PP2HAnalysis.cc
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PP2HAnalysis.cc
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	// -- C++ --
	//
	// This is the implementation of the non-inlined, non-templated member
	// functions of the PP2HAnalysis class.
	//

	#include "PP2HAnalysis.h"
	#include "ThePEG/Interface/Reference.h"
	#include "ThePEG/Interface/Parameter.h"
	#include "ThePEG/EventRecord/Particle.h"
	#include "ThePEG/EventRecord/Event.h"
	#include "ThePEG/PDT/EnumParticles.h"
	#include "ThePEG/PDT/ParticleData.h"
	#include "ThePEG/PDF/BeamParticleData.h"
	#include "ThePEG/Interface/ClassDocumentation.h"
	#include "ThePEG/Persistency/PersistentOStream.h"
	#include "ThePEG/Persistency/PersistentIStream.h"
	#include "Herwig++/Utilities/Histogram.h"


	using namespace Herwig;
	using namespace ThePEG;
	using namespace std;

	Histogram pt_30( 0., 30.,50);
	Histogram pt_200( 0.,200.,50);
	Histogram pt_400( 0.,400.,50);
	Histogram Yjet_10( -5.,5.,50);
	Histogram YjetYH_10( -5.,5.,50);
	Histogram Yjet_40( -5.,5.,50);
	Histogram YjetYH_40( -5.,5.,50);
	Histogram Yjet_80( -5.,5.,50);
	Histogram YjetYH_80( -5.,5.,50);
	Histogram Yjet_10A( -5.,5.,50);
	Histogram YjetYH_10A(-5.,5.,50);
	Histogram Yjet_40A( -5.,5.,50);
	Histogram YjetYH_40A(-5.,5.,50);
	Histogram Yjet_80A( -5.,5.,50);
	Histogram YjetYH_80A(-5.,5.,50);
	Histogram Njets_10(0.,10.,10);
	Histogram Njets_40(0.,10.,10);
	Histogram Njets_80(0.,10.,10);
	Histogram log_y23(-14.,-4.,100);
	Histogram log_y34(-14.,-4.,100);
	Histogram log_y45(-14.,-4.,100);
	Histogram cosjet(-1.,1.,50);
	Histogram cosjet_lt_10(-1.,1.,50);
	Histogram cosjet_lt_30(-1.,1.,50);
	Histogram cosjet_lt_100(-1.,1.,50);
	Histogram cosjet_gt_10(-1.,1.,50);
	Histogram cosjet_gt_30(-1.,1.,50);
	Histogram cosjet_gt_100(-1.,1.,50);
	Histogram cosjet_w(-0.5,0.5,50);
	Histogram cosjet_lt_10_w(-0.5,0.5,50);
	Histogram cosjet_lt_30_w(-0.5,0.5,50);
	Histogram cosjet_lt_100_w(-0.5,0.5,50);
	Histogram cosjet_gt_10_w(-0.5,0.5,50);
	Histogram cosjet_gt_30_w(-0.5,0.5,50);
	Histogram cosjet_gt_100_w(-0.5,0.5,50);
	Histogram cos1st(-1.,1.,50);
	Histogram cos1st_lt_10(-1.,1.,50);
	Histogram cos1st_lt_30(-1.,1.,50);
	Histogram cos1st_lt_100(-1.,1.,50);
	Histogram cos1st_gt_10(-1.,1.,50);
	Histogram cos1st_gt_30(-1.,1.,50);
	Histogram cos1st_gt_100(-1.,1.,50);
	Histogram cos1st_w(-0.5,0.5,50);
	Histogram cos1st_lt_10_w(-0.5,0.5,50);
	Histogram cos1st_lt_30_w(-0.5,0.5,50);
	Histogram cos1st_lt_100_w(-0.5,0.5,50);
	Histogram cos1st_gt_10_w(-0.5,0.5,50);
	Histogram cos1st_gt_30_w(-0.5,0.5,50);
	Histogram cos1st_gt_100_w(-0.5,0.5,50);

	void PP2HAnalysis::persistentOutput(PersistentOStream & os) const {
	// * ATTENTION * os << ; // Add all member variable which should be written persistently here.
	}

	void PP2HAnalysis::persistentInput(PersistentIStream & is, int) {
	// * ATTENTION * is >> ; // Add all member variable which should be read persistently here.
	}

