No OneTemporary
Actions

Size

272 KB

Subscribers

None

View Options

This file is larger than 256 KB, so syntax highlighting was skipped.

	diff --git a/include/HEJ/currents.hh b/include/HEJ/currents.hh
	index cd4615b..db2e535 100644
	--- a/include/HEJ/currents.hh
	+++ b/include/HEJ/currents.hh
	@@ -1,1329 +1,1332 @@
	//////////////////////////////////////////////////
	//////////////////////////////////////////////////
	// This source code is Copyright (2012) of //
	// Jeppe R. Andersen and Jennifer M. Smillie //
	// and is distributed under the //
	// Gnu Public License version 2 //
	// http://www.gnu.org/licenses/gpl-2.0.html //
	// You are allowed to distribute and alter the //
	// source under the conditions of the GPLv2 //
	// as long as this copyright notice //
	// is unaltered and distributed with the source //
	// Any use should comply with the //
	// MCNET GUIDELINES //
	// for Event Generator Authors and Users //
	// as distributed with this source code //
	//////////////////////////////////////////////////
	//////////////////////////////////////////////////

	/** \file
	* \brief Functions computing the square of current contractions.
	*
	* This file contains all the necessary functions to compute the current
	* contractions for all valid HEJ processes. PJETS, H+JETS and W+JETS along with
	* some unordered counterparts.
	*
	* @TODO add a namespace
	*/


	#pragma once

	#include <CLHEP/Vector/LorentzVector.h>
	#include <complex>
	#include <vector>
	#include <valarray>
	#include <limits>


	typedef std::complex<double> COM;
	typedef COM current[4];
	typedef CLHEP::HepLorentzVector HLV;

	//! Square of qQ->qenuQ W+Jets Scattering Current
	/**
	* @param p1out Momentum of final state quark
	* @param pe Momentum of final state electron
	* @param pnu Momentum of final state Neutrino
	* @param p1in Momentum of initial state quark
	* @param p2out Momentum of final state quark
	* @param p2in Momentum of intial state quark
	* @returns Square of the current contractions for qQ->qenuQ Scattering
	*
	* This returns the square of the current contractions in qQ->qenuQ scattering
	* with an emission of a W Boson.
	*/
	double jMWqQ (CLHEP::HepLorentzVector p1out, CLHEP::HepLorentzVector pe,
	CLHEP::HepLorentzVector pnu, CLHEP::HepLorentzVector p1in,
	CLHEP::HepLorentzVector p2out, CLHEP::HepLorentzVector p2in);


	//! Square of qbarQ->qbarenuQ W+Jets Scattering Current
	/**
	* @param p1out Momentum of final state anti-quark
	* @param pe Momentum of final state electron
	* @param pnu Momentum of final state Neutrino
	* @param p1in Momentum of initial state anti-quark
	* @param p2out Momentum of final state quark
	* @param p2in Momentum of intial state quark
	* @returns Square of the current contractions for qbarQ->qbarenuQ Scattering
	*
	* This returns the square of the current contractions in qbarQ->qbarenuQ scattering
	* with an emission of a W Boson.
	*/
	double jMWqbarQ (CLHEP::HepLorentzVector p1out, CLHEP::HepLorentzVector pe,
	CLHEP::HepLorentzVector pnu, CLHEP::HepLorentzVector p1in,
	CLHEP::HepLorentzVector p2out, CLHEP::HepLorentzVector p2in);


	//! Square of qQbar->qenuQbar W+Jets Scattering Current
	/**
	* @param p1out Momentum of final state quark
	* @param pe Momentum of final state electron
	* @param pnu Momentum of final state Neutrino
	* @param p1in Momentum of initial state quark
	* @param p2out Momentum of final state anti-quark
	* @param p2in Momentum of intial state anti-quark
	* @returns Square of the current contractions for qQbar->qenuQbar Scattering
	*
	* This returns the square of the current contractions in qQbar->qenuQbar scattering
	* with an emission of a W Boson.
	*/
	double jMWqQbar (CLHEP::HepLorentzVector p1out, CLHEP::HepLorentzVector pe,
	CLHEP::HepLorentzVector pnu, CLHEP::HepLorentzVector p1in,
	CLHEP::HepLorentzVector p2out, CLHEP::HepLorentzVector p2in);


	//! Square of qbarQbar->qbarenuQbar W+Jets Scattering Current
	/**
	* @param p1out Momentum of final state anti-quark
	* @param pe Momentum of final state electron
	* @param pnu Momentum of final state Neutrino
	* @param p1in Momentum of initial state anti-quark
	* @param p2out Momentum of final state anti-quark
	* @param p2in Momentum of intial state anti-quark
	* @returns Square of the current contractions for qbarQbar->qbarenuQbar Scattering
	*
	* This returns the square of the current contractions in qbarQbar->qbarenuQbar scattering
	* with an emission of a W Boson.
	*/
	double jMWqbarQbar (CLHEP::HepLorentzVector p1out, CLHEP::HepLorentzVector pe,
	CLHEP::HepLorentzVector pnu, CLHEP::HepLorentzVector p1in,
	CLHEP::HepLorentzVector p2out, CLHEP::HepLorentzVector p2in);

	//! Square of qg->qenug W+Jets Scattering Current
	/**
	* @param p1out Momentum of final state quark
	* @param pe Momentum of final state electron
	* @param pnu Momentum of final state Neutrino
	* @param p1in Momentum of initial state quark
	* @param p2out Momentum of final state gluon
	* @param p2in Momentum of intial state gluon
	* @returns Square of the current contractions for qg->qenug Scattering
	*
	* This returns the square of the current contractions in qg->qenug scattering
	* with an emission of a W Boson.
	*/
	double jMWqg (CLHEP::HepLorentzVector p1out, CLHEP::HepLorentzVector pe,
	CLHEP::HepLorentzVector pnu, CLHEP::HepLorentzVector p1in,
	CLHEP::HepLorentzVector p2out, CLHEP::HepLorentzVector p2in);

	//! Square of qbarg->qbarenug W+Jets Scattering Current
	/**
	* @param p1out Momentum of final state anti-quark
	* @param pe Momentum of final state electron
	* @param pnu Momentum of final state Neutrino
	* @param p1in Momentum of initial state anti-quark
	* @param p2out Momentum of final state gluon
	* @param p2in Momentum of intial state gluon
	* @returns Square of the current contractions for qbarg->qbarenug Scattering
	*
	* This returns the square of the current contractions in qbarg->qbarenug scattering
	* with an emission of a W Boson.
	*/
	double jMWqbarg (CLHEP::HepLorentzVector p1out, CLHEP::HepLorentzVector pe,
	CLHEP::HepLorentzVector pnu, CLHEP::HepLorentzVector p1in,
	CLHEP::HepLorentzVector p2out, CLHEP::HepLorentzVector p2in);


	// W+Jets Unordered Functions

	//! qQg Wjets Unordered backwards opposite leg to W
	/**
	* @param p1out Momentum of final state quark a
	* @param pe Momentum of final state electron
	* @param pnu Momentum of final state Neutrino
	* @param p1in Momentum of initial state quark a
	* @param p2out Momentum of final state quark b
	* @param p2in Momentum of intial state quark b
	* @param pg Momentum of final state unordered gluon
	* @returns Square of the current contractions for qQ->qQg Scattering
	*
	* This returns the square of the current contractions in qQg->qQg scattering
	* with an emission of a W Boson.
	*/
	double junobMWqQg (CLHEP::HepLorentzVector p1out, CLHEP::HepLorentzVector pe, CLHEP::HepLorentzVector pnu, CLHEP::HepLorentzVector p1in, CLHEP::HepLorentzVector p2out, CLHEP::HepLorentzVector p2in, CLHEP::HepLorentzVector pg);

	//! qbarQg Wjets Unordered backwards opposite leg to W
	/**
	* @param p1out Momentum of final state anti-quark a
	* @param pe Momentum of final state electron
	* @param pnu Momentum of final state Neutrino
	* @param p1in Momentum of initial state anti-quark a
	* @param p2out Momentum of final state quark b
	* @param p2in Momentum of intial state quark b
	* @param pg Momentum of final state unordered gluon
	* @returns Square of the current contractions for qbarQ->qbarQg Scattering
	*
	* This returns the square of the current contractions in qbarQg->qbarQg scattering
	* with an emission of a W Boson.
	*/
	double junobMWqbarQg (CLHEP::HepLorentzVector p1out, CLHEP::HepLorentzVector pe, CLHEP::HepLorentzVector pnu, CLHEP::HepLorentzVector p1in, CLHEP::HepLorentzVector p2out, CLHEP::HepLorentzVector p2in, CLHEP::HepLorentzVector pg);



