diff --git a/src/FitBase/Measurement2D.cxx b/src/FitBase/Measurement2D.cxx
index 4c3a6df..33fdd0f 100644
--- a/src/FitBase/Measurement2D.cxx
+++ b/src/FitBase/Measurement2D.cxx
@@ -1,1961 +1,1961 @@
// Copyright 2016 L. Pickering, P Stowell, R. Terri, C. Wilkinson, C. Wret
/*******************************************************************************
* This file is part of NUISANCE.
*
* NUISANCE is free software: you can redistribute it and/or modify
* it under the terms of the GNU General Public License as published by
* the Free Software Foundation, either version 3 of the License, or
* (at your option) any later version.
*
* NUISANCE is distributed in the hope that it will be useful,
* but WITHOUT ANY WARRANTY; without even the implied warranty of
* MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
* GNU General Public License for more details.
*
* You should have received a copy of the GNU General Public License
* along with NUISANCE. If not, see .
*******************************************************************************/
#include "Measurement2D.h"
#include "TDecompChol.h"
//********************************************************************
Measurement2D::Measurement2D(void) {
//********************************************************************
covar = NULL;
fDecomp = NULL;
fFullCovar = NULL;
fMCHist = NULL;
fMCFine = NULL;
fDataHist = NULL;
fMCHist_X = NULL;
fMCHist_Y = NULL;
fDataHist_X = NULL;
fDataHist_Y = NULL;
fMaskHist = NULL;
fMapHist = NULL;
fDataOrig = NULL;
fDataTrue = NULL;
fMCWeighted = NULL;
fDefaultTypes = "FIX/FULL/CHI2";
fAllowedTypes =
"FIX,FREE,SHAPE/FULL,DIAG/CHI2/NORM/ENUCORR/Q2CORR/ENU1D/FITPROJX/"
"FITPROJY";
fIsFix = false;
fIsShape = false;
fIsFree = false;
fIsDiag = false;
fIsFull = false;
fAddNormPen = false;
fIsMask = false;
fIsChi2SVD = false;
fIsRawEvents = false;
fIsDifXSec = false;
fIsEnu = false;
// XSec Scalings
fScaleFactor = -1.0;
fCurrentNorm = 1.0;
// Histograms
fDataHist = NULL;
fDataTrue = NULL;
fMCHist = NULL;
fMCFine = NULL;
fMCWeighted = NULL;
fMaskHist = NULL;
// Covar
covar = NULL;
fFullCovar = NULL;
fCovar = NULL;
fInvert = NULL;
fDecomp = NULL;
// Fake Data
fFakeDataInput = "";
fFakeDataFile = NULL;
// Options
fDefaultTypes = "FIX/FULL/CHI2";
fAllowedTypes =
"FIX,FREE,SHAPE/FULL,DIAG/CHI2/NORM/ENUCORR/Q2CORR/ENU1D/MASK";
fIsFix = false;
fIsShape = false;
fIsFree = false;
fIsDiag = false;
fIsFull = false;
fAddNormPen = false;
fIsMask = false;
fIsChi2SVD = false;
fIsRawEvents = false;
fIsDifXSec = false;
fIsEnu1D = false;
// Inputs
fInput = NULL;
fRW = NULL;
// Extra Histograms
fMCHist_Modes = NULL;
}
//********************************************************************
Measurement2D::~Measurement2D(void) {
//********************************************************************
if (fDataHist) delete fDataHist;
if (fDataTrue) delete fDataTrue;
if (fMCHist) delete fMCHist;
if (fMCFine) delete fMCFine;
if (fMCWeighted) delete fMCWeighted;
if (fMaskHist) delete fMaskHist;
if (covar) delete covar;
if (fFullCovar) delete fFullCovar;
if (fCovar) delete fCovar;
if (fInvert) delete fInvert;
if (fDecomp) delete fDecomp;
}
//********************************************************************
void Measurement2D::FinaliseSampleSettings() {
//********************************************************************
MeasurementBase::FinaliseSampleSettings();
// Setup naming + renaming
fName = fSettings.GetName();
fSettings.SetS("originalname", fName);
if (fSettings.Has("rename")) {
fName = fSettings.GetS("rename");
fSettings.SetS("name", fName);
}
// Setup all other options
LOG(SAM) << "Finalising Sample Settings: " << fName << std::endl;
if ((fSettings.GetS("originalname").find("Evt") != std::string::npos)) {
fIsRawEvents = true;
LOG(SAM) << "Found event rate measurement but using poisson likelihoods."
<< std::endl;
}
if (fSettings.GetS("originalname").find("XSec_1DEnu") != std::string::npos) {
fIsEnu1D = true;
LOG(SAM) << "::" << fName << "::" << std::endl;
LOG(SAM) << "Found XSec Enu measurement, applying flux integrated scaling, "
<< "not flux averaged!" << std::endl;
}
if (fIsEnu1D && fIsRawEvents) {
LOG(SAM) << "Found 1D Enu XSec distribution AND fIsRawEvents, is this "
"really correct?!"
<< std::endl;
LOG(SAM) << "Check experiment constructor for " << fName
<< " and correct this!" << std::endl;
LOG(SAM) << "I live in " << __FILE__ << ":" << __LINE__ << std::endl;
exit(-1);
}
if (!fRW) fRW = FitBase::GetRW();
if (!fInput) SetupInputs(fSettings.GetS("input"));
// Setup options
SetFitOptions(fDefaultTypes); // defaults
SetFitOptions(fSettings.GetS("type")); // user specified
EnuMin = GeneralUtils::StrToDbl(fSettings.GetS("enu_min"));
EnuMax = GeneralUtils::StrToDbl(fSettings.GetS("enu_max"));
if (fAddNormPen) {
fNormError = fSettings.GetNormError();
if (fNormError <= 0.0) {
ERR(WRN) << "Norm error for class " << fName << " is 0.0!" << std::endl;
ERR(WRN) << "If you want to use it please add fNormError=VAL" << std::endl;
throw;
}
}
}
void Measurement2D::CreateDataHistogram(int dimx, double* binx, int dimy, double* biny) {
if (fDataHist) delete fDataHist;
LOG(SAM) << "Creating Data Histogram dim : " << dimx << " " << dimy << std::endl;
fDataHist = new TH2D( (fSettings.GetName() + "_data").c_str(), (fSettings.GetFullTitles()).c_str(),
dimx - 1, binx, dimy - 1, biny );
}
void Measurement2D::SetDataFromTextFile(std::string datfile) {
// fDataHist = PlotUtils::GetTH2DFromTextFile(datfile,"");
}
void Measurement2D::SetDataFromRootFile(std::string datfile, std::string histname) {
fDataHist = PlotUtils::GetTH2DFromRootFile(datfile, histname);
}
void Measurement2D::SetDataValuesFromTextFile(std::string datfile, TH2D* hist) {
LOG(SAM) << "Setting data values from text file" << std::endl;
if (!hist) hist = fDataHist;
// Read TH2D From textfile
TH2D* valhist = (TH2D*) hist->Clone();
valhist->Reset();
PlotUtils::Set2DHistFromText(datfile, valhist, 1.0, true);
LOG(SAM) << " -> Filling values from read hist." << std::endl;
for (int i = 0; i < valhist->GetNbinsX(); i++) {
for (int j = 0; j < valhist->GetNbinsY(); j++) {
hist->SetBinContent(i + 1, j + 1, valhist->GetBinContent(i + 1, j + 1));
}
}
LOG(SAM) << " --> Done" << std::endl;
}
void Measurement2D::SetDataErrorsFromTextFile(std::string datfile, TH2D* hist) {