	ClassDescription<PP2HAnalysis> PP2HAnalysis::initPP2HAnalysis;
	// Definition of the static class description member.

	void PP2HAnalysis::Init() {

	static ClassDocumentation<PP2HAnalysis> documentation
	("There is no documentation for the PP2HAnalysis class");

	}

	void PP2HAnalysis::analyze(tEventPtr event, long ieve, int loop, int state) {

	// Store all of the final state particles as particles.
	particles=event->getFinalState();
	// Extract the emitted parton
	tPVector::iterator pit;
	int Higgses(0);
	for(pit=particles.begin();pit!=particles.end();++pit) {
	if((*pit)->id()==25) {
	Higgs = *pit;
	particles.erase(pit); // Delete the Higgs so it is not clustered
	Higgses++;
	}
	}
	if(Higgses>1\|\|Higgses==0)
	throw Exception() << "PP2HAnalysis::analyze"
	<< "\nMore / less than one Higgs in the final state"
	<< "\nNumberof Higgses is " << Higgses
	<< Exception::warning;

	//-----------------------//
	// //
	// pT Spectrum analysis //
	// //
	//-----------------------//
	Energy pTh = Higgs->momentum().perp();
	pt_30.addWeighted( pTh/GeV,1.);
	pt_200.addWeighted(pTh/GeV,1.);
	pt_400.addWeighted(pTh/GeV,1.);

	//-----------------------//
	// //
	// Jet Rapidity analysis //
	// //
	//-----------------------//
	_kint.clearMap();
	KtJet::KtEvent ev = KtJet::KtEvent(_kint.convert(particles),4,2,1,0.7);
	// Get the two jets ordered by their Pt (largest Pt is first).
	vector<KtJet::KtLorentzVector> ktjets = ev.getJetsPt();
	if( ktjets.size()>0
	&& Higgs
	&& abs(ktjets[0].t())!=abs(ktjets[0].z())
	&& abs(Higgs->momentum().t())!=abs(Higgs->momentum().z()) ) {
	double Yjet = ktjets[0].rapidity();
	double Yjet_YH = ktjets[0].rapidity()-Higgs->momentum().rapidity();
	if(ktjets[0].perp()>=10000.) {
	Yjet_10.addWeighted(Yjet,1.);
	YjetYH_10.addWeighted(Yjet_YH,1.);
	}
	if(ktjets[0].perp()>=40000.) {
	Yjet_40.addWeighted(Yjet,1.);
	YjetYH_40.addWeighted(Yjet_YH,1.);
	}
	if(ktjets[0].perp()>=80000.) {
	Yjet_80.addWeighted(Yjet,1.);
	YjetYH_80.addWeighted(Yjet_YH,1.);
	}
	unsigned int last(ktjets.size()-1);
	if(ktjets[last]>=10000.&&Higgs->momentum().perp()>=10000.*MeV) {
	Yjet_10A.addWeighted(Yjet,1.);
	YjetYH_10A.addWeighted(Yjet_YH,1.);
	}
	if(ktjets[last]>=40000.&&Higgs->momentum().perp()>=40000.*MeV) {
	Yjet_40A.addWeighted(Yjet,1.);
	YjetYH_40A.addWeighted(Yjet_YH,1.);
	}
	if(ktjets[last]>=80000.&&Higgs->momentum().perp()>=80000.*MeV) {
	Yjet_80A.addWeighted(Yjet,1.);
	YjetYH_80A.addWeighted(Yjet_YH,1.);
	}
	} else {
	if(!Higgs)
	generator()->log() << "PP2HAnalysis::analyze\n"
	<< "Didn't find a Higgs in final state!\n";
	if(ktjets.size()==0)
	generator()->log() << "PP2HAnalysis::analyze\n"
	<< "Didn't find any jets!\n";
	if(abs(ktjets[0].t())!=abs(ktjets[0].z()))
	generator()->log() << "PP2HAnalysis::analyze\n"
	<< "Infinite rapidity leading jet.\n";
	}

	//----------------------//
	// //
	// Soft radiation //
	// analysis //
	// //
	//----------------------//
	if( ktjets.size()>0 && Higgs ) {

