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	diff --git a/include/HEJ/MatrixElement.hh b/include/HEJ/MatrixElement.hh
	index 9cda5dd..f684722 100644
	--- a/include/HEJ/MatrixElement.hh
	+++ b/include/HEJ/MatrixElement.hh
	@@ -1,175 +1,164 @@
	/** \file
	* \brief Contains the MatrixElement Class
	*/
	#pragma once

	#include <functional>

	#include "HEJ/config.hh"
	#include "HEJ/utility.hh"
	#include "HEJ/HiggsCouplingSettings.hh"
	#include "HEJ/Weights.hh"

	#include "CLHEP/Vector/LorentzVector.h"


	namespace HEJ{
	class Event;

	//! Class to calculate the squares of matrix elements
	class MatrixElement{
	public:
	/** \brief MatrixElement Constructor
	* @param alpha_s Function taking the renormalisation scale
	* and returning the strong coupling constant
	* @param conf General matrix element settings
	*/
	MatrixElement(
	std::function<double (double)> alpha_s,
	MatrixElementConfig conf
	);

	/**
	* \brief squares of regulated HEJ matrix elements
	* @param event The event for which to calculate matrix elements
	* @param check_momenta Special treatment for partons inside extremal jets
	* @returns The squares of HEJ matrix elements including virtual corrections
	*
	* cf. eq. (22) in \cite Andersen:2011hs
	*
	* \internal Relation to standard HEJ Met2: MatrixElement = Met2shat^2/(pdftapdftb)
	*/
	Weights operator()(
	Event const & event,
	bool check_momenta
	) const;

	//! Squares of HEJ tree-level matrix elements
	/**
	* @param event The event for which to calculate matrix elements
	* @param check_momenta Special treatment for partons inside extremal jets
	* @returns The squares of HEJ matrix elements without virtual corrections
	*
	* cf. eq. (22) in \cite Andersen:2011hs
	*/
	Weights tree(
	Event const & event,
	bool check_momenta
	) const;

	/**
	* \brief Virtual corrections to matrix element squares
	* @param event The event for which to calculate matrix elements
	* @returns The virtual corrections to the squares of the matrix elements
	*
	* The all order virtual corrections to LL in the MRK limit is
	* given by replacing 1/t in the scattering amplitude according to the
	* lipatov ansatz.
	*
	* cf. second-to-last line of eq. (22) in \cite Andersen:2011hs
	* note that indices are off by one, i.e. out[0].p corresponds to p_1
	*/
	Weights virtual_corrections(
	Event const & event
	) const;

	private:

	Weights tree_param(
	Event const & event
	) const;

	double tree_kin(
	Event const & event,
	bool check_momenta
	) const;

	double tree_param(
	Event const & event,
	double mur
	) const;

	- double tree_kin(
	- std::array<Particle, 2> const & incoming,
	- std::vector<Particle> const & outgoing,
	- bool check_momenta
	- ) const;
	-
	double virtual_corrections(
	Event const & event,
	double mur
	) const;

	//! \internal cf. last line of eq. (22) in \cite Andersen:2011hs
	double omega0(
	double alpha_s, double mur,
	fastjet::PseudoJet const & q_j, double lambda
	) const;

	double tree_kin_jets(
	- std::array<Particle, 2> const & incoming,
	- std::vector<Particle> partons,
	+ Event const & ev,
	bool check_momenta
	) const;
	double tree_kin_Higgs(
	- std::array<Particle, 2> const & incoming,
	- std::vector<Particle> const & outgoing,
	+ Event const & ev,
	bool check_momenta
	) const;
	double tree_kin_Higgs_first(
	- std::array<Particle, 2> const & incoming,
	- std::vector<Particle> const & outgoing,
	+ Event const & ev,
	bool check_momenta
	) const;
	double tree_kin_Higgs_last(
	- std::array<Particle, 2> const & incoming,
	- std::vector<Particle> const & outgoing,
	+ Event const & ev,
	bool check_momenta
	) const;

	/**
	* \internal
	* \brief Higgs inbetween extremal partons.
	*
	* Note that in the case of unordered emission, the Higgs is always
	* treated as if in between the extremal (FKL) partons, even if its
	* rapidity is outside the extremal parton rapidities
	*/
	double tree_kin_Higgs_between(
	- std::array<Particle, 2> const & incoming,
	- std::vector<Particle> const & outgoing,
	+ Event const & ev,
	bool check_momenta
	) const;


	double tree_param_partons(
	double alpha_s, double mur,
	std::vector<Particle> const & partons
	) const;


	std::vector<int> in_extremal_jet_indices(
	std::vector<fastjet::PseudoJet> const & partons
	) const;


	std::vector<Particle> tag_extremal_jet_partons(
	std::array<Particle, 2> const & incoming,
	std::vector<Particle> out_partons, bool check_momenta
	) const;

	double MH2_forwardH(
	CLHEP::HepLorentzVector p1out, CLHEP::HepLorentzVector p1in,
	pid::ParticleID type2,
	CLHEP::HepLorentzVector p2out, CLHEP::HepLorentzVector p2in,
	CLHEP::HepLorentzVector pH,
	double t1, double t2
	) const;

	std::function<double (double)> alpha_s_;

	MatrixElementConfig param_;
	};