LOG(SAM) << "Setting data errors from text file" << std::endl;
if (!hist) hist = fDataHist;
// Read TH2D From textfile
TH2D* valhist = (TH2D*) hist->Clone();
valhist->Reset();
PlotUtils::Set2DHistFromText(datfile, valhist, 1.0);
// Fill Errors
LOG(SAM) << " -> Filling errors from read hist." << std::endl;
for (int i = 0; i < valhist->GetNbinsX(); i++) {
for (int j = 0; j < valhist->GetNbinsY(); j++) {
hist->SetBinError(i + 1, j + 1, valhist->GetBinContent(i + 1, j + 1));
}
}
LOG(SAM) << " --> Done" << std::endl;
}
void Measurement2D::SetMapValuesFromText(std::string dataFile) {
TH2D* hist = fDataHist;
std::vector edgex;
std::vector edgey;
for (int i = 0; i <= hist->GetNbinsX(); i++) edgex.push_back(hist->GetXaxis()->GetBinLowEdge(i + 1));
for (int i = 0; i <= hist->GetNbinsY(); i++) edgey.push_back(hist->GetYaxis()->GetBinLowEdge(i + 1));
fMapHist = new TH2I((fName + "_map").c_str(), (fName + fPlotTitles).c_str(),
edgex.size() - 1, &edgex[0], edgey.size() - 1, &edgey[0]);
LOG(SAM) << "Reading map from: " << dataFile << std::endl;
PlotUtils::Set2DHistFromText(dataFile, fMapHist, 1.0);
}
//********************************************************************
void Measurement2D::SetPoissonErrors() {
//********************************************************************
if (!fDataHist) {
ERR(FTL) << "Need a data hist to setup possion errors! " << std::endl;
ERR(FTL) << "Setup Data First!" << std::endl;
throw;
}
for (int i = 0; i < fDataHist->GetNbinsX() + 1; i++) {
fDataHist->SetBinError(i + 1, sqrt(fDataHist->GetBinContent(i + 1)));
}
}
//********************************************************************
void Measurement2D::SetCovarFromDiagonal(TH2D* data) {
//********************************************************************
if (!data and fDataHist) {
data = fDataHist;
}
if (data) {
LOG(SAM) << "Setting diagonal covariance for: " << data->GetName() << std::endl;
fFullCovar = StatUtils::MakeDiagonalCovarMatrix(data);
covar = StatUtils::GetInvert(fFullCovar);
fDecomp = StatUtils::GetDecomp(fFullCovar);
} else {
ERR(FTL) << "No data input provided to set diagonal covar from!" << std::endl;
}
// if (!fIsDiag) {
// ERR(FTL) << "SetCovarMatrixFromDiag called for measurement "
// << "that is not set as diagonal." << std::endl;
// throw;
// }
}
//********************************************************************
void Measurement2D::SetCovarFromTextFile(std::string covfile, int dim) {
//********************************************************************
if (dim == -1) {
dim = this->GetNDOF();
}
LOG(SAM) << "Reading covariance from text file: " << covfile << std::endl;
fFullCovar = StatUtils::GetCovarFromTextFile(covfile, dim);
covar = StatUtils::GetInvert(fFullCovar);
fDecomp = StatUtils::GetDecomp(fFullCovar);
}
//********************************************************************
void Measurement2D::SetCovarFromRootFile(std::string covfile, std::string histname) {
//********************************************************************
LOG(SAM) << "Reading covariance from text file: " << covfile << ";" << histname << std::endl;
fFullCovar = StatUtils::GetCovarFromRootFile(covfile, histname);
covar = StatUtils::GetInvert(fFullCovar);
fDecomp = StatUtils::GetDecomp(fFullCovar);
}
//********************************************************************
void Measurement2D::SetCovarInvertFromTextFile(std::string covfile, int dim) {
//********************************************************************
if (dim == -1) {
dim = this->GetNDOF();
}
LOG(SAM) << "Reading inverted covariance from text file: " << covfile << std::endl;
covar = StatUtils::GetCovarFromTextFile(covfile, dim);
fFullCovar = StatUtils::GetInvert(covar);
fDecomp = StatUtils::GetDecomp(fFullCovar);
}
//********************************************************************
void Measurement2D::SetCovarInvertFromRootFile(std::string covfile, std::string histname) {
//********************************************************************
LOG(SAM) << "Reading inverted covariance from text file: " << covfile << ";" << histname << std::endl;
covar = StatUtils::GetCovarFromRootFile(covfile, histname);
fFullCovar = StatUtils::GetInvert(covar);
fDecomp = StatUtils::GetDecomp(fFullCovar);
}
//********************************************************************
void Measurement2D::SetCorrelationFromTextFile(std::string covfile, int dim) {
//********************************************************************
if (dim == -1) dim = this->GetNDOF();
LOG(SAM) << "Reading data correlations from text file: " << covfile << ";" << dim << std::endl;
TMatrixDSym* correlation = StatUtils::GetCovarFromTextFile(covfile, dim);
if (!fDataHist) {
ERR(FTL) << "Trying to set correlations from text file but there is no data to build it from. \n"
<< "In constructor make sure data is set before SetCorrelationFromTextFile is called. \n" << std::endl;
throw;
}
// Fill covar from data errors and correlations
fFullCovar = new TMatrixDSym(dim);
for (int i = 0; i < fDataHist->GetNbinsX(); i++) {
for (int j = 0; j < fDataHist->GetNbinsX(); j++) {
(*fFullCovar)(i, j) = (*correlation)(i, j) * fDataHist->GetBinError(i + 1) * fDataHist->GetBinError(j + 1) * 1.E76;
}
}
// Fill other covars.
covar = StatUtils::GetInvert(fFullCovar);
fDecomp = StatUtils::GetDecomp(fFullCovar);
delete correlation;
}
//********************************************************************
void Measurement2D::SetCorrelationFromRootFile(std::string covfile, std::string histname) {
//********************************************************************
LOG(SAM) << "Reading data correlations from text file: " << covfile << ";" << histname << std::endl;
TMatrixDSym* correlation = StatUtils::GetCovarFromRootFile(covfile, histname);
if (!fDataHist) {
ERR(FTL) << "Trying to set correlations from text file but there is no data to build it from. \n"
<< "In constructor make sure data is set before SetCorrelationFromTextFile is called. \n" << std::endl;
throw;
}
// Fill covar from data errors and correlations
fFullCovar = new TMatrixDSym(fDataHist->GetNbinsX());
for (int i = 0; i < fDataHist->GetNbinsX(); i++) {
for (int j = 0; j < fDataHist->GetNbinsX(); j++) {
(*fFullCovar)(i, j) = (*correlation)(i, j) * fDataHist->GetBinError(i + 1) * fDataHist->GetBinError(j + 1) * 1.E76;
}
}
// Fill other covars.
