF, predsND_nominal, predsND_shifted);
148  SaveMaps(rootF, predsFD_nominal, predsFD_shifted);
149  if (extrap)
150  SaveMaps(rootF, predsExtrap_nominal, predsExtrap_shifted);
151  rootF->Close();
152 
153  // delete loaders;
154 
155  return;
156 
157 }
Cuts and Vars for the 2020 FD DiF Study.
Definition: vars.h:6
const Var kPPFXFluxCVWgt
Definition: PPFXWeights.h:16
std::unique_ptr< IPrediction > Generate(Loaders &loaders, const SystShifts &shiftMC=kNoShift) const override
std::unique_ptr< IPrediction > Generate(Loaders &loaders, const SystShifts &shiftMC=kNoShift) const override
Simple record of shifts applied to systematic parameters.
Definition: SystShifts.h:20
const Cut kNumuCutND2018
Definition: NumuCuts2018.h:41
Collection of SpectrumLoaders for many configurations.
Definition: Loaders.h:23
void SaveMaps(TDirectory *out, std::map< std::string, IDecomp * > decomps_nominal, std::map< std::string, std::map< std::string, std::map< int, IDecomp * > > > decomps_shifted, std::map< std::string, PredictionNoExtrap * > predsNE_nominal, std::map< std::string, std::map< std::string, std::map< int, PredictionNoExtrap * > > > predsNE_shifted, std::map< std::string, PredictionSterile * > predsSt_nominal, std::map< std::string, std::map< std::string, std::map< int, PredictionSterile * > > > predsSt_shifted)
Save all of the objects in the input maps to the out directory/file.
Definition: PPFXHelper.h:1077
std::pair< Spectrum *, CheatDecomp * > make_pair(SpectrumLoaderBase &loader_data, SpectrumLoaderBase &loader_mc, HistAxis *axis, Cut *cut, const SystShifts &shift, const Var &wei)
Definition: DataMCLoad.C:336
const NeutronVisEScaleSyst2018 kNeutronVisEScalePrimariesSyst2018(false)
static SystShifts Nominal()
Definition: SystShifts.h:34
Generates extrapolated NC predictions using ProportionalDecomp.
const Cut kNus18FD
Definition: NusCuts18.h:100
const HistAxis kNus18AxisE("Energy Deposited in Scintillator (GeV)", kNus18EnergyBinning, kNus18Energy)
Axes used in Nus18 analysis by nus group.
Definition: HistAxes.h:16
void Go()
Call Go() on all the loaders.
Definition: Loaders.cxx:162
void SetSpillCut(const SpillCut &cut)
Definition: Loaders.cxx:121
_Cut< caf::SRProxy > Cut
Representation of a cut (selection) to be applied to a caf::StandardRecord object.
Definition: Cut.h:96
const Cut kNus18ND
Full Nus18 ND analysis selection.
Definition: NusCuts18.h:137
Take the output of an extrapolation and oscillate it as required.
double sigma(TH1F *hist, double percentile)
const SystShifts kNoShift
Definition: SystShifts.cxx:22
OStream cout
Definition: OStream.cxx:6
const Var kXSecCVWgt2018
Definition: XsecTunes.h:49
std::vector< Loaders * > loaders
Definition: syst_header.h:386
bool systematics
Definition: fnexvscaf.C:31
A prediction object compatible with sterile oscillations.
const HistAxis kNus18BinsNumuCCAxis("Reconstructed Neutrino Energy (GeV)", kNus18EnergyBinning, kCCE)
Definition: HistAxes.h:17
void Nus18SystsNeutronLoad(TString opt)
Run systematics for Neutrons.
std::unique_ptr< IPrediction > Generate(Loaders &loaders, const SystShifts &shiftMC=kNoShift) const override
Take the output of an extrapolation and oscillate it as required.
const SpillCut kStandardSpillCuts
Apply this unless you&#39;re doing something special.
Definition: SpillCuts.h:49
For nominal spectra and reweighting systs (xsec/flux)
Definition: Prod4Loaders.h:96
Generates Near Detector predictions.
ECAFType
Definition: Loaders.h:19
enum BeamMode string