	}
	diff --git a/include/HEJ/event_types.hh b/include/HEJ/event_types.hh
	index ea0698d..6cf3d82 100644
	--- a/include/HEJ/event_types.hh
	+++ b/include/HEJ/event_types.hh
	@@ -1,55 +1,60 @@
	/** \file
	* \brief Define different types of events.
	*
	*/

	#pragma once

	#include "HEJ/utility.hh"

	namespace HEJ{

	//! Namespace for event types
	namespace event_type{
	//! Possible event types
	enum EventType: size_t{
	FKL, /*< FKL-type event /
	unordered_backward, /*< event with unordered backward emission /
	unordered_forward, /*< event with unordered forward emission /
	nonHEJ, /*< event configuration not covered by HEJ /
	no_2_jets, /*< event with less than two jets /
	bad_final_state, /*< event with an unsupported final state /
	unob = unordered_backward,
	unof = unordered_forward,
	first_type = FKL,
	last_type = bad_final_state
	};

	//! Event type names
	/**
	* For example, names[FKL] is the string "FKL"
	*/
	static constexpr auto names = make_array(
	"FKL",
	"unordered backward",
	"unordered forward",
	"nonHEJ",
	"no 2 jets",
	"bad final state"
	);

	inline
	bool is_HEJ(EventType type) {
	switch(type) {
	case FKL:
	case unordered_backward:
	case unordered_forward:
	return true;
	default:
	return false;
	}
	}

	+ inline
	+ bool is_uno(EventType type) {
	+ return type == unordered_backward \|\| type == unordered_forward;
	+ }
	+
	}

	}
	diff --git a/src/MatrixElement.cc b/src/MatrixElement.cc
	index 7d970e6..0abb59a 100644
	--- a/src/MatrixElement.cc
	+++ b/src/MatrixElement.cc
	@@ -1,862 +1,865 @@
	#include "HEJ/MatrixElement.hh"

	#include <unordered_map>

	#include <CLHEP/Random/Randomize.h>
	#include <CLHEP/Random/RanluxEngine.h>

	#include "HEJ/Constants.hh"
	#include "HEJ/currents.hh"
	#include "HEJ/exceptions.hh"
	#include "HEJ/PDG_codes.hh"
	#include "HEJ/uno.hh"
	#include "HEJ/event_types.hh"
	#include "HEJ/utility.hh"

	namespace HEJ{
	//cf. last line of eq. (22) in \ref Andersen:2011hs
	double MatrixElement::omega0(
	double alpha_s, double mur,
	fastjet::PseudoJet const & q_j, double lambda
	) const {
	const double result = - alpha_sN_C/M_PIlog(q_j.perp2()/(lambda*lambda));
	if(! param_.log_correction) return result;
	// use alpha_s(sqrt(q_j*lambda)), evolved to mur
	return (
	1. + alpha_s/(4.M_PI)beta0log(murmur/(q_j.perp()*lambda))
	)*result;
	}

	Weights MatrixElement::operator()(
	Event const & event,
	bool check_momenta
	) const {
	return tree(event, check_momenta)*virtual_corrections(event);
	}

	Weights MatrixElement::tree(
	Event const & event,
	bool check_momenta
	) const {
	if(! is_HEJ(event.type())) {
	return Weights{0., std::vector<double>(event.variations().size(), 0.)};
	}
	return tree_param(event)*tree_kin(event, check_momenta);
	}

	Weights MatrixElement::tree_param(
	Event const & event
	) const {
	Weights result;
	// only compute once for each renormalisation scale
	std::unordered_map<double, double> known;
	result.central = tree_param(event, event.central().mur);
	known.emplace(event.central().mur, result.central);
	for(auto const & var: event.variations()) {
	const auto ME_it = known.find(var.mur);
	if(ME_it == end(known)) {
	const double wt = tree_param(event, var.mur);
	result.variations.emplace_back(wt);
	known.emplace(var.mur, wt);
	}
	else {
	result.variations.emplace_back(ME_it->second);
	}
	}
	return result;
	}

	Weights MatrixElement::virtual_corrections(
	Event const & event
	) const {
	if(! is_HEJ(event.type())) {
	return Weights{0., std::vector<double>(event.variations().size(), 0.)};
	}
	Weights result;
	// only compute once for each renormalisation scale
	std::unordered_map<double, double> known;
	result.central = virtual_corrections(event, event.central().mur);
	known.emplace(event.central().mur, result.central);
	for(auto const & var: event.variations()) {
	const auto ME_it = known.find(var.mur);
	if(ME_it == end(known)) {
	const double wt = virtual_corrections(event, var.mur);
	result.variations.emplace_back(wt);
	known.emplace(var.mur, wt);
	}
	else {
	result.variations.emplace_back(ME_it->second);
	}
	}
	return result;
	}

	double MatrixElement::virtual_corrections(
	Event const & event,
	double mur
	) const{
	auto const & in = event.incoming();
	auto const & out = event.outgoing();
	fastjet::PseudoJet const & pa = in.front().p;
	#ifndef NDEBUG
	fastjet::PseudoJet const & pb = in.back().p;
	double const norm = (in.front().p + in.back().p).E();
	#endif

	assert(std::is_sorted(out.begin(), out.end(), rapidity_less{}));
	assert(out.size() >= 2);
	assert(pa.pz() < pb.pz());