covar = StatUtils::GetInvert(fFullCovar);
fDecomp = StatUtils::GetDecomp(fFullCovar);
delete correlation;
}
//********************************************************************
void Measurement2D::SetCholDecompFromTextFile(std::string covfile, int dim) {
//********************************************************************
if (dim == -1) {
dim = this->GetNDOF();
}
LOG(SAM) << "Reading cholesky from text file: " << covfile << " " << dim << std::endl;
TMatrixD* temp = StatUtils::GetMatrixFromTextFile(covfile, dim, dim);
TMatrixD* trans = (TMatrixD*)temp->Clone();
trans->T();
(*trans) *= (*temp);
fFullCovar = new TMatrixDSym(dim, trans->GetMatrixArray(), "");
covar = StatUtils::GetInvert(fFullCovar);
fDecomp = StatUtils::GetDecomp(fFullCovar);
delete temp;
delete trans;
}
//********************************************************************
void Measurement2D::SetCholDecompFromRootFile(std::string covfile, std::string histname) {
//********************************************************************
LOG(SAM) << "Reading cholesky decomp from root file: " << covfile << ";" << histname << std::endl;
TMatrixD* temp = StatUtils::GetMatrixFromRootFile(covfile, histname);
TMatrixD* trans = (TMatrixD*)temp->Clone();
trans->T();
(*trans) *= (*temp);
fFullCovar = new TMatrixDSym(temp->GetNrows(), trans->GetMatrixArray(), "");
covar = StatUtils::GetInvert(fFullCovar);
fDecomp = StatUtils::GetDecomp(fFullCovar);
delete temp;
delete trans;
}
//********************************************************************
void Measurement2D::ScaleData(double scale) {
//********************************************************************
fDataHist->Scale(scale);
}
//********************************************************************
void Measurement2D::ScaleDataErrors(double scale) {
//********************************************************************
for (int i = 0; i < fDataHist->GetNbinsX(); i++) {
for (int j = 0; j < fDataHist->GetNbinsY(); j++) {
fDataHist->SetBinError(i + 1, j + 1, fDataHist->GetBinError(i + 1, j + 1) * scale);
}
}
}
//********************************************************************
void Measurement2D::ScaleCovar(double scale) {
//********************************************************************
(*fFullCovar) *= scale;
(*covar) *= 1.0 / scale;
(*fDecomp) *= sqrt(scale);
}
//********************************************************************
void Measurement2D::SetBinMask(std::string maskfile) {
//********************************************************************
if (!fIsMask) return;
LOG(SAM) << "Reading bin mask from file: " << maskfile << std::endl;
// Create a mask histogram with dim of data
int nbinsx = fDataHist->GetNbinsX();
int nbinxy = fDataHist->GetNbinsY();
fMaskHist =
new TH2I((fSettings.GetName() + "_BINMASK").c_str(),
(fSettings.GetName() + "_BINMASK; Bin; Mask?").c_str(), nbinsx, 0, nbinsx, nbinxy, 0, nbinxy);
std::string line;
std::ifstream mask(maskfile.c_str(), ifstream::in);
if (!mask.is_open()) {
LOG(FTL) << " Cannot find mask file." << std::endl;
throw;
}
while (std::getline(mask >> std::ws, line, '\n')) {
std::vector entries = GeneralUtils::ParseToInt(line, " ");
// Skip lines with poorly formatted lines
if (entries.size() < 2) {
LOG(WRN) << "Measurement2D::SetBinMask(), couldn't parse line: " << line
<< std::endl;
continue;
}
// The first index should be the bin number, the second should be the mask
// value.
int val = 0;
if (entries[2] > 0) val = 1;
fMaskHist->SetBinContent(entries[0], entries[1], val);
}
// Apply masking by setting masked data bins to zero
PlotUtils::MaskBins(fDataHist, fMaskHist);
return;
}
//********************************************************************
void Measurement2D::FinaliseMeasurement() {
//********************************************************************
LOG(SAM) << "Finalising Measurement: " << fName << std::endl;
if (fSettings.GetB("onlymc")) {
if (fDataHist) delete fDataHist;
fDataHist = new TH2D("empty_data", "empty_data", 1, 0.0, 1.0,1,0.0,1.0);
}
// Make sure data is setup
if (!fDataHist) {
ERR(FTL) << "No data has been setup inside " << fName << " constructor!" << std::endl;
throw;
}
// Make sure covariances are setup
if (!fFullCovar) {
fIsDiag = true;
SetCovarFromDiagonal(fDataHist);
}
if (!covar) {
covar = StatUtils::GetInvert(fFullCovar);
}
if (!fDecomp) {
fDecomp = StatUtils::GetDecomp(fFullCovar);
}
// Setup fMCHist from data
fMCHist = (TH2D*)fDataHist->Clone();
fMCHist->SetNameTitle((fSettings.GetName() + "_MC").c_str(),
(fSettings.GetFullTitles()).c_str());
fMCHist->Reset();
// Setup fMCFine
fMCFine = new TH2D("mcfine", "mcfine", fDataHist->GetNbinsX() * 6,
fMCHist->GetXaxis()->GetBinLowEdge(1),
fMCHist->GetXaxis()->GetBinLowEdge(fDataHist->GetNbinsX() + 1),
fDataHist->GetNbinsY() * 6,
fMCHist->GetYaxis()->GetBinLowEdge(1),
fMCHist->GetYaxis()->GetBinLowEdge(fDataHist->GetNbinsY() + 1));
fMCFine->SetNameTitle((fSettings.GetName() + "_MC_FINE").c_str(),
(fSettings.GetFullTitles()).c_str());
fMCFine->Reset();
// Setup MC Stat
fMCStat = (TH2D*)fMCHist->Clone();
fMCStat->Reset();
// Search drawopts for possible types to include by default
std::string drawopts = FitPar::Config().GetParS("drawopts");
if (drawopts.find("MODES") != std::string::npos) {
fMCHist_Modes = new TrueModeStack( (fSettings.GetName() + "_MODES").c_str(),
("True Channels"), fMCHist);
SetAutoProcessTH1(fMCHist_Modes);
}
// Setup bin masks using sample name
if (fIsMask) {
std::string curname = fName;
std::string origname = fSettings.GetS("originalname");
// Check rename.mask
std::string maskloc = FitPar::Config().GetParDIR(curname + ".mask");
// Check origname.mask
if (maskloc.empty()) maskloc = FitPar::Config().GetParDIR(origname + ".mask");
// Check database
if (maskloc.empty()) {
maskloc = FitPar::GetDataBase() + "/masks/" + origname + ".mask";
}
// Setup Bin Mask
SetBinMask(maskloc);
}
if (fScaleFactor < 0) {
ERR(FTL) << "I found a negative fScaleFactor in " << __FILE__ << ":" << __LINE__ << std::endl;
ERR(FTL) << "fScaleFactor = " << fScaleFactor << std::endl;
ERR(FTL) << "EXITING" << std::endl;
throw;
}
// Create and fill Weighted Histogram
if (!fMCWeighted) {
fMCWeighted = (TH2D*)fMCHist->Clone();
fMCWeighted->SetNameTitle((fName + "_MCWGHTS").c_str(),
(fName + "_MCWGHTS" + fPlotTitles).c_str());
fMCWeighted->GetYaxis()->SetTitle("Weighted Events");
}
}
//********************************************************************
void Measurement2D::SetFitOptions(std::string opt) {
//********************************************************************
// Do nothing if default given
if (opt == "DEFAULT") return;
// CHECK Conflicting Fit Options
std::vector fit_option_allow =
GeneralUtils::ParseToStr(fAllowedTypes, "/");
for (UInt_t i = 0; i < fit_option_allow.size(); i++) {
std::vector fit_option_section =
GeneralUtils::ParseToStr(fit_option_allow.at(i), ",");
bool found_option = false;
for (UInt_t j = 0; j < fit_option_section.size(); j++) {
std::string av_opt = fit_option_section.at(j);
if (!found_option and opt.find(av_opt) != std::string::npos) {
found_option = true;
} else if (found_option and opt.find(av_opt) != std::string::npos) {
ERR(FTL) << "ERROR: Conflicting fit options provided: "
<< opt << std::endl
<< "Conflicting group = " << fit_option_section.at(i) << std::endl
<< "You should only supply one of these options in card file." << std::endl;
throw;
}
}
}
// Check all options are allowed
std::vector fit_options_input =
GeneralUtils::ParseToStr(opt, "/");
for (UInt_t i = 0; i < fit_options_input.size(); i++) {
if (fAllowedTypes.find(fit_options_input.at(i)) == std::string::npos) {
ERR(FTL) << "ERROR: Fit Option '" << fit_options_input.at(i)
<< "' Provided is not allowed for this measurement."