	//! qQbarg Wjets Unordered backwards opposite leg to W
	/**
	* @param p1out Momentum of final state quark a
	* @param pe Momentum of final state electron
	* @param pnu Momentum of final state Neutrino
	* @param p1in Momentum of initial state quark a
	* @param p2out Momentum of final state anti-quark b
	* @param p2in Momentum of intial state anti-quark b
	* @param pg Momentum of final state unordered gluon
	* @returns Square of the current contractions for qQbar->qQbarg Scattering
	*
	* This returns the square of the current contractions in qQbarg->qQbarg scattering
	* with an emission of a W Boson.
	*/
	double junobMWqQbarg (CLHEP::HepLorentzVector p1out, CLHEP::HepLorentzVector pe, CLHEP::HepLorentzVector pnu, CLHEP::HepLorentzVector p1in, CLHEP::HepLorentzVector p2out, CLHEP::HepLorentzVector p2in, CLHEP::HepLorentzVector pg);

	//! qbarQbarg Wjets Unordered backwards opposite leg to W
	/**
	* @param p1out Momentum of final state anti-quark a
	* @param pe Momentum of final state electron
	* @param pnu Momentum of final state Neutrino
	* @param p1in Momentum of initial state anti-quark a
	* @param p2out Momentum of final state anti-quark b
	* @param p2in Momentum of intial state anti-quark b
	* @param pg Momentum of final state unordered gluon
	* @returns Square of the current contractions for qbarQbar->qbarQbarg Scattering
	*
	* This returns the square of the current contractions in qbarQbarg->qbarQbarg scattering
	* with an emission of a W Boson.
	*/
	double junobMWqbarQbarg (CLHEP::HepLorentzVector p1out, CLHEP::HepLorentzVector pe, CLHEP::HepLorentzVector pnu, CLHEP::HepLorentzVector p1in, CLHEP::HepLorentzVector p2out, CLHEP::HepLorentzVector p2in, CLHEP::HepLorentzVector pg);


	//!Wjets Unordered forwards opposite leg to W
	/**
	* @param pg Momentum of final state unordered gluon
	* @param p1out Momentum of final state quark a
	* @param pe Momentum of final state electron
	* @param pnu Momentum of final state Neutrino
	* @param p1in Momentum of initial state quark a
	* @param p2out Momentum of final state quark b
	* @param p2in Momentum of intial state quark b
	* @returns Square of the current contractions for qQ->gqQ Scattering
	*
	* This returns the square of the current contractions in qQg->gqQ scattering
	* with an emission of a W Boson.
	*/
	double junofMWgqQ (CLHEP::HepLorentzVector pg,CLHEP::HepLorentzVector p1out, CLHEP::HepLorentzVector p1in, CLHEP::HepLorentzVector p2out, CLHEP::HepLorentzVector pe, CLHEP::HepLorentzVector pnu, CLHEP::HepLorentzVector p2in);

	//!Wjets Unordered forwards opposite leg to W
	/**
	* @param pg Momentum of final state unordered gluon
	* @param p1out Momentum of final state anti-quark a
	* @param pe Momentum of final state electron
	* @param pnu Momentum of final state Neutrino
	* @param p1in Momentum of initial state anti-quark a
	* @param p2out Momentum of final state quark b
	* @param p2in Momentum of intial state quark b
	* @returns Square of the current contractions for qbarQ->gqbarQ Scattering
	*
	* This returns the square of the current contractions in qbarQg->gqbarQ scattering
	* with an emission of a W Boson.
	*/
	double junofMWgqbarQ (CLHEP::HepLorentzVector pg,CLHEP::HepLorentzVector p1out, CLHEP::HepLorentzVector p1in, CLHEP::HepLorentzVector p2out, CLHEP::HepLorentzVector pe, CLHEP::HepLorentzVector pnu, CLHEP::HepLorentzVector p2in);

	//!Wjets Unordered forwards opposite leg to W
	/**
	* @param pg Momentum of final state unordered gluon
	* @param p1out Momentum of final state quark a
	* @param pe Momentum of final state electron
	* @param pnu Momentum of final state Neutrino
	* @param p1in Momentum of initial state quark a
	* @param p2out Momentum of final state anti-quark b
	* @param p2in Momentum of intial state anti-quark b
	* @returns Square of the current contractions for qQbar->gqQbar Scattering
	*
	* This returns the square of the current contractions in qQbarg->gqQbar scattering
	* with an emission of a W Boson.
	*/
	double junofMWgqQbar (CLHEP::HepLorentzVector pg,CLHEP::HepLorentzVector p1out, CLHEP::HepLorentzVector p1in, CLHEP::HepLorentzVector p2out, CLHEP::HepLorentzVector pe, CLHEP::HepLorentzVector pnu, CLHEP::HepLorentzVector p2in);

	//!Wjets Unordered forwards opposite leg to W
	/**
	* @param pg Momentum of final state unordered gluon
	* @param p1out Momentum of final state anti-quark a
	* @param pe Momentum of final state electron
	* @param pnu Momentum of final state Neutrino
	* @param p1in Momentum of initial state anti-quark a
	* @param p2out Momentum of final state anti-quark b
	* @param p2in Momentum of intial state anti-quark b
	* @returns Square of the current contractions for qbarQbar->gqbarQbar Scattering
	*
	* This returns the square of the current contractions in qbarQbarg->gqbarQbar scattering
	* with an emission of a W Boson.
	*/
	double junofMWgqbarQbar (CLHEP::HepLorentzVector pg,CLHEP::HepLorentzVector p1out, CLHEP::HepLorentzVector p1in, CLHEP::HepLorentzVector p2out, CLHEP::HepLorentzVector pe, CLHEP::HepLorentzVector pnu, CLHEP::HepLorentzVector p2in);

	//!W+uno same leg
	/**
	* @param pg Momentum of final state unordered gluon
	* @param p1out Momentum of final state quark a
	* @param plbar Momentum of final state anti-lepton
	* @param pl Momentum of final state lepton
	* @param p1in Momentum of initial state quark a
	* @param p2out Momentum of final state quark b
	* @param p2in Momentum of intial state quark b
	* @returns Square of the current contractions for qQ->qQg Scattering
	*
	* This returns the square of the current contractions in gqQ->gqQ scattering
	* with an emission of a W Boson.
	*/
	double jM2WunogqQ(CLHEP::HepLorentzVector pg, CLHEP::HepLorentzVector p1out,CLHEP::HepLorentzVector plbar,CLHEP::HepLorentzVector pl, CLHEP::HepLorentzVector p1in, CLHEP::HepLorentzVector p2out, CLHEP::HepLorentzVector p2in);

	//! @TODO What does this function do? Crossed contribution is Exqqx..?
	/**
	* @param pg Momentum of final state unordered gluon
	* @param p1out Momentum of final state quark a
	* @param plbar Momentum of final state anti-lepton
	* @param pl Momentum of final state lepton
	* @param p1in Momentum of initial state quark a
	* @param p2out Momentum of final state quark b
	* @param p2in Momentum of intial state quark b
	* @returns Square of the current contractions for qQ->gqQ Scattering
	*
	* This returns the square of the current contractions in gqQ->gqQ scattering
	* with an emission of a W Boson.
	*/
	double jM2WunogqQ_crossqQ(CLHEP::HepLorentzVector pg, CLHEP::HepLorentzVector p1out,CLHEP::HepLorentzVector plbar,CLHEP::HepLorentzVector pl, CLHEP::HepLorentzVector p1in, CLHEP::HepLorentzVector p2out, CLHEP::HepLorentzVector p2in);

	//! W+uno same leg. quark anti-quark
	/**
	* @param pg Momentum of final state unordered gluon
	* @param p1out Momentum of final state quark a
	* @param plbar Momentum of final state anti-lepton
	* @param pl Momentum of final state lepton
	* @param p1in Momentum of initial state quark a
	* @param p2out Momentum of final state anti-quark b
	* @param p2in Momentum of intial state anti-quark b
	* @returns Square of the current contractions for qQbar->gqQbar Scattering
	*
	* This returns the square of the current contractions in gqQbar->gqQbar scattering
	* with an emission of a W Boson. (Unordered Same Leg)
	*/
	double jM2WunogqQbar(CLHEP::HepLorentzVector pg, CLHEP::HepLorentzVector p1out,CLHEP::HepLorentzVector plbar,CLHEP::HepLorentzVector pl, CLHEP::HepLorentzVector p1in, CLHEP::HepLorentzVector p2out, CLHEP::HepLorentzVector p2in);