	// Find the gluons which fuse to give the Higgs:
	tPPtr parent_P;
	tPPtr parent_M;
	if(Higgs->parents().size()==1 &&
	Higgs->parents()[0]->parents().size()==2 &&
	Higgs->parents()[0]->parents()[0]->id()==21 &&
	Higgs->parents()[0]->parents()[1]->id()==21) {
	parent_P = Higgs->parents()[0]->parents()[0];
	parent_M = Higgs->parents()[0]->parents()[1];
	} else if(Higgs->parents().size()==2 &&
	Higgs->parents()[0]->id()==21 &&
	Higgs->parents()[1]->id()==21) {
	parent_P = Higgs->parents()[0];
	parent_M = Higgs->parents()[1];
	} else {
	throw Exception() << "PP2HAnalysis::analyze"
	<< "\nCan't find Higgs parent gluons"
	<< Exception::warning;
	}
	if(parent_P->momentum().z()<0.*GeV) swap(parent_P,parent_M);

	// Find the boost to the COM of the colliding gluons.
	Lorentz5Momentum p_P_gg = parent_P->momentum();
	Lorentz5Momentum p_M_gg = parent_M->momentum();
	Lorentz5Momentum pjet_gg = _kint.convert(ktjets[0]);
	Boost boost_gg = (p_P_gg+p_M_gg).findBoostToCM();
	// Boost the two gluons to their COM with them aligned along Z.
	p_P_gg = p_P_gg.boost(boost_gg);
	p_M_gg = p_M_gg.boost(boost_gg);
	// Also boost the leading jet to this frame.
	pjet_gg = pjet_gg.boost(boost_gg);

	// Find the first emission (with the widest angle).
	tPPtr emitter_P = parent_P;
	tPPtr ISchild_P;
	tPPtr emitted_P;
	tPPtr emitter_M = parent_M;
	tPPtr ISchild_M;
	tPPtr emitted_M;
	do {
	ISchild_P = emitter_P;
	emitter_P = emitter_P->parents()[0];
	}
	while(emitter_P->children().size()==1);
	emitted_P=emitter_P->children()[0]==ISchild_P ? emitter_P->children()[1] :
	emitter_P->children()[0] ;
	do {
	ISchild_M = emitter_M;
	emitter_M = emitter_M->parents()[0];
	}
	while(emitter_M->children().size()==1);
	emitted_M=emitter_M->children()[0]==ISchild_M ? emitter_M->children()[1] :
	emitter_M->children()[0] ;

	if(abs(emitter_P->id())==2212\|\|abs(emitter_M->id())==2212)
	throw Exception() << "PP2HAnalysis::analyze"
	<< "\nSelected a proton as a parent of emission."
	<< Exception::warning;

	Lorentz5Momentum p1st_P_gg = emitted_P->momentum();
	Lorentz5Momentum p1st_M_gg = emitted_M->momentum();
	p1st_P_gg = p1st_P_gg.boost(boost_gg);
	p1st_M_gg = p1st_M_gg.boost(boost_gg);