	fastjet::PseudoJet q = pa - out[0].p;
	size_t first_idx = 0;
	size_t last_idx = out.size() - 1;
	// if there is a Higgs or unordered gluon outside the extremal partons
	// then it is not part of the FKL ladder and does not contribute
	// to the virtual corrections
	if(out.front().type == pid::Higgs \|\| event.type() == event_type::unob){
	q -= out[1].p;
	++first_idx;
	}
	if(out.back().type == pid::Higgs \|\| event.type() == event_type::unof){
	--last_idx;
	}

	double exponent = 0;
	const double alpha_s = alpha_s_(mur);
	for(size_t j = first_idx; j < last_idx; ++j){
	exponent += omega0(alpha_s, mur, q, CLAMBDA)*(
	out[j+1].rapidity() - out[j].rapidity()
	);
	q -= out[j+1].p;
	}
	assert(
	nearby(q, -1*pb, norm)
	\|\| out.back().type == pid::Higgs
	\|\| event.type() == event_type::unof
	);
	return exp(exponent);
	}
	} // namespace HEJ

	namespace {
	//! Lipatov vertex for partons emitted into extremal jets
	double C2Lipatov(CLHEP::HepLorentzVector qav, CLHEP::HepLorentzVector qbv,
	CLHEP::HepLorentzVector p1, CLHEP::HepLorentzVector p2)
	{
	CLHEP::HepLorentzVector temptrans=-(qav+qbv);
	CLHEP::HepLorentzVector p5=qav-qbv;
	CLHEP::HepLorentzVector CL=temptrans
	+ p1(qav.m2()/p5.dot(p1) + 2.p5.dot(p2)/p1.dot(p2))
	- p2(qbv.m2()/p5.dot(p2) + 2.p5.dot(p1)/p1.dot(p2));

	// cout << "#Fadin qa : "<<qav<<endl;
	// cout << "#Fadin qb : "<<qbv<<endl;
	// cout << "#Fadin p1 : "<<p1<<endl;
	// cout << "#Fadin p2 : "<<p2<<endl;
	// cout << "#Fadin p5 : "<<p5<<endl;
	// cout << "#Fadin Gauge Check : "<< CL.dot(p5)<<endl;
	// cout << "#Fadin C2L : "<< -CL.dot(CL)<<" "<<-CL.dot(CL)/(qav.m2()*qbv.m2())/(4./p5.perp2())<<endl;

	// TODO can this dead test go?
	// if (-CL.dot(CL)<0.)
	// if (fabs(CL.dot(p5))>fabs(CL.dot(CL))) // not sufficient!
	// return 0.;
	// else
	return -CL.dot(CL);
	}

	//! Lipatov vertex with soft subtraction for partons emitted into extremal jets
	double C2Lipatovots(CLHEP::HepLorentzVector qav, CLHEP::HepLorentzVector qbv,
	CLHEP::HepLorentzVector p1, CLHEP::HepLorentzVector p2)
	{
	double kperp=(qav-qbv).perp();
	if (kperp>HEJ::CLAMBDA)
	return C2Lipatov(qav, qbv, p1, p2)/(qav.m2()*qbv.m2());
	else {
	double Cls=(C2Lipatov(qav, qbv, p1, p2)/(qav.m2()*qbv.m2()));
	return Cls-4./(kperp*kperp);
	}
	}

	//! Lipatov vertex
	double C2Lipatov(CLHEP::HepLorentzVector qav, CLHEP::HepLorentzVector qbv,
	CLHEP::HepLorentzVector pim, CLHEP::HepLorentzVector pip,
	CLHEP::HepLorentzVector pom, CLHEP::HepLorentzVector pop) // B
	{
	CLHEP::HepLorentzVector temptrans=-(qav+qbv);
	CLHEP::HepLorentzVector p5=qav-qbv;
	CLHEP::HepLorentzVector CL=temptrans
	+ qav.m2()(1./p5.dot(pip)pip + 1./p5.dot(pop)*pop)/2.
	- qbv.m2()(1./p5.dot(pim)pim + 1./p5.dot(pom)*pom)/2.
	+ ( pip*(p5.dot(pim)/pip.dot(pim) + p5.dot(pom)/pip.dot(pom))
	+ pop*(p5.dot(pim)/pop.dot(pim) + p5.dot(pom)/pop.dot(pom))
	- pim*(p5.dot(pip)/pip.dot(pim) + p5.dot(pop)/pop.dot(pim))
	- pom*(p5.dot(pip)/pip.dot(pom) + p5.dot(pop)/pop.dot(pom)) )/2.;

	return -CL.dot(CL);
	}

	//! Lipatov vertex with soft subtraction
	double C2Lipatovots(CLHEP::HepLorentzVector qav, CLHEP::HepLorentzVector qbv,
	CLHEP::HepLorentzVector pa, CLHEP::HepLorentzVector pb,
	CLHEP::HepLorentzVector p1, CLHEP::HepLorentzVector p2)
	{
	double kperp=(qav-qbv).perp();
	if (kperp>HEJ::CLAMBDA)
	return C2Lipatov(qav, qbv, pa, pb, p1, p2)/(qav.m2()*qbv.m2());
	else {
	double Cls=(C2Lipatov(qav, qbv, pa, pb, p1, p2)/(qav.m2()*qbv.m2()));
	double temp=Cls-4./(kperp*kperp);
	return temp;
	}
	}