	//! W+uno same leg. quark gluon
	/**
	* @param pg Momentum of final state unordered gluon
	* @param p1out Momentum of final state quark a
	* @param plbar Momentum of final state anti-lepton
	* @param pl Momentum of final state lepton
	* @param p1in Momentum of initial state quark a
	* @param p2out Momentum of final state gluon b
	* @param p2in Momentum of intial state gluon b
	* @returns Square of the current contractions for qg->gqg Scattering
	*
	* This returns the square of the current contractions in qg->gqg scattering
	* with an emission of a W Boson.
	*/
	double jM2Wunogqg(CLHEP::HepLorentzVector pg, CLHEP::HepLorentzVector p1out,CLHEP::HepLorentzVector plbar,CLHEP::HepLorentzVector pl, CLHEP::HepLorentzVector p1in, CLHEP::HepLorentzVector p2out, CLHEP::HepLorentzVector p2in);

	//! W+uno same leg. anti-quark quark
	/**
	* @param pg Momentum of final state unordered gluon
	* @param p1out Momentum of final state anti-quark a
	* @param plbar Momentum of final state anti-lepton
	* @param pl Momentum of final state lepton
	* @param p1in Momentum of initial state anti-quark a
	* @param p2out Momentum of final state quark b
	* @param p2in Momentum of intial state quark b
	* @returns Square of the current contractions for qbarQ->gqbarQ Scattering
	*
	* This returns the square of the current contractions in qbarQ->gqbarQ scattering
	* with an emission of a W Boson.
	*/
	double jM2WunogqbarQ(CLHEP::HepLorentzVector pg, CLHEP::HepLorentzVector p1out,CLHEP::HepLorentzVector plbar,CLHEP::HepLorentzVector pl, CLHEP::HepLorentzVector p1in, CLHEP::HepLorentzVector p2out, CLHEP::HepLorentzVector p2in);

	//! W+uno same leg. anti-quark anti-quark
	/**
	* @param pg Momentum of final state unordered gluon
	* @param p1out Momentum of final state anti-quark a
	* @param plbar Momentum of final state anti-lepton
	* @param pl Momentum of final state lepton
	* @param p1in Momentum of initial state anti-quark a
	* @param p2out Momentum of final state anti-quark b
	* @param p2in Momentum of intial state anti-quark b
	* @returns Square of the current contractions for qbarQbar->gqbarQbar Scattering
	*
	* This returns the square of the current contractions in gqbarQbar->qbarQbar scattering
	* with an emission of a W Boson.
	*/
	double jM2WunogqbarQbar(CLHEP::HepLorentzVector pg, CLHEP::HepLorentzVector p1out,CLHEP::HepLorentzVector plbar,CLHEP::HepLorentzVector pl, CLHEP::HepLorentzVector p1in, CLHEP::HepLorentzVector p2out, CLHEP::HepLorentzVector p2in);

	//! W+uno same leg. anti-quark gluon
	/**
	* @param pg Momentum of final state unordered gluon
	* @param p1out Momentum of final state anti-quark a
	* @param plbar Momentum of final state anti-lepton
	* @param pl Momentum of final state lepton
	* @param p1in Momentum of initial state anti-quark a
	* @param p2out Momentum of final state gluon b
	* @param p2in Momentum of intial state gluon b
	* @returns Square of the current contractions for ->gqbarg Scattering
	*
	* This returns the square of the current contractions in qbarg->gqbarg scattering
	* with an emission of a W Boson.
	*/
	double jM2Wunogqbarg(CLHEP::HepLorentzVector pg, CLHEP::HepLorentzVector p1out,CLHEP::HepLorentzVector plbar,CLHEP::HepLorentzVector pl, CLHEP::HepLorentzVector p1in, CLHEP::HepLorentzVector p2out, CLHEP::HepLorentzVector p2in);

	//W+Jets qqxExtremal
	//! W+Extremal qqx. qxqQ
	/**
	* @param pgin Momentum of initial state gluon
	* @param pqout Momentum of final state quark a
	* @param plbar Momentum of final state anti-lepton
	* @param pl Momentum of final state lepton
	* @param pqbarout Momentum of final state anti-quark a
	* @param p2out Momentum of initial state anti-quark b
	* @param p2in Momentum of final state gluon b
	* @returns Square of the current contractions for ->qbarqQ Scattering
	*
	* Calculates the square of the current contractions with extremal qqbar pair
	* production. This is calculated through the use of crossing symmetry.
	*/
	double jM2WgQtoqbarqQ(CLHEP::HepLorentzVector pgin, CLHEP::HepLorentzVector pqout,CLHEP::HepLorentzVector plbar,CLHEP::HepLorentzVector pl, CLHEP::HepLorentzVector pqbarout, CLHEP::HepLorentzVector p2out, CLHEP::HepLorentzVector p2in);

	//W+Jets qqxExtremal
	//! W+Extremal qqx. qqxQ
	/**
	* @param pgin Momentum of initial state gluon
	* @param pqout Momentum of final state quark a
	* @param plbar Momentum of final state anti-lepton
	* @param pl Momentum of final state lepton
	* @param pqbarout Momentum of final state anti-quark a
	* @param p2out Momentum of initial state anti-quark b
	* @param p2in Momentum of final state gluon b
	* @returns Square of the current contractions for ->qqbarQ Scattering
	*
	* Calculates the square of the current contractions with extremal qqbar pair
	* production. This is calculated through the use of crossing symmetry.
	*/
	double jM2WgQtoqqbarQ(CLHEP::HepLorentzVector pgin, CLHEP::HepLorentzVector pqout,CLHEP::HepLorentzVector plbar,CLHEP::HepLorentzVector pl, CLHEP::HepLorentzVector pqbarout, CLHEP::HepLorentzVector p2out, CLHEP::HepLorentzVector p2in);

	//W+Jets qqxExtremal
	//! W+Extremal qqx. gg->qxqg
	/**
	* @param pgin Momentum of initial state gluon
	* @param pqout Momentum of final state quark a
	* @param plbar Momentum of final state anti-lepton
	* @param pl Momentum of final state lepton
	* @param pqbarout Momentum of final state anti-quark a
	* @param p2out Momentum of initial state gluon b
	* @param p2in Momentum of final state gluon b
	* @returns Square of the current contractions for gg->qbarqg Scattering
	*
	* Calculates the square of the current contractions with extremal qqbar pair
	* production. This is calculated through the use of crossing symmetry.
	*/
	double jM2Wggtoqbarqg(CLHEP::HepLorentzVector pgin, CLHEP::HepLorentzVector pqout,CLHEP::HepLorentzVector plbar,CLHEP::HepLorentzVector pl, CLHEP::HepLorentzVector pqbarout, CLHEP::HepLorentzVector p2out, CLHEP::HepLorentzVector p2in);

	//W+Jets qqxExtremal
	//! W+Extremal qqx. gg->qqxg
	/**
	* @param pgin Momentum of initial state gluon
	* @param pqout Momentum of final state quark a
	* @param plbar Momentum of final state anti-lepton
	* @param pl Momentum of final state lepton
	* @param pqbarout Momentum of final state anti-quark a
	* @param p2out Momentum of initial state gluon a
	* @param p2in Momentum of final state gluon b
	* @returns Square of the current contractions for gg->qqbarg Scattering
	*
	* Calculates the square of the current contractions with extremal qqbar pair
	* production. This is calculated through the use of crossing symmetry.
	*/
	double jM2Wggtoqqbarg(CLHEP::HepLorentzVector pgin, CLHEP::HepLorentzVector pqbarout,CLHEP::HepLorentzVector plbar,CLHEP::HepLorentzVector pl, CLHEP::HepLorentzVector pqout, CLHEP::HepLorentzVector p2out, CLHEP::HepLorentzVector p2in);

	//W+Jets qqxExtremal, W emission from opposite leg
	//! W+Extremal qqx. gg->qqxg. qqx on forwards leg, W emission backwards leg.
	/**
	* @param pa Momentum of initial state (anti-)quark
	* @param pb Momentum of initial state gluon
	* @param p1 Momentum of final state (anti-)quark (after W emission)
	* @param p2 Momentum of final state anti-quark
	* @param p3 Momentum of final state quark
	* @param plbar Momentum of final state anti-lepton
	* @param pl Momentum of final state lepton
	* @param aqlinepa Is opposite extremal leg to qqx a quark or antiquark line
	* @returns Square of the current contractions for gq->qqbarqW Scattering
	*
	* Calculates the square of the current contractions with extremal qqbar pair
	* production. This is calculated via current contraction of existing currents.
	* Assumes qqx split from forwards leg, W emission from backwards leg.
	* Switch input (pa<->pb, p1<->pn) if calculating forwards qqx.
	*/
	double jM2WgqtoQQqW(CLHEP::HepLorentzVector pa, CLHEP::HepLorentzVector pb, CLHEP::HepLorentzVector p1, CLHEP::HepLorentzVector p2, CLHEP::HepLorentzVector p3,CLHEP::HepLorentzVector plbar,CLHEP::HepLorentzVector pl, bool aqlinepa);