<< std::endl;
ERR(FTL) << "Fit Options should be provided as a '/' seperated list "
"(e.g. FREE/DIAG/NORM)"
<< std::endl;
ERR(FTL) << "Available options for " << fName << " are '" << fAllowedTypes
<< "'" << std::endl;
throw;
}
}
// Set TYPE
fFitType = opt;
// FIX,SHAPE,FREE
if (opt.find("FIX") != std::string::npos) {
fIsFree = fIsShape = false;
fIsFix = true;
} else if (opt.find("SHAPE") != std::string::npos) {
fIsFree = fIsFix = false;
fIsShape = true;
} else if (opt.find("FREE") != std::string::npos) {
fIsFix = fIsShape = false;
fIsFree = true;
}
// DIAG,FULL (or default to full)
if (opt.find("DIAG") != std::string::npos) {
fIsDiag = true;
fIsFull = false;
} else if (opt.find("FULL") != std::string::npos) {
fIsDiag = false;
fIsFull = true;
}
// CHI2/LL (OTHERS?)
if (opt.find("LOG") != std::string::npos) {
fIsChi2 = false;
ERR(FTL) << "No other LIKELIHOODS properly supported!" << std::endl;
ERR(FTL) << "Try to use a chi2!" << std::endl;
throw;
} else {
fIsChi2 = true;
}
// EXTRAS
if (opt.find("RAW") != std::string::npos) fIsRawEvents = true;
if (opt.find("DIF") != std::string::npos) fIsDifXSec = true;
if (opt.find("ENU1D") != std::string::npos) fIsEnu1D = true;
if (opt.find("NORM") != std::string::npos) fAddNormPen = true;
if (opt.find("MASK") != std::string::npos) fIsMask = true;
// Set TYPE
fFitType = opt;
// FIX,SHAPE,FREE
if (opt.find("FIX") != std::string::npos) {
fIsFree = fIsShape = false;
fIsFix = true;
} else if (opt.find("SHAPE") != std::string::npos) {
fIsFree = fIsFix = false;
fIsShape = true;
} else if (opt.find("FREE") != std::string::npos) {
fIsFix = fIsShape = false;
fIsFree = true;
}
// DIAG,FULL (or default to full)
if (opt.find("DIAG") != std::string::npos) {
fIsDiag = true;
fIsFull = false;
} else if (opt.find("FULL") != std::string::npos) {
fIsDiag = false;
fIsFull = true;
}
// CHI2/LL (OTHERS?)
if (opt.find("LOG") != std::string::npos)
fIsChi2 = false;
else
fIsChi2 = true;
// EXTRAS
if (opt.find("RAW") != std::string::npos) fIsRawEvents = true;
if (opt.find("DIF") != std::string::npos) fIsDifXSec = true;
if (opt.find("ENU1D") != std::string::npos) fIsEnu = true;
if (opt.find("NORM") != std::string::npos) fAddNormPen = true;
if (opt.find("MASK") != std::string::npos) fIsMask = true;
fIsProjFitX = (opt.find("FITPROJX") != std::string::npos);
fIsProjFitY = (opt.find("FITPROJY") != std::string::npos);
return;
};
/*
Reconfigure LOOP
*/
//********************************************************************
void Measurement2D::ResetAll() {
//********************************************************************
fMCHist->Reset();
fMCFine->Reset();
fMCStat->Reset();
return;
};
//********************************************************************
void Measurement2D::FillHistograms() {
//********************************************************************
if (Signal) {
fMCHist->Fill(fXVar, fYVar, Weight);
fMCFine->Fill(fXVar, fYVar, Weight);
fMCStat->Fill(fXVar, fYVar, 1.0);
if (fMCHist_Modes) fMCHist_Modes->Fill(Mode, fXVar, fYVar, Weight);
}
return;
};
//********************************************************************
void Measurement2D::ScaleEvents() {
//********************************************************************
// Fill MCWeighted;
// for (int i = 0; i < fMCHist->GetNbinsX(); i++) {
// fMCWeighted->SetBinContent(i + 1, fMCHist->GetBinContent(i + 1));
// fMCWeighted->SetBinError(i + 1, fMCHist->GetBinError(i + 1));
// }
// Setup Stat ratios for MC and MC Fine
double* statratio = new double[fMCHist->GetNbinsX()];
for (int i = 0; i < fMCHist->GetNbinsX(); i++) {
if (fMCHist->GetBinContent(i + 1) != 0) {
statratio[i] = fMCHist->GetBinError(i + 1) / fMCHist->GetBinContent(i + 1);
} else {
statratio[i] = 0.0;
}
}
double* statratiofine = new double[fMCFine->GetNbinsX()];
for (int i = 0; i < fMCFine->GetNbinsX(); i++) {
if (fMCFine->GetBinContent(i + 1) != 0) {
statratiofine[i] = fMCFine->GetBinError(i + 1) / fMCFine->GetBinContent(i + 1);
} else {
statratiofine[i] = 0.0;
}
}
// Scaling for raw event rates
if (fIsRawEvents) {
double datamcratio = fDataHist->Integral() / fMCHist->Integral();
fMCHist->Scale(datamcratio);
fMCFine->Scale(datamcratio);
if (fMCHist_Modes) fMCHist_Modes->Scale(datamcratio);
// Scaling for XSec as function of Enu
} else if (fIsEnu1D) {
PlotUtils::FluxUnfoldedScaling(fMCHist, GetFluxHistogram(),
GetEventHistogram(), fScaleFactor);
PlotUtils::FluxUnfoldedScaling(fMCFine, GetFluxHistogram(),
GetEventHistogram(), fScaleFactor);
// if (fMCHist_Modes) {
// PlotUtils::FluxUnfoldedScaling(fMCHist_Modes, GetFluxHistogram(),
// GetEventHistogram(), fScaleFactor,
// fNEvents);
// }
// Any other differential scaling
} else {
fMCHist->Scale(fScaleFactor, "width");
fMCFine->Scale(fScaleFactor, "width");
// if (fMCHist_Modes) fMCHist_Modes->Scale(fScaleFactor, "width");
}
// Proper error scaling - ROOT Freaks out with xsec weights sometimes
for (int i = 0; i < fMCStat->GetNbinsX(); i++) {
fMCHist->SetBinError(i + 1, fMCHist->GetBinContent(i + 1) * statratio[i]);
}
for (int i = 0; i < fMCFine->GetNbinsX(); i++) {
fMCFine->SetBinError(i + 1, fMCFine->GetBinContent(i + 1) * statratiofine[i]);
}
// Clean up
delete statratio;
delete statratiofine;
return;
};
//********************************************************************
void Measurement2D::ApplyNormScale(double norm) {
//********************************************************************
fCurrentNorm = norm;
fMCHist->Scale(1.0 / norm);
fMCFine->Scale(1.0 / norm);
return;
};
/*
Statistic Functions - Outsources to StatUtils
*/
//********************************************************************
int Measurement2D::GetNDOF() {
//********************************************************************
// Just incase it has gone...
if (!fDataHist) return -1;
int nDOF = 0;
// If datahist has no errors make sure we don't include those bins as they are
// not data points
for (int xBin = 0; xBin < fDataHist->GetNbinsX() + 1; ++xBin) {
for (int yBin = 0; yBin < fDataHist->GetNbinsY() + 1; ++yBin) {
if (fDataHist->GetBinError(xBin, yBin) != 0)
++nDOF;
}
}
// Account for possible bin masking
int nMasked = 0;
if (fMaskHist and fIsMask)
if (fMaskHist->Integral() > 0)
for (int xBin = 0; xBin < fMaskHist->GetNbinsX() + 1; ++xBin)
for (int yBin = 0; yBin < fMaskHist->GetNbinsY() + 1; ++yBin)
if (fMaskHist->GetBinContent(xBin, yBin) > 0.5) ++nMasked;
// Take away those masked DOF
if (fIsMask) {
nDOF -= nMasked;
}
return nDOF;
}
//********************************************************************
double Measurement2D::GetLikelihood() {
//********************************************************************
// If this is for a ratio, there is no data histogram to compare to!
if (fNoData || !fDataHist) return 0.;
// Fix weird masking bug
if (!fIsMask) {
if (fMaskHist) {
fMaskHist = NULL;
}
} else {
if (fMaskHist) {
PlotUtils::MaskBins(fMCHist, fMaskHist);
}
}
// if (fIsProjFitX or fIsProjFitY) return GetProjectedChi2();
// Scale up the results to match each other (Not using width might be
// inconsistent with Meas1D)
double scaleF = fDataHist->Integral() / fMCHist->Integral();
if (fIsShape) {
fMCHist->Scale(scaleF);
fMCFine->Scale(scaleF);
- PlotUtils::ScaleNeutModeArray((TH1**)fMCHist_PDG, scaleF);
+ //PlotUtils::ScaleNeutModeArray((TH1**)fMCHist_PDG, scaleF);
}
if (!fMapHist) {
fMapHist = StatUtils::GenerateMap(fDataHist);
}
// Get the chi2 from either covar or diagonals
double chi2 = 0.0;
if (fIsChi2) {
if (fIsDiag) {
chi2 =
StatUtils::GetChi2FromDiag(fDataHist, fMCHist, fMapHist, fMaskHist);
} else {
chi2 = StatUtils::GetChi2FromCov(fDataHist, fMCHist, covar, fMapHist,
fMaskHist);
}
}
// Add a normal penalty term
if (fAddNormPen) {
chi2 +=
(1 - (fCurrentNorm)) * (1 - (fCurrentNorm)) / (fNormError * fNormError);
LOG(REC) << "Norm penalty = "
<< (1 - (fCurrentNorm)) * (1 - (fCurrentNorm)) /
(fNormError * fNormError)
<< std::endl;
}
// Adjust the shape back to where it was.