	/** Matrix element squared for tree-level current-current scattering
	* @param aptype Particle a PDG ID
	* @param bptype Particle b PDG ID
	* @param pn Particle n Momentum
	* @param pb Particle b Momentum
	* @param p1 Particle 1 Momentum
	* @param pa Particle a Momentum
	* @returns ME Squared for Tree-Level Current-Current Scattering
	*/
	double ME_current(
	int aptype, int bptype,
	CLHEP::HepLorentzVector const & pn,
	CLHEP::HepLorentzVector const & pb,
	CLHEP::HepLorentzVector const & p1,
	CLHEP::HepLorentzVector const & pa
	){
	if (aptype==21&&bptype==21) {
	return jM2gg(pn,pb,p1,pa);
	} else if (aptype==21&&bptype!=21) {
	if (bptype > 0)
	return jM2qg(pn,pb,p1,pa);
	else
	return jM2qbarg(pn,pb,p1,pa);
	}
	else if (bptype==21&&aptype!=21) { // ----- \|\| -----
	if (aptype > 0)
	return jM2qg(p1,pa,pn,pb);
	else
	return jM2qbarg(p1,pa,pn,pb);
	}
	else { // they are both quark
	if (bptype>0) {
	if (aptype>0)
	return jM2qQ(pn,pb,p1,pa);
	else
	return jM2qQbar(pn,pb,p1,pa);
	}
	else {
	if (aptype>0)
	return jM2qQbar(p1,pa,pn,pb);
	else
	return jM2qbarQbar(pn,pb,p1,pa);
	}
	}
	throw std::logic_error("unknown particle types");
	}

	/** \brief Matrix element squared for tree-level current-current scattering with Higgs
	* @param aptype Particle a PDG ID
	* @param bptype Particle b PDG ID
	* @param pn Particle n Momentum
	* @param pb Particle b Momentum
	* @param p1 Particle 1 Momentum
	* @param pa Particle a Momentum
	* @param qH t-channel momentum before Higgs
	* @param qHp1 t-channel momentum after Higgs
	* @returns ME Squared for Tree-Level Current-Current Scattering with Higgs
	*/
	double ME_Higgs_current(
	int aptype, int bptype,
	CLHEP::HepLorentzVector const & pn,
	CLHEP::HepLorentzVector const & pb,
	CLHEP::HepLorentzVector const & p1,
	CLHEP::HepLorentzVector const & pa,
	CLHEP::HepLorentzVector const & qH, // t-channel momentum before Higgs
	CLHEP::HepLorentzVector const & qHp1, // t-channel momentum after Higgs
	double mt, bool include_bottom, double mb
	){
	if (aptype==21&&bptype==21) // gg initial state
	return MH2gg(pn,pb,p1,pa,-qHp1,-qH,mt,include_bottom,mb);
	else if (aptype==21&&bptype!=21) {
	if (bptype > 0)
	return MH2qg(pn,pb,p1,pa,-qHp1,-qH,mt,include_bottom,mb)*4./9.;
	else
	return MH2qbarg(pn,pb,p1,pa,-qHp1,-qH,mt,include_bottom,mb)*4./9.;
	}
	else if (bptype==21&&aptype!=21) {
	if (aptype > 0)
	return MH2qg(p1,pa,pn,pb,-qH,-qHp1,mt,include_bottom,mb)*4./9.;
	else
	return MH2qbarg(p1,pa,pn,pb,-qH,-qHp1,mt,include_bottom,mb)*4./9.;
	}
	else { // they are both quark
	if (bptype>0) {
	if (aptype>0)
	return MH2qQ(pn,pb,p1,pa,-qHp1,-qH,mt,include_bottom,mb)4.4./(9.*9.);
	else
	return MH2qQbar(pn,pb,p1,pa,-qHp1,-qH,mt,include_bottom,mb)4.4./(9.*9.);
	}
	else {
	if (aptype>0)
	return MH2qQbar(p1,pa,pn,pb,-qH,-qHp1,mt,include_bottom,mb)4.4./(9.*9.);
	else
	return MH2qbarQbar(pn,pb,p1,pa,-qHp1,-qH,mt,include_bottom,mb)4.4./(9.*9.);
	}
	}
	throw std::logic_error("unknown particle types");
	}

	/** \brief Current matrix element squared with Higgs and unordered forward emission
	* @param aptype Particle A PDG ID
	* @param bptype Particle B PDG ID
	* @param punof Unordered Particle Momentum
	* @param pn Particle n Momentum
	* @param pb Particle b Momentum
	* @param p1 Particle 1 Momentum
	* @param pa Particle a Momentum
	* @param qH t-channel momentum before Higgs
	* @param qHp1 t-channel momentum after Higgs
	* @returns ME Squared with Higgs and unordered forward emission
	*/
	double ME_Higgs_current_unof(
	int aptype, int bptype,
	CLHEP::HepLorentzVector const & punof,
	CLHEP::HepLorentzVector const & pn,
	CLHEP::HepLorentzVector const & pb,
	CLHEP::HepLorentzVector const & p1,
	CLHEP::HepLorentzVector const & pa,
	CLHEP::HepLorentzVector const & qH, // t-channel momentum before Higgs
	CLHEP::HepLorentzVector const & qHp1, // t-channel momentum after Higgs
	double mt, bool include_bottom, double mb
	){
	if (aptype==21&&bptype!=21) {
	if (bptype > 0)
	return jM2unogqHg(punof,pn,pb,p1,pa,-qHp1,-qH,mt,include_bottom,mb);
	else
	return jM2unogqbarHg(punof,pn,pb,p1,pa,-qHp1,-qH,mt,include_bottom,mb);
	}
	else { // they are both quark
	if (bptype>0) {
	if (aptype>0)
	return jM2unogqHQ(punof,pn,pb,p1,pa,-qHp1,-qH,mt,include_bottom,mb);
	else
	return jM2unogqHQbar(punof,pn,pb,p1,pa,-qHp1,-qH,mt,include_bottom,mb);
	}
	else {
	if (aptype>0)
	return jM2unogqbarHQ(punof,pn,pb,p1,pa,-qHp1,-qH,mt,include_bottom,mb);
	else
	return jM2unogqbarHQbar(punof,pn,pb,p1,pa,-qHp1,-qH,mt,include_bottom,mb);
	}
	}
	throw std::logic_error("unknown particle types");
	}