	//! W+Jets qqxCentral. qqx W emission.
	/**
	* @param pa Momentum of initial state particle a
	* @param pb Momentum of initial state particle b
	* @param pl Momentum of final state lepton
	* @param plbar Momentum of final state anti-lepton
	* @param partons Vector of outgoing parton momenta
	* @param aqlinepa Bool: True= pa is anti-quark
	* @param aqlinepb Bool: True= pb is anti-quark
	* @param qqxmarker Bool: Ordering of the qqbar pair produced (qqx vs qxq)
	* @param nabove Number of lipatov vertices "above" qqbar pair
	* @param nbelow Number of lipatov vertices "below" qqbar pair
	* @returns Square of the current contractions for qq>qQQbarWq Scattering
	*
	* Calculates the square of the current contractions with extremal qqbar pair
	* production. This is calculated through the use of crossing symmetry.
	*/
	double jM2WqqtoqQQq(HLV pa, HLV pb,HLV pl,HLV plbar, std::vector<HLV> partons, bool aqlinepa, bool aqlinepb, bool qqxmarker, int nabove);
	//emission from backwards leg

	//! W+Jets qqxCentral. W emission from backwards leg.
	/**
	* @param ka HLV: Momentum of initial state particle a
	* @param kb HLV: Momentum of initial state particle b
	* @param pl HLV: Momentum of final state lepton
	* @param plbar HLV: Momentum of final state anti-lepton
	* @param partons Vector(HLV): outgoing parton momenta
	* @param aqlinepa Bool: True= pa is anti-quark
	* @param aqlinepb Bool: True= pb is anti-quark
	* @param qqxmarker Bool: Ordering of the qqbar pair produced (qqx vs qxq)
	* @param nabove Int: Number of lipatov vertices "above" qqbar pair
	* @param nbelow Int: Number of lipatov vertices "below" qqbar pair
	* @param forwards Bool: Swap to emission off front leg TODO:remove so args can be const
	* @returns Square of the current contractions for qq>qQQbarWq Scattering
	*
	* Calculates the square of the current contractions with extremal qqbar pair
	* production. This is calculated through the use of crossing symmetry.
	*/
	double jM2WqqtoqQQqW(HLV ka, HLV kb,HLV pl,HLV plbar, std::vector<HLV> partons, bool aqlinepa, bool aqlinepb, bool qqxmarker, int nabove, int nbelow, bool forwards); //Doing



	//! Square of qQ->qQ Pure Jets Scattering Current
	/**
	* @param p1out Momentum of final state quark
	* @param p1in Momentum of initial state quark
	* @param p2out Momentum of final state quark
	* @param p2in Momentum of intial state quark
	* @returns Square of the current contractions for qQ->qQ Scattering
	*
	* This returns the square of the current contractions in qQ->qQ Pure Jet Scattering.
	*/
	double jM2qQ (CLHEP::HepLorentzVector p1out, CLHEP::HepLorentzVector p1in,
	CLHEP::HepLorentzVector p2out, CLHEP::HepLorentzVector p2in);


	//! Square of qQbar->qQbar Pure Jets Scattering Current
	/**
	* @param p1out Momentum of final state quark
	* @param p1in Momentum of initial state quark
	* @param p2out Momentum of final state anti-quark
	* @param p2in Momentum of intial state anti-quark
	* @returns Square of the current contractions for qQbar->qQbar Scattering
	*
	* This returns the square of the current contractions in qQbar->qQbar Pure Jet Scattering.
	* Note this can be used for qbarQ->qbarQ Scattering by inputting arguments appropriately.
	*/
	double jM2qQbar (CLHEP::HepLorentzVector p1out, CLHEP::HepLorentzVector p1in,
	CLHEP::HepLorentzVector p2out, CLHEP::HepLorentzVector p2in);


	//! Square of qbarQbar->qbarQbar Pure Jets Scattering Current
	/**
	* @param p1out Momentum of final state anti-quark
	* @param p1in Momentum of initial state anti-quark
	* @param p2out Momentum of final state anti-quark
	* @param p2in Momentum of intial state anti-quark
	* @returns Square of the current contractions for qbarQbar->qbarQbar Scattering
	*
	* This returns the square of the current contractions in qbarQbar->qbarQbar Pure Jet Scattering.
	*/
	double jM2qbarQbar (CLHEP::HepLorentzVector p1out, CLHEP::HepLorentzVector p1in,
	CLHEP::HepLorentzVector p2out, CLHEP::HepLorentzVector p2in);


	//! Square of qg->qg Pure Jets Scattering Current
	/**
	* @param p1out Momentum of final state quark
	* @param p1in Momentum of initial state quark
	* @param p2out Momentum of final state gluon
	* @param p2in Momentum of intial state gluon
	* @returns Square of the current contractions for qg->qg Scattering
	*
	* This returns the square of the current contractions in qg->qg Pure Jet Scattering.
	* Note this can be used for gq->gq Scattering by inputting arguments appropriately.
	*/
	double jM2qg (CLHEP::HepLorentzVector p1out, CLHEP::HepLorentzVector p1in,
	CLHEP::HepLorentzVector p2out, CLHEP::HepLorentzVector p2in);


	//! Square of qbarg->qbarg Pure Jets Scattering Current
	/**
	* @param p1out Momentum of final state anti-quark
	* @param p1in Momentum of initial state anti-quark
	* @param p2out Momentum of final state gluon
	* @param p2in Momentum of intial state gluon
	* @returns Square of the current contractions for qbarg->qbarg Scattering
	*
	* This returns the square of the current contractions in qbarg->qbarg Pure Jet Scattering.
	* Note this can be used for gqbar->gqbar Scattering by inputting arguments appropriately.
	*/
	double jM2qbarg (CLHEP::HepLorentzVector p1out, CLHEP::HepLorentzVector p1in,
	CLHEP::HepLorentzVector p2out, CLHEP::HepLorentzVector p2in);


	//! Square of gg->gg Pure Jets Scattering Current
	/**
	* @param p1out Momentum of final state gluon
	* @param p1in Momentum of initial state gluon
	* @param p2out Momentum of final state gluon
	* @param p2in Momentum of intial state gluon
	* @returns Square of the current contractions for gg->gg Scattering
	*
	* This returns the square of the current contractions in gg->gg Pure Jet Scattering.
	*/
	double jM2gg (CLHEP::HepLorentzVector p1out, CLHEP::HepLorentzVector p1in,
	CLHEP::HepLorentzVector p2out, CLHEP::HepLorentzVector p2in);


	//! Square of gg->gg Higgs+Jets Scattering Current
	/**
	* @param p1out Momentum of final state gluon
	* @param p1in Momentum of initial state gluon
	* @param p2out Momentum of final state gluon
	* @param p2in Momentum of intial state gluon
	* @param q1 Momentum of t-channel propagator before Higgs
	* @param qH2 Momentum of t-channel propagator after Higgs
	* @param mt Top quark mass
	* @param include_bottom Specifies whether bottom corrections are included
	* @param mb Bottom quark mass
	* @returns Square of the current contractions for gg->gg Scattering
	*
	* This returns the square of the current contractions in gg->gg Higgs+Jet Scattering.
	*
	* g~p1 g~p2
	* should be called with q1 meant to be contracted with p2 in first part of vertex
	* (i.e. if g is backward, q1 is forward)
	*/
	double MH2gg (CLHEP::HepLorentzVector p1out, CLHEP::HepLorentzVector p1in,
	CLHEP::HepLorentzVector p2out, CLHEP::HepLorentzVector p2in,
	CLHEP::HepLorentzVector q1, CLHEP::HepLorentzVector qH2,
	double mt,
	bool include_bottom, double mb);

	//! Square of gq->gq Higgs+Jets Scattering Current with Higgs before Gluon
	/**
	* @param p1out Momentum of final state gluon
	* @param p1in Momentum of initial state gluon
	* @param p2out Momentum of final state gluon
	* @param p2in Momentum of intial state gluon
	* @param pH Momentum of Higgs
	* @param mt Top quark mass
	* @param include_bottom Specifies whether bottom corrections are included
	* @param mb Bottom quark mass
	* @returns Square of the current contraction
	*
	*/
	double MH2gq_outsideH(CLHEP::HepLorentzVector p1out, CLHEP::HepLorentzVector p1in,
	CLHEP::HepLorentzVector p2out, CLHEP::HepLorentzVector p2in,
	CLHEP::HepLorentzVector pH,
	double mt,
	bool include_bottom, double mb);