	double c1st_P = p1st_P_gg.cosTheta();
	double c1st_M = p1st_M_gg.cosTheta();
	double c1st = abs(c1st_P) <= abs(c1st_M) ? c1st_P : c1st_M;
	if(abs(emitter_P->id())==2212) c1st = c1st_M;
	if(abs(emitter_M->id())==2212) c1st = c1st_P;
	double cjet = pjet_gg.cosTheta();
	cos1st.addWeighted(c1st,1.);
	cosjet.addWeighted(cjet,1.);
	cos1st_w.addWeighted(c1st,1.);
	cosjet_w.addWeighted(cjet,1.);
	if(ktjets[0].perp()<=10000.) {
	cos1st_lt_10.addWeighted(c1st,1.);
	cosjet_lt_10.addWeighted(cjet,1.);
	cos1st_lt_10_w.addWeighted(c1st,1.);
	cosjet_lt_10_w.addWeighted(cjet,1.);
	}
	if(ktjets[0].perp()<=30000.) {
	cos1st_lt_30.addWeighted(c1st,1.);
	cosjet_lt_30.addWeighted(cjet,1.);
	cos1st_lt_30_w.addWeighted(c1st,1.);
	cosjet_lt_30_w.addWeighted(cjet,1.);
	}
	if(ktjets[0].perp()<=100000.) {
	cos1st_lt_100.addWeighted(c1st,1.);
	cosjet_lt_100.addWeighted(cjet,1.);
	cos1st_lt_100_w.addWeighted(c1st,1.);
	cosjet_lt_100_w.addWeighted(cjet,1.);
	}
	if(ktjets[0].perp()>=10000.) {
	cos1st_gt_10.addWeighted(c1st,1.);
	cosjet_gt_10.addWeighted(cjet,1.);
	cos1st_gt_10_w.addWeighted(c1st,1.);
	cosjet_gt_10_w.addWeighted(cjet,1.);
	}
	if(ktjets[0].perp()>=30000.) {
	cos1st_gt_30.addWeighted(c1st,1.);
	cosjet_gt_30.addWeighted(cjet,1.);
	cos1st_gt_30_w.addWeighted(c1st,1.);
	cosjet_gt_30_w.addWeighted(cjet,1.);
	}
	if(ktjets[0].perp()>=100000.) {
	cos1st_gt_100.addWeighted(c1st,1.);
	cosjet_gt_100.addWeighted(cjet,1.);
	cos1st_gt_100_w.addWeighted(c1st,1.);
	cosjet_gt_100_w.addWeighted(cjet,1.);
	}
	}

	//----------------------//
	// //
	// Jet multiplicity //
	// analysis //
	// //
	//----------------------//
	unsigned int n10(0);
	unsigned int n40(0);
	unsigned int n80(0);
	for(unsigned int ix=0; ix<ktjets.size(); ++ix) {
	if(ktjets[ix].perp()>=10000.) n10++;
	if(ktjets[ix].perp()>=40000.) n40++;
	if(ktjets[ix].perp()>=80000.) n80++;
	}
	Njets_10.addWeighted(n10+0.001,1);
	Njets_40.addWeighted(n40+0.001,1);
	Njets_80.addWeighted(n80+0.001,1);

	//----------------------//
	// //
	// Y merge analysis //
	// //
	//----------------------//
	if(ktjets.size()>2)
	log_y23.addWeighted(log(ev.getYMerge(2))/log(10.),1);
	if(ktjets.size()>3)
	log_y34.addWeighted(log(ev.getYMerge(3))/log(10.),1);
	if(ktjets.size()>4)
	log_y45.addWeighted(log(ev.getYMerge(4))/log(10.),1);

	}

	void PP2HAnalysis::dofinish() {
	AnalysisHandler::dofinish();
	string fname = generator()->filename()+string("-")+name()+string(".top");
	ofstream outfile(fname.c_str());