	/** \brief Current matrix element squared with Higgs and unordered backward emission
	* @param aptype Particle A PDG ID
	* @param bptype Particle B PDG ID
	* @param pn Particle n Momentum
	* @param pb Particle b Momentum
	* @param punob Unordered back Particle Momentum
	* @param p1 Particle 1 Momentum
	* @param pa Particle a Momentum
	* @param qH t-channel momentum before Higgs
	* @param qHp1 t-channel momentum after Higgs
	* @returns ME Squared with Higgs and unordered backward emission
	*/
	double ME_Higgs_current_unob(
	int aptype, int bptype,
	CLHEP::HepLorentzVector const & pn,
	CLHEP::HepLorentzVector const & pb,
	CLHEP::HepLorentzVector const & punob,
	CLHEP::HepLorentzVector const & p1,
	CLHEP::HepLorentzVector const & pa,
	CLHEP::HepLorentzVector const & qH, // t-channel momentum before Higgs
	CLHEP::HepLorentzVector const & qHp1, // t-channel momentum after Higgs
	double mt, bool include_bottom, double mb
	){
	if (bptype==21&&aptype!=21) {
	if (aptype > 0)
	return jM2unobgHQg(pn,pb,punob,p1,pa,-qHp1,-qH,mt,include_bottom,mb);
	else
	return jM2unobgHQbarg(pn,pb,punob,p1,pa,-qHp1,-qH,mt,include_bottom,mb);
	}
	else { // they are both quark
	if (aptype>0) {
	if (bptype>0)
	return jM2unobqHQg(pn,pb,punob,p1,pa,-qHp1,-qH,mt,include_bottom,mb);
	else
	return jM2unobqbarHQg(pn,pb,punob,p1,pa,-qHp1,-qH,mt,include_bottom,mb);
	}
	else {
	if (bptype>0)
	return jM2unobqHQbarg(pn,pb,punob,p1,pa,-qHp1,-qH,mt,include_bottom,mb);
	else
	return jM2unobqbarHQbarg(pn,pb,punob,p1,pa,-qHp1,-qH,mt,include_bottom,mb);
	}
	}
	throw std::logic_error("unknown particle types");
	}

	CLHEP::HepLorentzVector to_HepLorentzVector(HEJ::Particle const & particle){
	return {particle.p.px(), particle.p.py(), particle.p.pz(), particle.p.E()};
	}

	void validate(HEJ::MatrixElementConfig const & config) {
	#ifndef HEJ_BUILD_WITH_QCDLOOP
	if(!config.Higgs_coupling.use_impact_factors) {
	throw std::invalid_argument{
	"Invalid Higgs coupling settings.\n"
	"HEJ without QCDloop support can only use impact factors.\n"
	"Set use_impact_factors to true or recompile HEJ.\n"
	};
	}
	#endif
	if(config.Higgs_coupling.use_impact_factors
	&& config.Higgs_coupling.mt != std::numeric_limits<double>::infinity()) {
	throw std::invalid_argument{
	"Conflicting settings: "
	"impact factors may only be used in the infinite top mass limit"
	};
	}
	}
	} // namespace anonymous

	namespace HEJ{
	MatrixElement::MatrixElement(
	std::function<double (double)> alpha_s,
	MatrixElementConfig conf
	):
	alpha_s_{std::move(alpha_s)},
	param_{std::move(conf)}
	{
	validate(param_);
	}

	double MatrixElement::tree_kin(
	Event const & ev,
	bool check_momenta
	) const {

	auto AWZH_boson = std::find_if(
	begin(ev.outgoing()), end(ev.outgoing()),
	[](Particle const & p){return is_AWZH_boson(p);}
	);

	if(AWZH_boson == end(ev.outgoing())){
	- return tree_kin_jets(ev.incoming(), ev.outgoing(), check_momenta);
	+ return tree_kin_jets(ev, check_momenta);
	}

	switch(AWZH_boson->type){
	case pid::Higgs: {
	- return tree_kin_Higgs(ev.incoming(), ev.outgoing(), check_momenta);
	+ return tree_kin_Higgs(ev, check_momenta);
	}
	// TODO
	case pid::Wp:
	case pid::Wm:
	case pid::photon:
	case pid::Z:
	default:
	throw std::logic_error("Emission of boson of unsupported type");
	}
	}

	namespace{
	constexpr int extremal_jet_idx = 1;
	constexpr int no_extremal_jet_idx = 0;

	bool treat_as_extremal(Particle const & parton){
	return parton.p.user_index() == extremal_jet_idx;
	}