if (fIsShape and !FitPar::Config().GetParB("saveshapescaling")) {
fMCHist->Scale(1. / scaleF);
fMCFine->Scale(1. / scaleF);
}
fLikelihood = chi2;
return chi2;
}
/*
Fake Data Functions
*/
//********************************************************************
void Measurement2D::SetFakeDataValues(std::string fakeOption) {
//********************************************************************
// Setup original/datatrue
TH2D* tempdata = (TH2D*) fDataHist->Clone();
if (!fIsFakeData) {
fIsFakeData = true;
// Make a copy of the original data histogram.
if (!fDataOrig) fDataOrig = (TH2D*)fDataHist->Clone((fName + "_data_original").c_str());
} else {
ResetFakeData();
}
// Setup Inputs
fFakeDataInput = fakeOption;
LOG(SAM) << "Setting fake data from : " << fFakeDataInput << std::endl;
// From MC
if (fFakeDataInput.compare("MC") == 0) {
fDataHist = (TH2D*)fMCHist->Clone((fName + "_MC").c_str());
// Fake File
} else {
if (!fFakeDataFile) fFakeDataFile = new TFile(fFakeDataInput.c_str(), "READ");
fDataHist = (TH2D*)fFakeDataFile->Get((fName + "_MC").c_str());
}
// Setup Data Hist
fDataHist->SetNameTitle((fName + "_FAKE").c_str(),
(fName + fPlotTitles).c_str());
// Replace Data True
if (fDataTrue) delete fDataTrue;
fDataTrue = (TH2D*)fDataHist->Clone();
fDataTrue->SetNameTitle((fName + "_FAKE_TRUE").c_str(),
(fName + fPlotTitles).c_str());
// Make a new covariance for fake data hist.
int nbins = fDataHist->GetNbinsX() * fDataHist->GetNbinsY();
double alpha_i = 0.0;
double alpha_j = 0.0;
for (int i = 0; i < nbins; i++) {
for (int j = 0; j < nbins; j++) {
if (tempdata->GetBinContent(i + 1) && tempdata->GetBinContent(j + 1)) {
alpha_i = fDataHist->GetBinContent(i + 1) / tempdata->GetBinContent(i + 1);
alpha_j = fDataHist->GetBinContent(j + 1) / tempdata->GetBinContent(j + 1);
} else {
alpha_i = 0.0;
alpha_j = 0.0;
}
(*fFullCovar)(i, j) = alpha_i * alpha_j * (*fFullCovar)(i, j);
}
}
// Setup Covariances
if (covar) delete covar;
covar = StatUtils::GetInvert(fFullCovar);
if (fDecomp) delete fDecomp;
fDecomp = StatUtils::GetInvert(fFullCovar);
delete tempdata;
return;
};
//********************************************************************
void Measurement2D::ResetFakeData() {
//********************************************************************
if (fIsFakeData) {
if (fDataHist) delete fDataHist;
fDataHist = (TH2D*)fDataTrue->Clone((fSettings.GetName() + "_FKDAT").c_str());
}
}
//********************************************************************
void Measurement2D::ResetData() {
//********************************************************************
if (fIsFakeData) {
if (fDataHist) delete fDataHist;
fDataHist = (TH2D*)fDataOrig->Clone((fSettings.GetName() + "_data").c_str());
}
fIsFakeData = false;
}
//********************************************************************
void Measurement2D::ThrowCovariance() {
//********************************************************************
// Take a fDecomposition and use it to throw the current dataset.
// Requires fDataTrue also be set incase used repeatedly.
if (fDataHist) delete fDataHist;
fDataHist = StatUtils::ThrowHistogram(fDataTrue, fFullCovar);
return;
};
//********************************************************************
void Measurement2D::ThrowDataToy() {
//********************************************************************
if (!fDataTrue) fDataTrue = (TH2D*) fDataHist->Clone();
if (fMCHist) delete fMCHist;
fMCHist = StatUtils::ThrowHistogram(fDataTrue, fFullCovar);
}
/*
Access Functions
*/
//********************************************************************
TH2D* Measurement2D::GetMCHistogram() {
//********************************************************************
if (!fMCHist) return fMCHist;
std::ostringstream chi2;
chi2 << std::setprecision(5) << this->GetLikelihood();
int linecolor = kRed;
int linestyle = 1;
int linewidth = 1;
int fillcolor = 0;
int fillstyle = 1001;
if (fSettings.Has("linecolor")) linecolor = fSettings.GetI("linecolor");
if (fSettings.Has("linestyle")) linestyle = fSettings.GetI("linestyle");
if (fSettings.Has("linewidth")) linewidth = fSettings.GetI("linewidth");
if (fSettings.Has("fillcolor")) fillcolor = fSettings.GetI("fillcolor");
if (fSettings.Has("fillstyle")) fillstyle = fSettings.GetI("fillstyle");
fMCHist->SetTitle(chi2.str().c_str());
fMCHist->SetLineColor(linecolor);
fMCHist->SetLineStyle(linestyle);
fMCHist->SetLineWidth(linewidth);
fMCHist->SetFillColor(fillcolor);
fMCHist->SetFillStyle(fillstyle);
return fMCHist;
};
//********************************************************************
TH2D* Measurement2D::GetDataHistogram() {
//********************************************************************
if (!fDataHist) return fDataHist;
int datacolor = kBlack;
int datastyle = 1;
int datawidth = 1;
if (fSettings.Has("datacolor")) datacolor = fSettings.GetI("datacolor");
if (fSettings.Has("datastyle")) datastyle = fSettings.GetI("datastyle");
if (fSettings.Has("datawidth")) datawidth = fSettings.GetI("datawidth");
fDataHist->SetLineColor(datacolor);
fDataHist->SetLineWidth(datawidth);
fDataHist->SetMarkerStyle(datastyle);
return fDataHist;
};
/*
Write Functions
*/
// Save all the histograms at once
//********************************************************************
void Measurement2D::Write(std::string drawOpt) {
//********************************************************************
// Get Draw Options
drawOpt = FitPar::Config().GetParS("drawopts");
// Write Settigns
if (drawOpt.find("SETTINGS") != std::string::npos) {
fSettings.Set("#chi^{2}", fLikelihood);
fSettings.Set("NDOF", this->GetNDOF() );
fSettings.Set("#chi^{2}/NDOF", fLikelihood / this->GetNDOF() );
fSettings.Write();
}
// Write Data/MC
GetDataList().at(0)->Write();
GetMCList().at(0)->Write();
// Write Fine Histogram
if (drawOpt.find("FINE") != std::string::npos)
GetFineList().at(0)->Write();
// Write Weighted Histogram
if (drawOpt.find("WEIGHTS") != std::string::npos && fMCWeighted)
fMCWeighted->Write();
// Save Flux/Evt if no event manager
if (!FitPar::Config().GetParB("EventManager")) {
if (drawOpt.find("FLUX") != std::string::npos && GetFluxHistogram())
GetFluxHistogram()->Write();
if (drawOpt.find("EVT") != std::string::npos && GetEventHistogram())
GetEventHistogram()->Write();
if (drawOpt.find("XSEC") != std::string::npos && GetEventHistogram())
GetEventHistogram()->Write();
}
// Write Mask
if (fIsMask && (drawOpt.find("MASK") != std::string::npos)) {
fMaskHist->Write();
}
// Write Covariances
if (drawOpt.find("COV") != std::string::npos && fFullCovar) {