	//! Square of qg->qg Higgs+Jets Scattering Current
	/**
	* @param p1out Momentum of final state quark
	* @param p1in Momentum of initial state quark
	* @param p2out Momentum of final state gluon
	* @param p2in Momentum of intial state gluon
	* @param q1 Momentum of t-channel propagator before Higgs
	* @param qH2 Momentum of t-channel propagator after Higgs
	* @param mt Top quark mass
	* @param include_bottom Specifies whether bottom corrections are included
	* @param mb Bottom quark mass
	* @returns Square of the current contractions for qg->qg Scattering
	*
	* This returns the square of the current contractions in qg->qg Higgs+Jet Scattering.
	*
	* q~p1 g~p2 (i.e. ALWAYS p1 for quark, p2 for gluon)
	* should be called with q1 meant to be contracted with p2 in first part of vertex
	* (i.e. if g is backward, q1 is forward)
	*/
	double MH2qg (CLHEP::HepLorentzVector p1out, CLHEP::HepLorentzVector p1in,
	CLHEP::HepLorentzVector p2out, CLHEP::HepLorentzVector p2in,
	CLHEP::HepLorentzVector q1, CLHEP::HepLorentzVector qH2,
	double mt,
	bool include_bottom, double mb);


	//! Square of qbarg->qbarg Higgs+Jets Scattering Current
	/**
	* @param p1out Momentum of final state anti-quark
	* @param p1in Momentum of initial state anti-quark
	* @param p2out Momentum of final state gluon
	* @param p2in Momentum of intial state gluon
	* @param q1 Momentum of t-channel propagator before Higgs
	* @param qH2 Momentum of t-channel propagator after Higgs
	* @param mt Top quark mass
	* @param include_bottom Specifies whether bottom corrections are included
	* @param mb Bottom quark mass
	* @returns Square of the current contractions for qbarg->qbarg Scattering
	*
	* This returns the square of the current contractions in qbarg->qbarg Higgs+Jet Scattering.
	*
	* qbar~p1 g~p2 (i.e. ALWAYS p1 for anti-quark, p2 for gluon)
	* should be called with q1 meant to be contracted with p2 in first part of vertex
	* (i.e. if g is backward, q1 is forward)
	*/
	double MH2qbarg (CLHEP::HepLorentzVector p1out, CLHEP::HepLorentzVector p1in,
	CLHEP::HepLorentzVector p2out, CLHEP::HepLorentzVector p2in,
	CLHEP::HepLorentzVector q1, CLHEP::HepLorentzVector qH2,
	double mt,
	bool include_bottom, double mb);


	//! Square of qQ->qQ Higgs+Jets Scattering Current
	/**
	* @param p1out Momentum of final state quark
	* @param p1in Momentum of initial state quark
	* @param p2out Momentum of final state quark
	* @param p2in Momentum of intial state quark
	* @param q1 Momentum of t-channel propagator before Higgs
	* @param qH2 Momentum of t-channel propagator after Higgs
	* @param mt Top quark mass
	* @param include_bottom Specifies whether bottom corrections are included
	* @param mb Bottom quark mass
	* @returns Square of the current contractions for qQ->qQ Scattering
	*
	* This returns the square of the current contractions in qQ->qQ Higgs+Jet Scattering.
	*
	* q~p1 Q~p2 (i.e. ALWAYS p1 for quark, p2 for quark)
	* should be called with q1 meant to be contracted with p2 in first part of vertex
	* (i.e. if Q is backward, q1 is forward)
	*/
	double MH2qQ (CLHEP::HepLorentzVector p1out, CLHEP::HepLorentzVector p1in,
	CLHEP::HepLorentzVector p2out, CLHEP::HepLorentzVector p2in,
	CLHEP::HepLorentzVector q1, CLHEP::HepLorentzVector qH2,
	double mt,
	bool include_bottom, double mb);

	//! Square of qQbar->qQbar Higgs+Jets Scattering Current
	/**
	* @param p1out Momentum of final state quark
	* @param p1in Momentum of initial state quark
	* @param p2out Momentum of final state anti-quark
	* @param p2in Momentum of intial state anti-quark
	* @param q1 Momentum of t-channel propagator before Higgs
	* @param qH2 Momentum of t-channel propagator after Higgs
	* @param mt Top quark mass
	* @param include_bottom Specifies whether bottom corrections are included
	* @param mb Bottom quark mass
	* @returns Square of the current contractions for qQ->qQ Scattering
	*
	* This returns the square of the current contractions in qQbar->qQbar Higgs+Jet Scattering.
	*
	* q~p1 Qbar~p2 (i.e. ALWAYS p1 for quark, p2 for anti-quark)
	* should be called with q1 meant to be contracted with p2 in first part of vertex
	* (i.e. if Qbar is backward, q1 is forward)
	*/
	double MH2qQbar (CLHEP::HepLorentzVector p1out, CLHEP::HepLorentzVector p1in,
	CLHEP::HepLorentzVector p2out, CLHEP::HepLorentzVector p2in,
	CLHEP::HepLorentzVector q1, CLHEP::HepLorentzVector qH2,
	double mt,
	bool include_bottom, double mb);

	//! Square of qbarQ->qbarQ Higgs+Jets Scattering Current
	/**
	* @param p1out Momentum of final state anti-quark
	* @param p1in Momentum of initial state anti-quark
	* @param p2out Momentum of final state quark
	* @param p2in Momentum of intial state quark
	* @param q1 Momentum of t-channel propagator before Higgs
	* @param qH2 Momentum of t-channel propagator after Higgs
	* @param mt Top quark mass
	* @param include_bottom Specifies whether bottom corrections are included
	* @param mb Bottom quark mass
	* @returns Square of the current contractions for qbarQ->qbarQ Scattering
	*
	* This returns the square of the current contractions in qbarQ->qbarQ Higgs+Jet Scattering.
	*
	* qbar~p1 Q~p2 (i.e. ALWAYS p1 for anti-quark, p2 for quark)
	* should be called with q1 meant to be contracted with p2 in first part of vertex
	* (i.e. if Q is backward, q1 is forward)
	*/
	double MH2qbarQ (CLHEP::HepLorentzVector p1out, CLHEP::HepLorentzVector p1in,
	CLHEP::HepLorentzVector p2out, CLHEP::HepLorentzVector p2in,
	CLHEP::HepLorentzVector q1, CLHEP::HepLorentzVector qH2,
	double mt,
	bool include_bottom, double mb);


	//! Square of qbarQbar->qbarQbar Higgs+Jets Scattering Current
	/**
	* @param p1out Momentum of final state anti-quark
	* @param p1in Momentum of initial state anti-quark
	* @param p2out Momentum of final state anti-quark
	* @param p2in Momentum of intial state anti-quark
	* @param q1 Momentum of t-channel propagator before Higgs
	* @param qH2 Momentum of t-channel propagator after Higgs
	* @param mt Top quark mass
	* @param include_bottom Specifies whether bottom corrections are included
	* @param mb Bottom quark mass
	* @returns Square of the current contractions for qbarQbar->qbarQbar Scattering
	*
	* This returns the square of the current contractions in qbarQbar->qbarQbar Higgs+Jet Scattering.
	*
	* qbar~p1 Qbar~p2 (i.e. ALWAYS p1 for anti-quark, p2 for anti-quark)
	* should be called with q1 meant to be contracted with p2 in first part of vertex
	* (i.e. if Qbar is backward, q1 is forward)
	*/
	double MH2qbarQbar (CLHEP::HepLorentzVector p1out, CLHEP::HepLorentzVector p1in,
	CLHEP::HepLorentzVector p2out, CLHEP::HepLorentzVector p2in,
	CLHEP::HepLorentzVector q1, CLHEP::HepLorentzVector qH2,
	double mt,
	bool include_bottom, double mb);


	// Unordered f

	//! Square of qQ->gqQ Higgs+Jets Unordered f Scattering Current
	/**
	* @param pg Momentum of unordered gluon
	* @param p1out Momentum of final state quark
	* @param p1in Momentum of initial state quark
	* @param p2out Momentum of final state quark
	* @param p2in Momentum of intial state quark
	* @param qH1 Momentum of t-channel propagator before Higgs
	* @param qH2 Momentum of t-channel propagator after Higgs
	* @param mt Top quark mass
	* @param include_bottom Specifies whether bottom corrections are included
	* @param mb Bottom quark mass
	* @returns Square of the current contractions for qQ->gqQ Scattering
	*
	* This returns the square of the current contractions in qQ->gqQ Higgs+Jet Scattering.
	*
	* This construction is taking rapidity order: pg > p1out >> p2out
	*/
	double jM2unogqHQ (CLHEP::HepLorentzVector pg, CLHEP::HepLorentzVector p1out,
	CLHEP::HepLorentzVector p1in, CLHEP::HepLorentzVector p2out,
	CLHEP::HepLorentzVector p2in, CLHEP::HepLorentzVector qH1,
	CLHEP::HepLorentzVector qH2,
	double mt,
	bool include_bottom, double mb);