	template<class InputIterator>
	double FKL_ladder_weight(
	InputIterator begin_gluon, InputIterator end_gluon,
	CLHEP::HepLorentzVector const & q0,
	CLHEP::HepLorentzVector const & pa, CLHEP::HepLorentzVector const & pb,
	CLHEP::HepLorentzVector const & p1, CLHEP::HepLorentzVector const & pn
	){
	double wt = 1;
	auto qi = q0;
	for(auto gluon_it = begin_gluon; gluon_it != end_gluon; ++gluon_it){
	assert(gluon_it->type == pid::gluon);
	const auto g = to_HepLorentzVector(*gluon_it);
	const auto qip1 = qi - g;

	if(treat_as_extremal(*gluon_it)){
	wt = C2Lipatovots(qip1, qi, pa, pb)C_A;
	} else{
	wt = C2Lipatovots(qip1, qi, pa, pb, p1, pn)C_A;
	}

	qi = qip1;
	}
	return wt;
	}

	} // namespace anonymous

	std::vector<Particle> MatrixElement::tag_extremal_jet_partons(
	std::array<Particle, 2> const & incoming,
	std::vector<Particle> out_partons, bool check_momenta
	) const{
	if(!check_momenta){
	for(auto & parton: out_partons){
	parton.p.set_user_index(no_extremal_jet_idx);
	}
	return out_partons;
	}
	fastjet::ClusterSequence cs(to_PseudoJet(out_partons), param_.jet_param.def);
	const auto jets = sorted_by_rapidity(cs.inclusive_jets(param_.jet_param.min_pt));
	assert(jets.size() >= 2);
	auto most_backward = begin(jets);
	auto most_forward = end(jets) - 1;
	// skip jets caused by unordered emission
	if(has_unob_gluon(incoming, out_partons)){
	assert(jets.size() >= 3);
	++most_backward;
	}
	else if(has_unof_gluon(incoming, out_partons)){
	assert(jets.size() >= 3);
	--most_forward;
	}
	const auto extremal_jet_indices = cs.particle_jet_indices(
	{most_backward, most_forward}
	);
	assert(extremal_jet_indices.size() == out_partons.size());
	for(size_t i = 0; i < out_partons.size(); ++i){
	assert(HEJ::is_parton(out_partons[i]));
	const int idx = (extremal_jet_indices[i]>=0)?
	extremal_jet_idx:
	no_extremal_jet_idx;
	out_partons[i].p.set_user_index(idx);
	}
	return out_partons;
	}

	double MatrixElement::tree_kin_jets(
	- std::array<Particle, 2> const & incoming,
	- std::vector<Particle> partons,
	+ Event const & ev,
	bool check_momenta
	) const {
	- partons = tag_extremal_jet_partons(incoming, partons, check_momenta);
	+ auto const & incoming = ev.incoming();
	+ const auto partons = tag_extremal_jet_partons(incoming, ev.outgoing(), check_momenta);
	if(has_unob_gluon(incoming, partons) \|\| has_unof_gluon(incoming, partons)){
	throw not_implemented("unordered emission not implemented for pure jets");
	}

	const auto pa = to_HepLorentzVector(incoming[0]);
	const auto pb = to_HepLorentzVector(incoming[1]);

	const auto p1 = to_HepLorentzVector(partons.front());
	const auto pn = to_HepLorentzVector(partons.back());

	return ME_current(
	incoming[0].type, incoming[1].type,
	pn, pb, p1, pa
	)/(4(N_CN_C - 1))*FKL_ladder_weight(
	begin(partons) + 1, end(partons) - 1,
	pa - p1, pa, pb, p1, pn
	);
	}

	double MatrixElement::tree_kin_Higgs(
	- std::array<Particle, 2> const & incoming,
	- std::vector<Particle> const & outgoing,
	+ Event const & ev,
	bool check_momenta
	) const {
	- if(has_uno_gluon(incoming, outgoing)){
	- return tree_kin_Higgs_between(incoming, outgoing, check_momenta);
	+ if(is_uno(ev.type())){
	+ return tree_kin_Higgs_between(ev, check_momenta);
	}
	- if(outgoing.front().type == pid::Higgs){
	- return tree_kin_Higgs_first(incoming, outgoing, check_momenta);
	+ if(ev.outgoing().front().type == pid::Higgs){
	+ return tree_kin_Higgs_first(ev, check_momenta);
	}
	- if(outgoing.back().type == pid::Higgs){
	- return tree_kin_Higgs_last(incoming, outgoing, check_momenta);
	+ if(ev.outgoing().back().type == pid::Higgs){
	+ return tree_kin_Higgs_last(ev, check_momenta);
	}
	- return tree_kin_Higgs_between(incoming, outgoing, check_momenta);
	+ return tree_kin_Higgs_between(ev, check_momenta);
	}

	namespace {
	// Colour acceleration multipliers, for gluons see eq. (7) in arXiv:0910.5113
	// TODO: code duplication with currents.cc
	double K_g(double p1minus, double paminus) {
	return 1./2.(p1minus/paminus + paminus/p1minus)(C_A - 1./C_A) + 1./C_A;
	}
	double K_g(
	CLHEP::HepLorentzVector const & pout,
	CLHEP::HepLorentzVector const & pin
	) {
	if(pin.z() > 0) return K_g(pout.plus(), pin.plus());
	return K_g(pout.minus(), pin.minus());
	}
	double K(
	ParticleID type,
	CLHEP::HepLorentzVector const & pout,
	CLHEP::HepLorentzVector const & pin
	) {
	if(type == ParticleID::gluon) return K_g(pout, pin);
	return C_F;
	}
	// Colour factor in strict MRK limit
	double K_MRK(ParticleID type) {
	return (type == ParticleID::gluon)?C_A:C_F;
	}
	}