	using namespace HistogramOptions;
	pt_30.normaliseToCrossSection();
	pt_30.prefactor(pt_30.prefactor()*1.e3);
	pt_30.topdrawOutput(outfile,Frame,"RED",
	"Higgs boson p0T1",
	" X X",
	"dS/dp0T1 (pb)",
	" G X X ");
	pt_200.normaliseToCrossSection();
	pt_200.prefactor(pt_200.prefactor()*1.e3);
	pt_200.topdrawOutput(outfile,Frame\|Ylog,"RED",
	"Higgs boson p0T1",
	" X X",
	"dS/dp0T1 (pb)",
	" G X X ");
	pt_400.normaliseToCrossSection();
	pt_400.prefactor(pt_400.prefactor()*1.e3);
	pt_400.topdrawOutput(outfile,Frame\|Ylog,"RED",
	"Higgs boson p0T1",
	" X X",
	"dS/dp0T1 (pb)",
	" G X X ");
	Yjet_10.normaliseToCrossSection();
	Yjet_10.prefactor(Yjet_10.prefactor()*1.e3);
	Yjet_10.topdrawOutput(outfile,Frame\|Ylog,"RED",
	"y0jet1 (p0T,jet1>10 GeV)",
	" X X X X ",
	"dS/dy0jet1 (pb)",
	" G X X ");
	Yjet_40.normaliseToCrossSection();
	Yjet_40.prefactor(Yjet_40.prefactor()*1.e3);
	Yjet_40.topdrawOutput(outfile,Frame\|Ylog,"RED",
	"y0jet1 (p0T,jet1>40 GeV)",
	" X X X X ",
	"dS/dy0jet1 (pb)",
	" G X X ");
	Yjet_80.normaliseToCrossSection();
	Yjet_80.prefactor(Yjet_80.prefactor()*1.e3);
	Yjet_80.topdrawOutput(outfile,Frame\|Ylog,"RED",
	"y0jet1 (p0T,jet1>80 GeV)",
	" X X X X ",
	"dS/dy0jet1 (pb)",
	" G X X ");
	YjetYH_10.normaliseToCrossSection();
	YjetYH_10.prefactor(YjetYH_10.prefactor()*1.e3);
	YjetYH_10.topdrawOutput(outfile,Frame\|Ylog,"RED",
	"y0jet1-y0H1 (p0T,jet1>10 GeV)",
	" X X X X X X ",
	"dS/d(y0jet1-y0H1) (pb)",
	" G X X X X ");
	YjetYH_40.normaliseToCrossSection();
	YjetYH_40.prefactor(YjetYH_40.prefactor()*1.e3);
	YjetYH_40.topdrawOutput(outfile,Frame\|Ylog,"RED",
	"y0jet1-y0H1 (p0T,jet1>40 GeV)",
	" X X X X X X ",
	"dS/d(y0jet1-y0H1) (pb)",
	" G X X X X ");
	YjetYH_80.normaliseToCrossSection();
	YjetYH_80.prefactor(YjetYH_80.prefactor()*1.e3);
	YjetYH_80.topdrawOutput(outfile,Frame\|Ylog,"RED",
	"y0jet1-y0H1 (p0T,jet1>80 GeV)",
	" X X X X X X ",
	"dS/d(y0jet1-y0H1) (pb)",
	" G X X X X ");
	Yjet_10A.normaliseToCrossSection();
	Yjet_10A.prefactor(Yjet_10A.prefactor()*1.e3);
	Yjet_10A.topdrawOutput(outfile,Frame\|Ylog,"RED",
	"y0jet1 (p0T,all1>10 GeV)",
	" X X X X ",
	"dS/dy0jet1 (pb)",
	" G X X ");
	Yjet_40A.normaliseToCrossSection();
	Yjet_40A.prefactor(Yjet_40A.prefactor()*1.e3);
	Yjet_40A.topdrawOutput(outfile,Frame\|Ylog,"RED",
	"y0jet1 (p0T,all1>40 GeV)",
	" X X X X ",
	"dS/dy0jet1 (pb)",
	" G X X ");
	Yjet_80A.normaliseToCrossSection();
	Yjet_80A.prefactor(Yjet_80A.prefactor()*1.e3);
	Yjet_80A.topdrawOutput(outfile,Frame\|Ylog,"RED",
	"y0jet1 (p0T,all1>80 GeV)",
	" X X X X ",
	"dS/dy0jet1 (pb)",
	" G X X ");
	YjetYH_10A.normaliseToCrossSection();
	YjetYH_10A.prefactor(YjetYH_10A.prefactor()*1.e3);
	YjetYH_10A.topdrawOutput(outfile,Frame\|Ylog,"RED",
	"y0jet1-y0H1 (p0T,all1>10 GeV)",
	" X X X X X X ",
	"dS/d(y0jet1-y0H1) (pb)",
	" G X X X X ");
	YjetYH_40A.normaliseToCrossSection();
	YjetYH_40A.prefactor(YjetYH_40A.prefactor()*1.e3);
	YjetYH_40A.topdrawOutput(outfile,Frame\|Ylog,"RED",
	"y0jet1-y0H1 (p0T,all1>40 GeV)",
	" X X X X X X ",
	"dS/d(y0jet1-y0H1) (pb)",
	" G X X X X ");
	YjetYH_80A.normaliseToCrossSection();
	YjetYH_80A.prefactor(YjetYH_80A.prefactor()*1.e3);
	YjetYH_80A.topdrawOutput(outfile,Frame\|Ylog,"RED",
	"y0jet1-y0H1 (p0T,all1>80 GeV)",
	" X X X X X X ",
	"dS/d(y0jet1-y0H1) (pb)",
	" G X X X X ");
	Njets_10.normaliseToCrossSection();
	Njets_10.prefactor(Njets_10.prefactor()*1.e3);
	Njets_10.topdrawOutput(outfile,Frame,"RED",
	"Jet multiplicity (p0T,jets1>10 GeV)",
	" X X ",
	"dS/dn0jets1 (pb)",
	" G X X ");
	Njets_40.normaliseToCrossSection();
	Njets_40.prefactor(Njets_40.prefactor()*1.e3);
	Njets_40.topdrawOutput(outfile,Frame,"RED",
	"Jet multiplicity (p0T,jets1>40 GeV)",
	" X X ",
	"dS/dn0jets1 (pb)",
	" G X X ");
	Njets_80.normaliseToCrossSection();
	Njets_80.prefactor(Njets_80.prefactor()*1.e3);
	Njets_80.topdrawOutput(outfile,Frame,"RED",
	"Jet multiplicity (p0T,jets1>80 GeV)",
	" X X ",
	"dS/dn0jets1 (pb)",
	" G X X ");