	//! Square of qQbar->gqQbar Higgs+Jets Unordered f Scattering Current
	/**
	* @param pg Momentum of unordered gluon
	* @param p1out Momentum of final state quark
	* @param p1in Momentum of initial state quark
	* @param p2out Momentum of final state anti-quark
	* @param p2in Momentum of intial state anti-quark
	* @param qH1 Momentum of t-channel propagator before Higgs
	* @param qH2 Momentum of t-channel propagator after Higgs
	* @param mt Top quark mass
	* @param include_bottom Specifies whether bottom corrections are included
	* @param mb Bottom quark mass
	* @returns Square of the current contractions for qQbar->gqQbar Scattering
	*
	* This returns the square of the current contractions in qQbar->gqQbar Higgs+Jet Scattering.
	*
	* This construction is taking rapidity order: pg > p1out >> p2out
	*/
	double jM2unogqHQbar (CLHEP::HepLorentzVector pg, CLHEP::HepLorentzVector p1out,
	CLHEP::HepLorentzVector p1in, CLHEP::HepLorentzVector p2out,
	CLHEP::HepLorentzVector p2in, CLHEP::HepLorentzVector qH1,
	CLHEP::HepLorentzVector qH2,
	double mt,
	bool include_bottom, double mb);

	//! Square of qbarQ->gqbarQ Higgs+Jets Unordered f Scattering Current
	/**
	* @param pg Momentum of unordered gluon
	* @param p1out Momentum of final state anti-quark
	* @param p1in Momentum of initial state anti-quark
	* @param p2out Momentum of final state quark
	* @param p2in Momentum of intial state quark
	* @param qH1 Momentum of t-channel propagator before Higgs
	* @param qH2 Momentum of t-channel propagator after Higgs
	* @param mt Top quark mass
	* @param include_bottom Specifies whether bottom corrections are included
	* @param mb Bottom quark mass
	* @returns Square of the current contractions for qbarQ->gqbarQ Scattering
	*
	* This returns the square of the current contractions in qbarQ->gqbarQ Higgs+Jet Scattering.
	*
	* This construction is taking rapidity order: pg > p1out >> p2out
	*/
	double jM2unogqbarHQ (CLHEP::HepLorentzVector pg, CLHEP::HepLorentzVector p1out,
	CLHEP::HepLorentzVector p1in, CLHEP::HepLorentzVector p2out,
	CLHEP::HepLorentzVector p2in, CLHEP::HepLorentzVector qH1,
	CLHEP::HepLorentzVector qH2,
	double mt,
	bool include_bottom, double mb);

	//! Square of qbarQbar->gqbarQbar Higgs+Jets Unordered f Scattering Current
	/**
	* @param pg Momentum of unordered gluon
	* @param p1out Momentum of final state anti-quark
	* @param p1in Momentum of initial state anti-quark
	* @param p2out Momentum of final state anti-quark
	* @param p2in Momentum of intial state anti-quark
	* @param qH1 Momentum of t-channel propagator before Higgs
	* @param qH2 Momentum of t-channel propagator after Higgs
	* @param mt Top quark mass
	* @param include_bottom Specifies whether bottom corrections are included
	* @param mb Bottom quark mass
	* @returns Square of the current contractions for qbarQbar->gqbarQbar Scattering
	*
	* This returns the square of the current contractions in qbarQbar->gqbarQbar Higgs+Jet Scattering.
	*
	* This construction is taking rapidity order: pg > p1out >> p2out
	*/
	double jM2unogqbarHQbar (CLHEP::HepLorentzVector pg, CLHEP::HepLorentzVector p1out,
	CLHEP::HepLorentzVector p1in, CLHEP::HepLorentzVector p2out,
	CLHEP::HepLorentzVector p2in, CLHEP::HepLorentzVector qH1,
	CLHEP::HepLorentzVector qH2,
	double mt,
	bool include_bottom, double mb);


	//! Square of qg->gqg Higgs+Jets Unordered f Scattering Current
	/**
	* @param pg Momentum of unordered gluon
	* @param p1out Momentum of final state quark
	* @param p1in Momentum of initial state quark
	* @param p2out Momentum of final state gluon
	* @param p2in Momentum of intial state gluon
	* @param qH1 Momentum of t-channel propagator before Higgs
	* @param qH2 Momentum of t-channel propagator after Higgs
	* @param mt Top quark mass
	* @param include_bottom Specifies whether bottom corrections are included
	* @param mb Bottom quark mass
	* @returns Square of the current contractions for qg->gqg Scattering
	*
	* This returns the square of the current contractions in qg->gqg Higgs+Jet Scattering.
	*
	* This construction is taking rapidity order: pg > p1out >> p2out
	*/
	double jM2unogqHg (CLHEP::HepLorentzVector pg, CLHEP::HepLorentzVector p1out,
	CLHEP::HepLorentzVector p1in, CLHEP::HepLorentzVector p2out,
	CLHEP::HepLorentzVector p2in, CLHEP::HepLorentzVector qH1,
	CLHEP::HepLorentzVector qH2,
	double mt,
	bool include_bottom, double mb);


	//! Square of qbarg->gqbarg Higgs+Jets Unordered f Scattering Current
	/**
	* @param pg Momentum of unordered gluon
	* @param p1out Momentum of final state anti-quark
	* @param p1in Momentum of initial state anti-quark
	* @param p2out Momentum of final state gluon
	* @param p2in Momentum of intial state gluon
	* @param qH1 Momentum of t-channel propagator before Higgs
	* @param qH2 Momentum of t-channel propagator after Higgs
	* @param mt Top quark mass
	* @param include_bottom Specifies whether bottom corrections are included
	* @param mb Bottom quark mass
	* @returns Square of the current contractions for qbarg->gbarg Scattering
	*
	* This returns the square of the current contractions in qbarg->gqbarg Higgs+Jet Scattering.
	*
	* This construction is taking rapidity order: pg > p1out >> p2out
	*/
	double jM2unogqbarHg (CLHEP::HepLorentzVector pg, CLHEP::HepLorentzVector p1out,
	CLHEP::HepLorentzVector p1in, CLHEP::HepLorentzVector p2out,
	CLHEP::HepLorentzVector p2in, CLHEP::HepLorentzVector qH1,
	CLHEP::HepLorentzVector qH2,
	double mt,
	bool include_bottom, double mb);


	//Unordered b

	//! Square of qbarQ->qbarQg Higgs+Jets Unordered b Scattering Current
	/**
	* @param p1out Momentum of final state anti-quark
	* @param p1in Momentum of initial state anti-quark
	* @param pg Momentum of unordered b gluon
	* @param p2out Momentum of final state quark
	* @param p2in Momentum of intial state quark
	* @param qH1 Momentum of t-channel propagator before Higgs
	* @param qH2 Momentum of t-channel propagator after Higgs
	* @param mt Top quark mass
	* @param include_bottom Specifies whether bottom corrections are included
	* @param mb Bottom quark mass
	* @returns Square of the current contractions for qbarQ->qbarQg Scattering
	*
	* This returns the square of the current contractions in qbarQ->qbarQg Higgs+Jet Scattering.
	*
	* This construction is taking rapidity order: p1out >> p2out > pg
	*/
	double jM2unobqbarHQg (CLHEP::HepLorentzVector p1out, CLHEP::HepLorentzVector p1in,
	CLHEP::HepLorentzVector pg, CLHEP::HepLorentzVector p2out,
	CLHEP::HepLorentzVector p2in, CLHEP::HepLorentzVector qH1,
	CLHEP::HepLorentzVector qH2,
	double mt,
	bool include_bottom, double mb);


	//! Square of qQ->qQg Higgs+Jets Unordered b Scattering Current
	/**
	* @param p1out Momentum of final state quark
	* @param p1in Momentum of initial state quark
	* @param pg Momentum of unordered b gluon
	* @param p2out Momentum of final state quark
	* @param p2in Momentum of intial state quark
	* @param qH1 Momentum of t-channel propagator before Higgs
	* @param qH2 Momentum of t-channel propagator after Higgs
	* @param mt Top quark mass
	* @param include_bottom Specifies whether bottom corrections are included
	* @param mb Bottom quark mass
	* @returns Square of the current contractions for qQ->qQg Scattering
	*
	* This returns the square of the current contractions in qQ->qQg Higgs+Jet Scattering.
	*
	* This construction is taking rapidity order: p1out >> p2out > pg
	*/
	double jM2unobqHQg (CLHEP::HepLorentzVector p1out, CLHEP::HepLorentzVector p1in,
	CLHEP::HepLorentzVector pg, CLHEP::HepLorentzVector p2out,
	CLHEP::HepLorentzVector p2in, CLHEP::HepLorentzVector qH1,
	CLHEP::HepLorentzVector qH2,
	double mt,
	bool include_bottom, double mb);