	double MatrixElement::MH2_forwardH(
	CLHEP::HepLorentzVector p1out, CLHEP::HepLorentzVector p1in,
	ParticleID type2,
	CLHEP::HepLorentzVector p2out, CLHEP::HepLorentzVector p2in,
	CLHEP::HepLorentzVector pH,
	double t1, double t2
	) const{
	ignore(p2out, p2in);
	const double shat = p1in.invariantMass2(p2in);
	// gluon case
	#ifdef HEJ_BUILD_WITH_QCDLOOP
	if(!param_.Higgs_coupling.use_impact_factors){
	return K(type2, p2out, p2in)C_A1./(16M_PIM_PI)t1/t2MH2gq_outsideH(
	p1out, p1in, p2out, p2in, pH,
	param_.Higgs_coupling.mt, param_.Higgs_coupling.include_bottom,
	param_.Higgs_coupling.mb
	)/(4(N_CN_C - 1));
	}
	#endif
	return K_MRK(type2)/C_A9./2.shatshat(
	C2gHgp(p1in,p1out,pH) + C2gHgm(p1in,p1out,pH)
	)/(t1*t2);
	}

	double MatrixElement::tree_kin_Higgs_first(
	- std::array<Particle, 2> const & incoming,
	- std::vector<Particle> const & outgoing,
	+ Event const & ev,
	bool check_momenta
	) const {
	+ auto const & incoming = ev.incoming();
	+ auto const & outgoing = ev.outgoing();
	assert(outgoing.front().type == pid::Higgs);
	if(outgoing[1].type != pid::gluon) {
	assert(incoming.front().type == outgoing[1].type);
	- return tree_kin_Higgs_between(incoming, outgoing, check_momenta);
	+ return tree_kin_Higgs_between(ev, check_momenta);
	}
	const auto pH = to_HepLorentzVector(outgoing.front());
	const auto partons = tag_extremal_jet_partons(
	incoming,
	std::vector<Particle>(begin(outgoing) + 1, end(outgoing)),
	check_momenta
	);

	const auto pa = to_HepLorentzVector(incoming[0]);
	const auto pb = to_HepLorentzVector(incoming[1]);

	const auto p1 = to_HepLorentzVector(partons.front());
	const auto pn = to_HepLorentzVector(partons.back());

	const auto q0 = pa - p1 - pH;

	const double t1 = q0.m2();
	const double t2 = (pn - pb).m2();

	return MH2_forwardH(
	p1, pa, incoming[1].type, pn, pb, pH,
	t1, t2
	)*FKL_ladder_weight(
	begin(partons) + 1, end(partons) - 1,
	q0, pa, pb, p1, pn
	);
	}

	double MatrixElement::tree_kin_Higgs_last(
	- std::array<Particle, 2> const & incoming,
	- std::vector<Particle> const & outgoing,
	+ Event const & ev,
	bool check_momenta
	) const {
	+ auto const & incoming = ev.incoming();
	+ auto const & outgoing = ev.outgoing();
	assert(outgoing.back().type == pid::Higgs);
	if(outgoing[outgoing.size()-2].type != pid::gluon) {
	assert(incoming.back().type == outgoing[outgoing.size()-2].type);
	- return tree_kin_Higgs_between(incoming, outgoing, check_momenta);
	+ return tree_kin_Higgs_between(ev, check_momenta);
	}
	const auto pH = to_HepLorentzVector(outgoing.back());
	const auto partons = tag_extremal_jet_partons(
	incoming,
	std::vector<Particle>(begin(outgoing), end(outgoing) - 1),
	check_momenta
	);

	const auto pa = to_HepLorentzVector(incoming[0]);
	const auto pb = to_HepLorentzVector(incoming[1]);

	auto p1 = to_HepLorentzVector(partons.front());
	const auto pn = to_HepLorentzVector(partons.back());

	auto q0 = pa - p1;

	const double t1 = q0.m2();
	const double t2 = (pn + pH - pb).m2();

	return MH2_forwardH(
	pn, pb, incoming[0].type, p1, pa, pH,
	t2, t1
	)*FKL_ladder_weight(
	begin(partons) + 1, end(partons) - 1,
	q0, pa, pb, p1, pn
	);
	}


	double MatrixElement::tree_kin_Higgs_between(
	- std::array<Particle, 2> const & incoming,
	- std::vector<Particle> const & outgoing,
	+ Event const & ev,
	bool check_momenta
	) const {
	+ auto const & incoming = ev.incoming();
	+ auto const & outgoing = ev.outgoing();
	+
	const auto the_Higgs = std::find_if(
	begin(outgoing), end(outgoing),
	[](Particle const & s){ return s.type == pid::Higgs; }
	);
	assert(the_Higgs != end(outgoing));
	const auto pH = to_HepLorentzVector(*the_Higgs);
	std::vector<Particle> partons(begin(outgoing), the_Higgs);
	partons.insert(end(partons), the_Higgs + 1, end(outgoing));
	partons = tag_extremal_jet_partons(incoming, partons, check_momenta);