	log_y23.normaliseToCrossSection();
	log_y23.prefactor(log_y23.prefactor()*1.e3);
	log_y23.topdrawOutput(outfile,Frame\|Ylog,"RED",
	"Log0101(y0231)",
	" X X X X ",
	"dS/dLog0101(y0231)",
	" G X X X X ");
	log_y34.normaliseToCrossSection();
	log_y34.prefactor(log_y34.prefactor()*1.e3);
	log_y34.topdrawOutput(outfile,Frame\|Ylog,"RED",
	"Log0101(y0341)",
	" X X X X ",
	"dS/dLog0101(y0341)",
	" G X X X X ");
	log_y45.normaliseToCrossSection();
	log_y45.prefactor(log_y45.prefactor()*1.e3);
	log_y45.topdrawOutput(outfile,Frame\|Ylog,"RED",
	"Log0101(y0451)",
	" X X X X ",
	"dS/dLog0101(y0451)",
	" G X X X X ");
	cosjet.normaliseToCrossSection();
	cosjet.prefactor(cosjet.prefactor()*1.e3);
	cosjet.topdrawOutput(outfile,Frame,"RED",
	"CosQ0jet1",
	" GX X",
	"dS/dcosQ0jet1 (pb)",
	" G GX X ");
	cosjet_lt_10.normaliseToCrossSection();
	cosjet_lt_10.prefactor(cosjet_lt_10.prefactor()*1.e3);
	cosjet_lt_10.topdrawOutput(outfile,Frame,"RED",
	"CosQ0jet1 (p0t,jet1<10 GeV)",
	" GX X X X ",
	"dS/dcosQ0jet1 (pb)",
	" G GX X ");
	cosjet_lt_30.normaliseToCrossSection();
	cosjet_lt_30.prefactor(cosjet_lt_30.prefactor()*1.e3);
	cosjet_lt_30.topdrawOutput(outfile,Frame,"RED",
	"CosQ0jet1 (p0t,jet1<30 GeV)",
	" GX X X X ",
	"dS/dcosQ0jet1 (pb)",
	" G GX X ");
	cosjet_lt_100.normaliseToCrossSection();
	cosjet_lt_100.prefactor(cosjet_lt_100.prefactor()*1.e3);
	cosjet_lt_100.topdrawOutput(outfile,Frame,"RED",
	"CosQ0jet1 (p0t,jet1<100 GeV)",
	" GX X X X ",
	"dS/dcosQ0jet1 (pb)",
	" G GX X ");
	cosjet_gt_10.normaliseToCrossSection();
	cosjet_gt_10.prefactor(cosjet_gt_10.prefactor()*1.e3);
	cosjet_gt_10.topdrawOutput(outfile,Frame,"RED",
	"CosQ0jet1 (p0t,jet1>10 GeV)",
	" GX X X X ",
	"dS/dcosQ0jet1 (pb)",
	" G GX X ");
	cosjet_gt_30.normaliseToCrossSection();
	cosjet_gt_30.prefactor(cosjet_gt_30.prefactor()*1.e3);
	cosjet_gt_30.topdrawOutput(outfile,Frame,"RED",
	"CosQ0jet1 (p0t,jet1>30 GeV)",
	" GX X X X ",
	"dS/dcosQ0jet1 (pb)",
	" G GX X ");
	cosjet_gt_100.normaliseToCrossSection();
	cosjet_gt_100.prefactor(cosjet_gt_100.prefactor()*1.e3);
	cosjet_gt_100.topdrawOutput(outfile,Frame,"RED",
	"CosQ0jet1 (p0t,jet1>100 GeV)",
	" GX X X X ",
	"dS/dcosQ0jet1 (pb)",
	" G GX X ");
	cosjet_lt_10_w.normaliseToCrossSection();