	//! Square of qQbar->qQbarg Higgs+Jets Unordered b Scattering Current
	/**
	* @param p1out Momentum of final state quark
	* @param p1in Momentum of initial state quark
	* @param pg Momentum of unordered b gluon
	* @param p2out Momentum of final state anti-quark
	* @param p2in Momentum of intial state anti-quark
	* @param qH1 Momentum of t-channel propagator before Higgs
	* @param qH2 Momentum of t-channel propagator after Higgs
	* @param mt Top quark mass
	* @param include_bottom Specifies whether bottom corrections are included
	* @param mb Bottom quark mass
	* @returns Square of the current contractions for qQbar->qQbarg Scattering
	*
	* This returns the square of the current contractions in qQbar->qQbarg Higgs+Jet Scattering.
	*
	* This construction is taking rapidity order: p1out >> p2out > pg
	*/
	double jM2unobqHQbarg (CLHEP::HepLorentzVector p1out, CLHEP::HepLorentzVector p1in,
	CLHEP::HepLorentzVector pg, CLHEP::HepLorentzVector p2out,
	CLHEP::HepLorentzVector p2in, CLHEP::HepLorentzVector qH1,
	CLHEP::HepLorentzVector qH2,
	double mt,
	bool include_bottom, double mb);

	//! Square of qbarQbar->qbarQbarg Higgs+Jets Unordered b Scattering Current
	/**
	* @param p1out Momentum of final state anti-quark
	* @param p1in Momentum of initial state anti-quark
	* @param pg Momentum of unordered b gluon
	* @param p2out Momentum of final state anti-quark
	* @param p2in Momentum of intial state anti-quark
	* @param qH1 Momentum of t-channel propagator before Higgs
	* @param qH2 Momentum of t-channel propagator after Higgs
	* @param mt Top quark mass
	* @param include_bottom Specifies whether bottom corrections are included
	* @param mb Bottom quark mass
	* @returns Square of the current contractions for qbarQbar->qbarQbarg Scattering
	*
	* This returns the square of the current contractions in qbarQbar->qbarQbarg Higgs+Jet Scattering.
	*
	* This construction is taking rapidity order: p1out >> p2out > pg
	*/
	double jM2unobqbarHQbarg (CLHEP::HepLorentzVector p1out, CLHEP::HepLorentzVector p1in,
	CLHEP::HepLorentzVector pg, CLHEP::HepLorentzVector p2out,
	CLHEP::HepLorentzVector p2in, CLHEP::HepLorentzVector qH1,
	CLHEP::HepLorentzVector qH2,
	double mt,
	bool include_bottom, double mb);


	//! Square of gQbar->gQbarg Higgs+Jets Unordered b Scattering Current
	/**
	* @param p1out Momentum of final state gluon
	* @param p1in Momentum of initial state gluon
	* @param pg Momentum of unordered b gluon
	* @param p2out Momentum of final state anti-quark
	* @param p2in Momentum of intial state anti-quark
	* @param qH1 Momentum of t-channel propagator before Higgs
	* @param qH2 Momentum of t-channel propagator after Higgs
	* @param mt Top quark mass
	* @param include_bottom Specifies whether bottom corrections are included
	* @param mb Bottom quark mass
	* @returns Square of the current contractions for gQbar->gQbarg Scattering
	*
	* This returns the square of the current contractions in gQbar->gQbarg Higgs+Jet Scattering.
	*
	* This construction is taking rapidity order: p1out >> p2out > pg
	*/
	double jM2unobgHQbarg (CLHEP::HepLorentzVector p1out, CLHEP::HepLorentzVector p1in,
	CLHEP::HepLorentzVector pg, CLHEP::HepLorentzVector p2out,
	CLHEP::HepLorentzVector p2in, CLHEP::HepLorentzVector qH1,
	CLHEP::HepLorentzVector qH2,
	double mt,
	bool include_bottom, double mb);

	//! Square of gQ->gQg Higgs+Jets Unordered b Scattering Current
	/**
	* @param p1out Momentum of final state gluon
	* @param p1in Momentum of initial state gluon
	* @param pg Momentum of unordered b gluon
	* @param p2out Momentum of final state quark
	* @param p2in Momentum of intial state quark
	* @param qH1 Momentum of t-channel propagator before Higgs
	* @param qH2 Momentum of t-channel propagator after Higgs
	* @param mt Top quark mass
	* @param include_bottom Specifies whether bottom corrections are included
	* @param mb Bottom quark mass
	* @returns Square of the current contractions for gQ->gQg Scattering
	*
	* This returns the square of the current contractions in gQ->gQg Higgs+Jet Scattering.
	*
	* This construction is taking rapidity order: p1out >> p2out > pg
	*/
	double jM2unobgHQg (CLHEP::HepLorentzVector p1out, CLHEP::HepLorentzVector p1in,
	CLHEP::HepLorentzVector pg, CLHEP::HepLorentzVector p2out,
	CLHEP::HepLorentzVector p2in, CLHEP::HepLorentzVector qH1,
	CLHEP::HepLorentzVector qH2,
	double mt,
	bool include_bottom, double mb);

	// impact factors for Higgs + jet


	//! Implements Eq. (4.22) in hep-ph/0301013 with modifications to incoming plus momenta
	/**
	* @param p2 Momentum of Particle 2
	* @param p1 Momentum of Particle 1
	* @param pH Momentum of Higgs
	* @returns Value of Eq. (4.22) in Hep-ph/0301013 with modifications
	*
	* This gives the impact factor. First it determines first whether this is the case
	* p1p\sim php>>p3p or the opposite
	*/
	double C2gHgm(CLHEP::HepLorentzVector p2, CLHEP::HepLorentzVector p1,
	CLHEP::HepLorentzVector pH);


	//! Implements Eq. (4.23) in hep-ph/0301013 with modifications to incoming plus momenta
	/**
	* @param p2 Momentum of Particle 2
	* @param p1 Momentum of Particle 1
	* @param pH Momentum of Higgs
	* @returns Value of Eq. (4.23) in Hep-ph/0301013
	*
	* This gives the impact factor. First it determines first whether this is the case
	* p1p\sim php>>p3p or the opposite
	*/
	double C2gHgp(CLHEP::HepLorentzVector p2, CLHEP::HepLorentzVector p1,
	CLHEP::HepLorentzVector pH);


	//! Implements Eq. (4.22) in hep-ph/0301013
	/**
	* @param p2 Momentum of Particle 2
	* @param p1 Momentum of Particle 1
	* @param pH Momentum of Higgs
	* @returns Value of Eq. (4.22) in Hep-ph/0301013
	*
	* This gives the impact factor. First it determines first whether this is the case
	* p1p\sim php>>p3p or the opposite
	*/
	double C2qHqm(CLHEP::HepLorentzVector p2, CLHEP::HepLorentzVector p1,
	CLHEP::HepLorentzVector pH);

	/** \class CCurrent currents.hh "include/HEJ/currents.hh"
	* \brief This is the a new class structure for currents.
	*/
	class CCurrent
	{
	public:
	CCurrent(COM sc0, COM sc1, COM sc2, COM sc3)
	:c0(sc0),c1(sc1),c2(sc2),c3(sc3)
	{};
	CCurrent(const CLHEP::HepLorentzVector p)
	{
	c0=p.e();
	c1=p.px();
	c2=p.py();
	c3=p.pz();
	};
	CCurrent()
	{};
	CCurrent operator+(const CCurrent& other);
	CCurrent operator-(const CCurrent& other);
	CCurrent operator*(const double x);
	CCurrent operator*(const COM x);
	CCurrent operator/(const double x);
	CCurrent operator/(const COM x);

	friend std::ostream& operator<<(std::ostream& os, const CCurrent& cur);
	COM dot(CLHEP::HepLorentzVector p1);
	COM dot(CCurrent p1);
	COM c0,c1,c2,c3;
	private:
	};

	/* std::ostream& operator <<(std::ostream& os, const CCurrent& cur); */
	CCurrent operator * ( double x, CCurrent& m);
	CCurrent operator * ( COM x, CCurrent& m);
	CCurrent operator / ( double x, CCurrent& m);
	CCurrent operator / ( COM x, CCurrent& m);


	//! Current <outgoing state \| mu \| incoming state>
	/**
	* These functions are a mess. There are many more defined in the source file than declared in the
	* header - and the arguments are mislabelled in some cases. Need to investigate.
	*/
	//! @TODO remove
	[[deprecated("Use joi instead")]]
	void j (CLHEP::HepLorentzVector pout, bool helout, CLHEP::HepLorentzVector pin, bool helin,current &cur);