PlotUtils::GetFullCovarPlot(fFullCovar, fSettings.GetName());
}
if (drawOpt.find("INVCOV") != std::string::npos && covar) {
PlotUtils::GetInvCovarPlot(covar, fSettings.GetName());
}
if (drawOpt.find("DECOMP") != std::string::npos && fDecomp) {
PlotUtils::GetDecompCovarPlot(fDecomp, fSettings.GetName());
}
// // Likelihood residual plots
// if (drawOpt.find("RESIDUAL") != std::string::npos) {
// WriteResidualPlots();
// }
// // RATIO
// if (drawOpt.find("CANVMC") != std::string::npos) {
// TCanvas* c1 = WriteMCCanvas(fDataHist, fMCHist);
// c1->Write();
// delete c1;
// }
// // PDG
// if (drawOpt.find("CANVPDG") != std::string::npos && fMCHist_Modes) {
// TCanvas* c2 = WritePDGCanvas(fDataHist, fMCHist, fMCHist_Modes);
// c2->Write();
// delete c2;
// }
// Write Extra Histograms
AutoWriteExtraTH1();
WriteExtraHistograms();
/// 2D VERSION
// If null pointer return
if (!fMCHist and !fDataHist) {
LOG(SAM) << fName << "Incomplete histogram set!" << std::endl;
return;
}
// FitPar::Config().out->cd();
// Get Draw Options
drawOpt = FitPar::Config().GetParS("drawopts");
bool drawData = (drawOpt.find("DATA") != std::string::npos);
bool drawNormal = (drawOpt.find("MC") != std::string::npos);
bool drawEvents = (drawOpt.find("EVT") != std::string::npos);
bool drawXSec = (drawOpt.find("XSEC") != std::string::npos);
bool drawFine = (drawOpt.find("FINE") != std::string::npos);
bool drawRatio = (drawOpt.find("RATIO") != std::string::npos);
// bool drawModes = (drawOpt.find("MODES") != std::string::npos);
bool drawShape = (drawOpt.find("SHAPE") != std::string::npos);
bool residual = (drawOpt.find("RESIDUAL") != std::string::npos);
bool drawMatrix = (drawOpt.find("MATRIX") != std::string::npos);
bool drawFlux = (drawOpt.find("FLUX") != std::string::npos);
bool drawMask = (drawOpt.find("MASK") != std::string::npos);
bool drawMap = (drawOpt.find("MAP") != std::string::npos);
bool drawProj = (drawOpt.find("PROJ") != std::string::npos);
// bool drawCanvPDG = (drawOpt.find("CANVPDG") != std::string::npos);
bool drawCov = (drawOpt.find("COV") != std::string::npos);
bool drawSliceCanvYMC = (drawOpt.find("CANVYMC") != std::string::npos);
bool drawWeighted = (drawOpt.find("WGHT") != std::string::npos);
if (FitPar::Config().GetParB("EventManager")) {
drawFlux = false;
drawXSec = false;
drawEvents = false;
}
if (fMaskHist) fMaskHist->Write();
// Save standard plots
if (drawData) this->GetDataList().at(0)->Write();
if (drawNormal) this->GetMCList().at(0)->Write();
if (drawCov) {
TH2D(*fFullCovar).Write((fName + "_COV").c_str());
}
if (drawOpt.find("INVCOV") != std::string::npos) {
TH2D(*covar).Write((fName + "_INVCOV").c_str());
}
// Generate a simple map
if (!fMapHist) fMapHist = StatUtils::GenerateMap(fDataHist);
// Convert to 1D Lists
TH1D* data_1D = StatUtils::MapToTH1D(fDataHist, fMapHist);
TH1D* mc_1D = StatUtils::MapToTH1D(fMCHist, fMapHist);
TH1I* mask_1D = StatUtils::MapToMask(fMaskHist, fMapHist);
data_1D->Write();
mc_1D->Write();
if (mask_1D) {
mask_1D->Write();
TMatrixDSym* calc_cov =
StatUtils::ApplyInvertedMatrixMasking(covar, mask_1D);
TH1D* calc_data = StatUtils::ApplyHistogramMasking(data_1D, mask_1D);
TH1D* calc_mc = StatUtils::ApplyHistogramMasking(mc_1D, mask_1D);
TH2D* bin_cov = new TH2D(*calc_cov);
bin_cov->Write();
calc_data->Write();
calc_mc->Write();
delete mask_1D;
delete calc_cov;
delete calc_data;
delete calc_mc;
delete bin_cov;
}
delete data_1D;
delete mc_1D;
// Save only mc and data if splines
if (fEventType == 4 or fEventType == 3) {
return;
}
// Draw Extra plots
if (drawFine) this->GetFineList().at(0)->Write();
if (drawFlux and GetFluxHistogram()) {
GetFluxHistogram()->Write();
}
if (drawEvents and GetEventHistogram()) {
GetEventHistogram()->Write();
}
if (fIsMask and drawMask) {
fMaskHist->Write((fName + "_MSK").c_str()); //< save mask
}
if (drawMap) fMapHist->Write((fName + "_MAP").c_str()); //< save map
// // Save neut stack
// if (drawModes) {
// THStack combo_fMCHist_PDG = PlotUtils::GetNeutModeStack(
// (fName + "_MC_PDG").c_str(), (TH1**)fMCHist_PDG, 0);
// combo_fMCHist_PDG.Write();
// }
// Save Matrix plots
if (drawMatrix and fFullCovar and covar and fDecomp) {
TH2D cov = TH2D((*fFullCovar));
cov.SetNameTitle((fName + "_cov").c_str(),
(fName + "_cov;Bins; Bins;").c_str());
cov.Write();
TH2D covinv = TH2D((*this->covar));
covinv.SetNameTitle((fName + "_covinv").c_str(),
(fName + "_cov;Bins; Bins;").c_str());
covinv.Write();
TH2D covdec = TH2D((*fDecomp));
covdec.SetNameTitle((fName + "_covdec").c_str(),
(fName + "_cov;Bins; Bins;").c_str());
covdec.Write();
}
// Save ratio plots if required
if (drawRatio) {
// Needed for error bars
for (int i = 0; i < fMCHist->GetNbinsX() * fMCHist->GetNbinsY(); i++)
fMCHist->SetBinError(i + 1, 0.0);
fDataHist->GetSumw2();
fMCHist->GetSumw2();
// Create Ratio Histograms
TH2D* dataRatio = (TH2D*)fDataHist->Clone((fName + "_data_RATIO").c_str());
TH2D* mcRatio = (TH2D*)fMCHist->Clone((fName + "_MC_RATIO").c_str());
mcRatio->Divide(fMCHist);
dataRatio->Divide(fMCHist);
// Cancel bin errors on MC
for (int i = 0; i < mcRatio->GetNbinsX() * mcRatio->GetNbinsY(); i++) {
mcRatio->SetBinError(
i + 1, fMCHist->GetBinError(i + 1) / fMCHist->GetBinContent(i + 1));
}
mcRatio->SetMinimum(0);
mcRatio->SetMaximum(2);
dataRatio->SetMinimum(0);
dataRatio->SetMaximum(2);
mcRatio->Write();
dataRatio->Write();
delete mcRatio;
delete dataRatio;
}
// Save Shape Plots if required
if (drawShape) {
// Create Shape Histogram
TH2D* mcShape = (TH2D*)fMCHist->Clone((fName + "_MC_SHAPE").c_str());
double shapeScale = 1.0;
if (fIsRawEvents) {
shapeScale = fDataHist->Integral() / fMCHist->Integral();
} else {
shapeScale = fDataHist->Integral("width") / fMCHist->Integral("width");
}
mcShape->Scale(shapeScale);
mcShape->SetLineWidth(3);
mcShape->SetLineStyle(7); // dashes
mcShape->Write();
// Save shape ratios
if (drawRatio) {
// Needed for error bars
mcShape->GetSumw2();
// Create shape ratio histograms
TH2D* mcShapeRatio =
(TH2D*)mcShape->Clone((fName + "_MC_SHAPE_RATIO").c_str());
TH2D* dataShapeRatio =
(TH2D*)fDataHist->Clone((fName + "_data_SHAPE_RATIO").c_str());
// Divide the histograms
mcShapeRatio->Divide(mcShape);
dataShapeRatio->Divide(mcShape);
// Colour the shape ratio plots
mcShapeRatio->SetLineWidth(3);
mcShapeRatio->SetLineStyle(7); // dashes
mcShapeRatio->Write();
dataShapeRatio->Write();
delete mcShapeRatio;
delete dataShapeRatio;
}
delete mcShape;
}
// Save residual calculations of what contributed to the chi2 values.