	cosjet_lt_10_w.prefactor(cosjet_lt_10_w.prefactor()*1.e3);
	cosjet_lt_10_w.topdrawOutput(outfile,Frame,"RED",
	"CosQ0jet1 (p0t,jet1<10 GeV)",
	" GX X X X ",
	"dS/dcosQ0jet1 (pb)",
	" G GX X ");
	cosjet_lt_30_w.normaliseToCrossSection();
	cosjet_lt_30_w.prefactor(cosjet_lt_30_w.prefactor()*1.e3);
	cosjet_lt_30_w.topdrawOutput(outfile,Frame,"RED",
	"CosQ0jet1 (p0t,jet1<30 GeV)",
	" GX X X X ",
	"dS/dcosQ0jet1 (pb)",
	" G GX X ");
	cosjet_lt_100_w.normaliseToCrossSection();
	cosjet_lt_100_w.prefactor(cosjet_lt_100_w.prefactor()*1.e3);
	cosjet_lt_100_w.topdrawOutput(outfile,Frame,"RED",
	"CosQ0jet1 (p0t,jet1<100 GeV)",
	" GX X X X ",
	"dS/dcosQ0jet1 (pb)",
	" G GX X ");
	cosjet_gt_10_w.normaliseToCrossSection();
	cosjet_gt_10_w.prefactor(cosjet_gt_10_w.prefactor()*1.e3);
	cosjet_gt_10_w.topdrawOutput(outfile,Frame,"RED",
	"CosQ0jet1 (p0t,jet1>10 GeV)",
	" GX X X X ",
	"dS/dcosQ0jet1 (pb)",
	" G GX X ");
	cosjet_gt_30_w.normaliseToCrossSection();
	cosjet_gt_30_w.prefactor(cosjet_gt_30_w.prefactor()*1.e3);
	cosjet_gt_30_w.topdrawOutput(outfile,Frame,"RED",
	"CosQ0jet1 (p0t,jet1>30 GeV)",
	" GX X X X ",
	"dS/dcosQ0jet1 (pb)",
	" G GX X ");
	cosjet_gt_100_w.normaliseToCrossSection();
	cosjet_gt_100_w.prefactor(cosjet_gt_100_w.prefactor()*1.e3);
	cosjet_gt_100_w.topdrawOutput(outfile,Frame,"RED",
	"CosQ0jet1 (p0t,jet1>100 GeV)",
	" GX X X X ",
	"dS/dcosQ0jet1 (pb)",
	" G GX X ");
	cos1st.normaliseToCrossSection();
	cos1st.prefactor(cos1st.prefactor()*1.e3);
	cos1st.topdrawOutput(outfile,Frame,"RED",
	"CosQ01st1",
	" GX X",
	"dS/dcosQ01st1 (pb)",
	" G GX X ");
	cos1st_lt_10.normaliseToCrossSection();
	cos1st_lt_10.prefactor(cos1st_lt_10.prefactor()*1.e3);
	cos1st_lt_10.topdrawOutput(outfile,Frame,"RED",
	"CosQ01st1 (p0T,jet1<10 GeV)",
	" GX X X X ",
	"dS/dcosQ01st1 (pb)",
	" G GX X ");
	cos1st_lt_30.normaliseToCrossSection();
	cos1st_lt_30.prefactor(cos1st_lt_30.prefactor()*1.e3);
	cos1st_lt_30.topdrawOutput(outfile,Frame,"RED",
	"CosQ01st1 (p0T,jet1<30 GeV)",
	" GX X X X ",
	"dS/dcosQ01st1 (pb)",
	" G GX X ");
	cos1st_lt_100.normaliseToCrossSection();
	cos1st_lt_100.prefactor(cos1st_lt_100.prefactor()*1.e3);
	cos1st_lt_100.topdrawOutput(outfile,Frame,"RED",
	"CosQ01st1 (p0T,jet1<100 GeV)",
	" GX X X X ",