	const auto pa = to_HepLorentzVector(incoming[0]);
	const auto pb = to_HepLorentzVector(incoming[1]);

	auto p1 = to_HepLorentzVector(
	partons[has_unob_gluon(incoming, outgoing)?1:0]
	);
	auto pn = to_HepLorentzVector(
	partons[partons.size() - (has_unof_gluon(incoming, outgoing)?2:1)]
	);

	auto first_after_Higgs = begin(partons) + (the_Higgs-begin(outgoing));
	assert(
	(first_after_Higgs == end(partons) && (
	has_unob_gluon(incoming, outgoing)
	\|\| partons.back().type != pid::gluon
	))
	\|\| first_after_Higgs->rapidity() >= the_Higgs->rapidity()
	);
	assert(
	(first_after_Higgs == begin(partons) && (
	has_unof_gluon(incoming, outgoing)
	\|\| partons.front().type != pid::gluon
	))
	\|\| (first_after_Higgs-1)->rapidity() <= the_Higgs->rapidity()
	);
	// always treat the Higgs as if it were in between the extremal FKL partons
	if(first_after_Higgs == begin(partons)) ++first_after_Higgs;
	else if(first_after_Higgs == end(partons)) --first_after_Higgs;

	// t-channel momentum before Higgs
	auto qH = pa;
	for(auto parton_it = begin(partons); parton_it != first_after_Higgs; ++parton_it){
	qH -= to_HepLorentzVector(*parton_it);
	}

	auto q0 = pa - p1;
	auto begin_ladder = begin(partons) + 1;
	auto end_ladder = end(partons) - 1;

	double current_factor;
	if(has_unob_gluon(incoming, outgoing)){
	current_factor = C_AC_A/2.ME_Higgs_current_unob( // 1/2 = "K_uno"
	incoming[0].type, incoming[1].type,
	pn, pb, to_HepLorentzVector(partons.front()), p1, pa, qH, qH - pH,
	param_.Higgs_coupling.mt,
	param_.Higgs_coupling.include_bottom, param_.Higgs_coupling.mb
	);
	const auto p_unob = to_HepLorentzVector(partons.front());
	q0 -= p_unob;
	p1 += p_unob;
	++begin_ladder;
	}
	else if(has_unof_gluon(incoming, outgoing)){
	current_factor = C_AC_A/2.ME_Higgs_current_unof( // 1/2 = "K_uno"
	incoming[0].type, incoming[1].type,
	to_HepLorentzVector(partons.back()), pn, pb, p1, pa, qH, qH - pH,
	param_.Higgs_coupling.mt,
	param_.Higgs_coupling.include_bottom, param_.Higgs_coupling.mb
	);
	pn += to_HepLorentzVector(partons.back());
	--end_ladder;
	}
	else{
	current_factor = ME_Higgs_current(
	incoming[0].type, incoming[1].type,
	pn, pb, p1, pa, qH, qH - pH,
	param_.Higgs_coupling.mt,
	param_.Higgs_coupling.include_bottom, param_.Higgs_coupling.mb
	);
	}

	const double ladder_factor = FKL_ladder_weight(
	begin_ladder, first_after_Higgs,
	q0, pa, pb, p1, pn
	)*FKL_ladder_weight(
	first_after_Higgs, end_ladder,
	qH - pH, pa, pb, p1, pn
	);
	return current_factorC_AC_A/(N_CN_C-1.)ladder_factor;
	}

	double MatrixElement::tree_param_partons(
	double alpha_s, double mur,
	std::vector<Particle> const & partons
	) const{
	const double gs2 = 4.M_PIalpha_s;
	double wt = std::pow(gs2, partons.size());
	if(param_.log_correction){
	// use alpha_s(q_perp), evolved to mur
	assert(partons.size() >= 2);
	for(size_t i = 1; i < partons.size()-1; ++i){
	wt = 1 + alpha_s/(2M_PI)beta0log(mur/partons[i].p.perp());
	}
	}
	return wt;
	}

	double MatrixElement::tree_param(
	Event const & ev,
	double mur
	) const{
	assert(is_HEJ(ev.type()));

	const auto & out = ev.outgoing();
	const double alpha_s = alpha_s_(mur);
	auto AWZH_boson = std::find_if(
	begin(out), end(out),
	[](auto const & p){return is_AWZH_boson(p);}
	);
	double AWZH_coupling = 1.;
	if(AWZH_boson != end(out)){
	switch(AWZH_boson->type){
	case pid::Higgs: {
	AWZH_coupling = alpha_s*alpha_s;
	break;
	}
	// TODO
	case pid::Wp:
	case pid::Wm:
	case pid::photon:
	case pid::Z:
	default:
	throw std::logic_error("Emission of boson of unsupported type");
	}
	}
	if(ev.type() == event_type::unob){
	return AWZH_coupling4M_PIalpha_stree_param_partons(
	alpha_s, mur, filter_partons({begin(out) + 1, end(out)})
	);
	}
	if(ev.type() == event_type::unof){
	return AWZH_coupling4M_PIalpha_stree_param_partons(
	alpha_s, mur, filter_partons({begin(out), end(out) - 1})
	);
	}
	return AWZH_coupling*tree_param_partons(alpha_s, mur, filter_partons(out));
	}

	} // namespace HEJ

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