if (residual) {
}
if (fIsProjFitX or fIsProjFitY or drawProj) {
// If not already made, make the projections
if (!fMCHist_X) {
PlotUtils::MatchEmptyBins(fDataHist, fMCHist);
fMCHist_X = PlotUtils::GetProjectionX(fMCHist, fMaskHist);
fMCHist_Y = PlotUtils::GetProjectionY(fMCHist, fMaskHist);
fDataHist_X = PlotUtils::GetProjectionX(fDataHist, fMaskHist);
fDataHist_Y = PlotUtils::GetProjectionY(fDataHist, fMaskHist);
double chi2X = StatUtils::GetChi2FromDiag(fDataHist_X, fMCHist_X);
double chi2Y = StatUtils::GetChi2FromDiag(fDataHist_Y, fMCHist_Y);
fMCHist_X->SetTitle(Form("%f", chi2X));
fMCHist_Y->SetTitle(Form("%f", chi2Y));
}
// Save the histograms
fDataHist_X->Write();
fMCHist_X->Write();
fDataHist_Y->Write();
fMCHist_Y->Write();
}
if (drawSliceCanvYMC or true) {
TCanvas* c1 = new TCanvas((fName + "_MC_CANV_Y").c_str(),
(fName + "_MC_CANV_Y").c_str(), 800, 600);
c1->Divide(int(sqrt(fDataHist->GetNbinsY() + 1)),
int(sqrt(fDataHist->GetNbinsY() + 1)));
TH2D* mcShape = (TH2D*)fMCHist->Clone((fName + "_MC_SHAPE").c_str());
double shapeScale =
fDataHist->Integral("width") / fMCHist->Integral("width");
mcShape->Scale(shapeScale);
mcShape->SetLineStyle(7);
c1->cd(1);
TLegend* leg = new TLegend(0.6, 0.6, 0.9, 0.9);
leg->AddEntry(fDataHist, (fName + " Data").c_str(), "ep");
leg->AddEntry(fMCHist, (fName + " MC").c_str(), "l");
leg->AddEntry(mcShape, (fName + " Shape").c_str(), "l");
leg->Draw("SAME");
/*
// Make Y slices
for (int i = 0; i < fDataHist->GetNbinY(); i++){
c1->cd(i+2);
TH1D* fDataHist_SliceY = PlotUtils::GetSliceY(fDataHist, i);
fDataHist_SliceY->Draw("E1");
TH1D* fMCHist_SliceY = PlotUtils::GetSliceY(fMCHist, i);
fMCHist_SliceY->Draw("SAME HIST C");
TH1D* mcShape_SliceY = PlotUtils::GetSliceY(mcShape, i);
mcShape_SliceY->Draw("SAME HIST C");
}
*/
c1->Write();
}
if (drawWeighted) {
fMCWeighted->Write();
}
// Returning
LOG(SAM) << "Written Histograms: " << fName << std::endl;
return;
// Returning
LOG(SAM) << "Written Histograms: " << fName << std::endl;
return;
}
/*
Setup Functions
*/
//********************************************************************
void Measurement2D::SetupMeasurement(std::string inputfile, std::string type,
FitWeight* rw, std::string fkdt) {
//********************************************************************
// Check if name contains Evt, indicating that it is a raw number of events
// measurements and should thus be treated as once
fIsRawEvents = false;
if ((fName.find("Evt") != std::string::npos) && fIsRawEvents == false) {
fIsRawEvents = true;
LOG(SAM) << "Found event rate measurement but fIsRawEvents == false!"
<< std::endl;
LOG(SAM) << "Overriding this and setting fIsRawEvents == true!"
<< std::endl;
}
fIsEnu = false;
if ((fName.find("XSec") != std::string::npos) &&
(fName.find("Enu") != std::string::npos)) {
fIsEnu = true;
LOG(SAM) << "::" << fName << "::" << std::endl;
LOG(SAM) << "Found XSec Enu measurement, applying flux integrated scaling, "
"not flux averaged!"
<< std::endl;
if (FitPar::Config().GetParB("EventManager")) {
ERR(FTL) << "Enu Measurements do not yet work with the Event Manager!"
<< std::endl;
ERR(FTL) << "If you want decent flux unfolded results please run in "
"series mode (-q EventManager=0)"
<< std::endl;
sleep(2);
}
}
if (fIsEnu && fIsRawEvents) {
LOG(SAM) << "Found 1D Enu XSec distribution AND fIsRawEvents, is this "
"really correct?!"
<< std::endl;
LOG(SAM) << "Check experiment constructor for " << fName
<< " and correct this!" << std::endl;
LOG(SAM) << "I live in " << __FILE__ << ":" << __LINE__ << std::endl;
exit(-1);
}
// Reset everything to NULL
fRW = rw;
// Setting up 2D Inputs
this->SetupInputs(inputfile);
// Set Default Options
SetFitOptions(fDefaultTypes);
// Set Passed Options
SetFitOptions(type);
}
//********************************************************************
void Measurement2D::SetupDefaultHist() {
//********************************************************************
// Setup fMCHist
fMCHist = (TH2D*)fDataHist->Clone();
fMCHist->SetNameTitle((fName + "_MC").c_str(),
(fName + "_MC" + fPlotTitles).c_str());
// Setup fMCFine
Int_t nBinsX = fMCHist->GetNbinsX();
Int_t nBinsY = fMCHist->GetNbinsY();
fMCFine = new TH2D((fName + "_MC_FINE").c_str(),
(fName + "_MC_FINE" + fPlotTitles).c_str(), nBinsX * 3,
fMCHist->GetXaxis()->GetBinLowEdge(1),
fMCHist->GetXaxis()->GetBinLowEdge(nBinsX + 1), nBinsY * 3,
fMCHist->GetYaxis()->GetBinLowEdge(1),
fMCHist->GetYaxis()->GetBinLowEdge(nBinsY + 1));
// Setup MC Stat
fMCStat = (TH2D*)fMCHist->Clone();
fMCStat->Reset();
// Setup the NEUT Mode Array
- PlotUtils::CreateNeutModeArray(fMCHist, (TH1**)fMCHist_PDG);
+ //PlotUtils::CreateNeutModeArray(fMCHist, (TH1**)fMCHist_PDG);
// Setup bin masks using sample name
if (fIsMask) {
std::string maskloc = FitPar::Config().GetParDIR(fName + ".mask");
if (maskloc.empty()) {
maskloc = FitPar::GetDataBase() + "/masks/" + fName + ".mask";
}
SetBinMask(maskloc);
}
return;
}
//********************************************************************
void Measurement2D::SetDataValues(std::string dataFile, std::string TH2Dname) {
//********************************************************************
if (dataFile.find(".root") == std::string::npos) {
ERR(FTL) << "Error! " << dataFile << " is not a .root file" << std::endl;
ERR(FTL) << "Currently only .root file reading is supported (MiniBooNE "
"CC1pi+ 2D), but implementing .txt should be dirt easy"
<< std::endl;
ERR(FTL) << "See me at " << __FILE__ << ":" << __LINE__ << std::endl;
exit(-1);
} else {
TFile* inFile = new TFile(dataFile.c_str(), "READ");
fDataHist = (TH2D*)(inFile->Get(TH2Dname.c_str())->Clone());
fDataHist->SetDirectory(0);
fDataHist->SetNameTitle((fName + "_data").c_str(),
(fName + "_MC" + fPlotTitles).c_str());
delete inFile;
}
return;
}
//********************************************************************
void Measurement2D::SetDataValues(std::string dataFile, double dataNorm,
std::string errorFile, double errorNorm) {
//********************************************************************
// Make a counter to track the line number
int yBin = 0;
std::string line;
std::ifstream data(dataFile.c_str(), ifstream::in);
fDataHist = new TH2D((fName + "_data").c_str(), (fName + fPlotTitles).c_str(),
fNDataPointsX - 1, fXBins, fNDataPointsY - 1, fYBins);
if (data.is_open())
LOG(SAM) << "Reading data from: " << dataFile.c_str() << std::endl;
while (std::getline(data >> std::ws, line, '\n')) {
int xBin = 0;
// Loop over entries and insert them into the histogram