	"dS/dcosQ01st1 (pb)",
	" G GX X ");
	cos1st_gt_10.normaliseToCrossSection();
	cos1st_gt_10.prefactor(cos1st_gt_10.prefactor()*1.e3);
	cos1st_gt_10.topdrawOutput(outfile,Frame,"RED",
	"CosQ01st1 (p0T,jet1>10 GeV)",
	" GX X X X ",
	"dS/dcosQ01st1 (pb)",
	" G GX X ");
	cos1st_gt_30.normaliseToCrossSection();
	cos1st_gt_30.prefactor(cos1st_gt_30.prefactor()*1.e3);
	cos1st_gt_30.topdrawOutput(outfile,Frame,"RED",
	"CosQ01st1 (p0T,jet1>30 GeV)",
	" GX X X X ",
	"dS/dcosQ01st1 (pb)",
	" G GX X ");
	cos1st_gt_100.normaliseToCrossSection();
	cos1st_gt_100.prefactor(cos1st_gt_100.prefactor()*1.e3);
	cos1st_gt_100.topdrawOutput(outfile,Frame,"RED",
	"CosQ01st1 (p0T,jet1>100 GeV)",
	" GX X X X ",
	"dS/dcosQ01st1 (pb)",
	" G GX X ");
	cos1st_lt_10_w.normaliseToCrossSection();
	cos1st_lt_10_w.prefactor(cos1st_lt_10_w.prefactor()*1.e3);
	cos1st_lt_10_w.topdrawOutput(outfile,Frame,"RED",
	"CosQ01st1 (p0T,jet1<10 GeV)",
	" GX X X X ",
	"dS/dcosQ01st1 (pb)",
	" G GX X ");
	cos1st_lt_30_w.normaliseToCrossSection();
	cos1st_lt_30_w.prefactor(cos1st_lt_30_w.prefactor()*1.e3);
	cos1st_lt_30_w.topdrawOutput(outfile,Frame,"RED",
	"CosQ01st1 (p0T,jet1<30 GeV)",
	" GX X X X ",
	"dS/dcosQ01st1 (pb)",
	" G GX X ");
	cos1st_lt_100_w.normaliseToCrossSection();
	cos1st_lt_100_w.prefactor(cos1st_lt_100_w.prefactor()*1.e3);
	cos1st_lt_100_w.topdrawOutput(outfile,Frame,"RED",
	"CosQ01st1 (p0T,jet1<100 GeV)",
	" GX X X X ",
	"dS/dcosQ01st1 (pb)",
	" G GX X ");
	cos1st_gt_10_w.normaliseToCrossSection();
	cos1st_gt_10_w.prefactor(cos1st_gt_10_w.prefactor()*1.e3);
	cos1st_gt_10_w.topdrawOutput(outfile,Frame,"RED",
	"CosQ01st1 (p0T,jet1>10 GeV)",
	" GX X X X ",
	"dS/dcosQ01st1 (pb)",
	" G GX X ");
	cos1st_gt_30_w.normaliseToCrossSection();
	cos1st_gt_30_w.prefactor(cos1st_gt_30_w.prefactor()*1.e3);
	cos1st_gt_30_w.topdrawOutput(outfile,Frame,"RED",
	"CosQ01st1 (p0T,jet1>30 GeV)",
	" GX X X X ",
	"dS/dcosQ01st1 (pb)",
	" G GX X ");
	cos1st_gt_100_w.normaliseToCrossSection();
	cos1st_gt_100_w.prefactor(cos1st_gt_100_w.prefactor()*1.e3);
	cos1st_gt_100_w.topdrawOutput(outfile,Frame,"RED",
	"CosQ01st1 (p0T,jet1>100 GeV)",
	" GX X X X ",
	"dS/dcosQ01st1 (pb)",
	" G GX X ");

	outfile.close();
	}

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