std::vector entries = GeneralUtils::ParseToDbl(line, " ");
for (std::vector::iterator iter = entries.begin();
iter != entries.end(); iter++) {
fDataHist->SetBinContent(xBin + 1, yBin + 1, (*iter) * dataNorm);
xBin++;
}
yBin++;
}
yBin = 0;
std::ifstream error(errorFile.c_str(), ifstream::in);
if (error.is_open())
LOG(SAM) << "Reading errors from: " << errorFile.c_str() << std::endl;
while (std::getline(error >> std::ws, line, '\n')) {
int xBin = 0;
// Loop over entries and insert them into the histogram
std::vector entries = GeneralUtils::ParseToDbl(line, " ");
for (std::vector::iterator iter = entries.begin();
iter != entries.end(); iter++) {
fDataHist->SetBinError(xBin + 1, yBin + 1, (*iter) * errorNorm);
xBin++;
}
yBin++;
}
return;
};
//********************************************************************
void Measurement2D::SetDataValuesFromText(std::string dataFile,
double dataNorm) {
//********************************************************************
fDataHist = new TH2D((fName + "_data").c_str(), (fName + fPlotTitles).c_str(),
fNDataPointsX - 1, fXBins, fNDataPointsY - 1, fYBins);
LOG(SAM) << "Reading data from: " << dataFile << std::endl;
PlotUtils::Set2DHistFromText(dataFile, fDataHist, dataNorm, true);
return;
};
//********************************************************************
void Measurement2D::SetCovarMatrix(std::string covarFile) {
//********************************************************************
// Used to read a covariance matrix from a root file
TFile* tempFile = new TFile(covarFile.c_str(), "READ");
// Make plots that we want
TH2D* covarPlot = new TH2D();
// TH2D* decmpPlot = new TH2D();
TH2D* covarInvPlot = new TH2D();
TH2D* fFullCovarPlot = new TH2D();
// Get covariance options for fake data studies
std::string covName = "";
std::string covOption = FitPar::Config().GetParS("throw_covariance");
// Which matrix to get?
if (fIsShape || fIsFree) covName = "shp_";
if (fIsDiag)
covName += "diag";
else
covName += "full";
covarPlot = (TH2D*)tempFile->Get((covName + "cov").c_str());
covarInvPlot = (TH2D*)tempFile->Get((covName + "covinv").c_str());
// Throw either the sub matrix or the full matrix
if (!covOption.compare("SUB"))
fFullCovarPlot = (TH2D*)tempFile->Get((covName + "cov").c_str());
else if (!covOption.compare("FULL"))
fFullCovarPlot = (TH2D*)tempFile->Get("fullcov");
else
ERR(WRN) << " Incorrect thrown_covariance option in parameters."
<< std::endl;
// Bin masking?
int dim = int(fDataHist->GetNbinsX()); //-this->masked->Integral());
int covdim = int(fDataHist->GetNbinsX());
// Make new covars
this->covar = new TMatrixDSym(dim);
fFullCovar = new TMatrixDSym(dim);
fDecomp = new TMatrixDSym(dim);
// Full covariance values
int row, column = 0;
row = 0;
column = 0;
for (Int_t i = 0; i < covdim; i++) {
// masking can be dodgy
// if (this->masked->GetBinContent(i+1) > 0) continue;
for (Int_t j = 0; j < covdim; j++) {
// if (this->masked->GetBinContent(j+1) > 0) continue;
(*this->covar)(row, column) = covarPlot->GetBinContent(i + 1, j + 1);
(*fFullCovar)(row, column) = fFullCovarPlot->GetBinContent(i + 1, j + 1);
column++;
}
column = 0;
row++;
}
// Set bin errors on data
if (!fIsDiag) {
for (Int_t i = 0; i < fDataHist->GetNbinsX(); i++) {
fDataHist->SetBinError(
i + 1, sqrt((covarPlot->GetBinContent(i + 1, i + 1))) * 1E-38);
}
}
TDecompSVD LU = TDecompSVD(*this->covar);
this->covar = new TMatrixDSym(dim, LU.Invert().GetMatrixArray(), "");
tempFile->Close();
delete tempFile;
return;
};
//********************************************************************
void Measurement2D::SetCovarMatrixFromText(std::string covarFile, int dim) {
//********************************************************************
// Make a counter to track the line number
int row = 0;
std::string line;
std::ifstream covar(covarFile.c_str(), ifstream::in);
this->covar = new TMatrixDSym(dim);
fFullCovar = new TMatrixDSym(dim);
if (covar.is_open())
LOG(SAM) << "Reading covariance matrix from file: " << covarFile
<< std::endl;
while (std::getline(covar >> std::ws, line, '\n')) {
int column = 0;
// Loop over entries and insert them into matrix
// Multiply by the errors to get the covariance, rather than the correlation
// matrix
std::vector entries = GeneralUtils::ParseToDbl(line, " ");
for (std::vector::iterator iter = entries.begin();
iter != entries.end(); iter++) {
double val = (*iter) * fDataHist->GetBinError(row + 1) * 1E38 *
fDataHist->GetBinError(column + 1) * 1E38;
(*this->covar)(row, column) = val;
(*fFullCovar)(row, column) = val;
column++;
}
row++;
}
// Robust matrix inversion method
TDecompSVD LU = TDecompSVD(*this->covar);
this->covar = new TMatrixDSym(dim, LU.Invert().GetMatrixArray(), "");
return;
};
//********************************************************************
void Measurement2D::SetCovarMatrixFromChol(std::string covarFile, int dim) {
//********************************************************************
// Make a counter to track the line number
int row = 0;
std::string line;
std::ifstream covarread(covarFile.c_str(), ifstream::in);
TMatrixD* newcov = new TMatrixD(dim, dim);
if (covarread.is_open())
LOG(SAM) << "Reading covariance matrix from file: " << covarFile
<< std::endl;
while (std::getline(covarread >> std::ws, line, '\n')) {
int column = 0;
// Loop over entries and insert them into matrix
// Multiply by the errors to get the covariance, rather than the correlation
// matrix
std::vector entries = GeneralUtils::ParseToDbl(line, " ");
for (std::vector::iterator iter = entries.begin();
iter != entries.end(); iter++) {
(*newcov)(row, column) = *iter;
column++;
}
row++;
}
covarread.close();
// Form full covariance
TMatrixD* trans = (TMatrixD*)(newcov)->Clone();
trans->T();
(*trans) *= (*newcov);
fFullCovar = new TMatrixDSym(dim, trans->GetMatrixArray(), "");
delete newcov;
delete trans;
// Robust matrix inversion method
TDecompChol LU = TDecompChol(*this->fFullCovar);
this->covar = new TMatrixDSym(dim, LU.Invert().GetMatrixArray(), "");
return;
};
// //********************************************************************
// void Measurement2D::SetMapValuesFromText(std::string dataFile) {
// //********************************************************************
// fMapHist = new TH2I((fName + "_map").c_str(), (fName + fPlotTitles).c_str(),
// fNDataPointsX - 1, fXBins, fNDataPointsY - 1, fYBins);
// LOG(SAM) << "Reading map from: " << dataFile << std::endl;
// PlotUtils::Set2DHistFromText(dataFile, fMapHist, 1.0);
// return;
// };