	//! Current <incoming state \| mu \| outgoing state>
	/**
	* These functions are a mess. There are many more defined in the source file than declared in the
	* header - and the arguments are mislabelled in some cases. Need to investigate.
	*/
	void jio(HLV pin, bool helin, HLV pout, bool helout, current &cur);

	//! Current <outgoing state \| mu \| outgoing state>
	/**
	* These functions are a mess. There are many more defined in the source file than declared in the
	* header - and the arguments are mislabelled in some cases. Need to investigate.
	*/
	void joo(HLV pi, bool heli, HLV pj, bool helj, current &cur);

	//! Current <outgoing state \| mu \| incoming state>
	/**
	* These functions are a mess. There are many more defined in the source file than declared in the
	* header - and the arguments are mislabelled in some cases. Need to investigate.
	*/
	void joi(HLV pout, bool helout, HLV pin, bool helin, current &cur);

	//! Current <outgoing state \| mu \| incoming state>
	/**
	* These functions are a mess. There are many more defined in the source file than declared in the
	* header - and the arguments are mislabelled in some cases. Need to investigate.
	*/
	//! @TODO remove
	[[deprecated("Use joi instead")]]
	CCurrent j (CLHEP::HepLorentzVector pout, bool helout, CLHEP::HepLorentzVector pin, bool helin);

	//! Current <outgoing state \| mu \| incoming state>
	/**
	* These functions are a mess. There are many more defined in the source file than declared in the
	* header - and the arguments are mislabelled in some cases. Need to investigate.
	*/
	CCurrent joi (CLHEP::HepLorentzVector pout, bool helout, CLHEP::HepLorentzVector pin, bool helin);

	//! Current <incoming state \| mu \| outgoing state>
	/**
	* These functions are a mess. There are many more defined in the source file than declared in the
	* header - and the arguments are mislabelled in some cases. Need to investigate.
	*/
	CCurrent jio (CLHEP::HepLorentzVector pout, bool helout, CLHEP::HepLorentzVector pin, bool helin);

	//! Current <outgoing state \| mu \| outgoing state>
	/**
	* These functions are a mess. There are many more defined in the source file than declared in the
	* header - and the arguments are mislabelled in some cases. Need to investigate.
	*/
	CCurrent joo (CLHEP::HepLorentzVector pout, bool helout, CLHEP::HepLorentzVector pin, bool helin);

	inline COM cdot(const current & j1, const current & j2)
	{
	return j1[0]j2[0]-j1[1]j2[1]-j1[2]j2[2]-j1[3]j2[3];
	}

	inline COM cdot(const HLV & p, const current & j1) {
	return j1[0]p.e()-j1[1]p.x()-j1[2]p.y()-j1[3]p.z();
	}

	inline void cmult(const COM & factor, const current & j1, current &cur)
	{
	cur[0]=factor*j1[0];
	cur[1]=factor*j1[1];
	cur[2]=factor*j1[2];
	cur[3]=factor*j1[3];
	}

	// WHY!?!
	inline void cadd(const current & j1, const current & j2, const current & j3,
	const current & j4, const current & j5, current &sum)
	{
	sum[0]=j1[0]+j2[0]+j3[0]+j4[0]+j5[0];
	sum[1]=j1[1]+j2[1]+j3[1]+j4[1]+j5[1];
	sum[2]=j1[2]+j2[2]+j3[2]+j4[2]+j5[2];
	sum[3]=j1[3]+j2[3]+j3[3]+j4[3]+j5[3];
	}

	inline void cadd(const current & j1, const current & j2, const current & j3,
	const current & j4, current &sum) {
	sum[0] = j1[0] + j2[0] + j3[0] + j4[0];
	sum[1] = j1[1] + j2[1] + j3[1] + j4[1];
	sum[2] = j1[2] + j2[2] + j3[2] + j4[2];
	sum[3] = j1[3] + j2[3] + j3[3] + j4[3];
	}

	inline void cadd(const current & j1, const current & j2, const current & j3,
	current &sum)
	{
	sum[0]=j1[0]+j2[0]+j3[0];
	sum[1]=j1[1]+j2[1]+j3[1];
	sum[2]=j1[2]+j2[2]+j3[2];
	sum[3]=j1[3]+j2[3]+j3[3];
	}

	inline void cadd(const current & j1, const current & j2, current &sum)
	{
	sum[0]=j1[0]+j2[0];
	sum[1]=j1[1]+j2[1];
	sum[2]=j1[2]+j2[2];
	sum[3]=j1[3]+j2[3];
	}

	inline double abs2(const COM & a)
	{
	return (a*conj(a)).real();
	}

	inline double vabs2(const CCurrent & cur)
	{
	return abs2(cur.c0)-abs2(cur.c1)-abs2(cur.c2)-abs2(cur.c3);
	}

	inline double vre(const CCurrent & a, const CCurrent & b)
	{
	return real(a.c0conj(b.c0)-a.c1conj(b.c1)-a.c2conj(b.c2)-a.c3conj(b.c3));
	}
	+// @TODO: These are not currents and should be moved elsewhere.
	+double K_g(double p1minus, double paminus);
	+double K_g(CLHEP::HepLorentzVector const & pout, CLHEP::HepLorentzVector const & pin);
	diff --git a/src/Wjets.cc b/src/Wjets.cc
	index 3fa3871..f621f63 100644
	--- a/src/Wjets.cc
	+++ b/src/Wjets.cc
	@@ -1,1715 +1,2005 @@
	#include "HEJ/currents.hh"
	#include "HEJ/utility.hh"
	#include "HEJ/Tensor.hh"
	#include "HEJ/Constants.hh"

	#include <array>

	#include <iostream>



	namespace { // Helper Functions
	// FKL W Helper Functions
	+ void jW (CLHEP::HepLorentzVector pout, bool helout, CLHEP::HepLorentzVector pe, bool hele, CLHEP::HepLorentzVector pnu, bool helnu, CLHEP::HepLorentzVector pin, bool helin, current cur)
	+ {
	+ // NOTA BENE: Conventions for W+ --> e+ nu, so that nu is lepton(6), e is anti-lepton(5)
	+ // Need to swap e and nu for events with W- --> e- nubar!
	+ if (helin==helout && hele==helnu) {
	+ CLHEP::HepLorentzVector qa=pout+pe+pnu;
	+ CLHEP::HepLorentzVector qb=pin-pe-pnu;
	+ double ta(qa.m2()),tb(qb.m2());
	+
	+ current t65,vout,vin,temp2,temp3,temp5;
	+ joo(pnu,helnu,pe,hele,t65);
	+ vout[0]=pout.e();
	+ vout[1]=pout.x();
	+ vout[2]=pout.y();
	+ vout[3]=pout.z();
	+ vin[0]=pin.e();
	+ vin[1]=pin.x();
	+ vin[2]=pin.y();
	+ vin[3]=pin.z();
	+
	+ COM brac615=cdot(t65,vout);
	+ COM brac645=cdot(t65,vin);
	+
	+ // prod1565 and prod6465 are zero for Ws (not Zs)!!
	+ // noalias(temp)=prod(trans(CurrentOutOut(pout,helout,pnu,helout)),metric);
	+ joo(pout,helout,pnu,helout,temp2);
	+ // noalias(temp2)=prod(temp,ctemp);
	+ COM prod1665=cdot(temp2,t65);
	+ // noalias(temp)=prod(trans(Current(pe,helin,pin,helin)),metric);
	+ // noalias(temp2)=prod(temp,ctemp);
	+ joi(pe,helin,pin,helin,temp3);
	+ COM prod5465=cdot(temp3,t65);
	+ // noalias(temp)=prod(trans(Current(pnu,helin,pin,helin)),metric);
	+ // noalias(temp2)=prod(temp,ctemp);
	+
	+ joo(pout,helout,pe,helout,temp2);
	+ joi(pnu,helnu,pin,helin,temp3);
	+ joi(pout,helout,pin,helin,temp5);
	+
	+ current term1,term2,term3,sum;
	+ cmult(2.brac615/ta+2.brac645/tb,temp5,term1);
	+ cmult(prod1665/ta,temp3,term2);
	+ cmult(-prod5465/tb,temp2,term3);
	+
	+ // cur=((2.brac615Current(pout,helout,pin,helin)+prod1565Current(pe,helin,pin,helin)+prod1665Current(pnu,helin,pin,helin))/ta + (2.brac645Current(pout,helout,pin,helin)-prod5465CurrentOutOut(pout,helout,pe,helout)-prod6465CurrentOutOut(pout,helout,pnu,helout))/tb);
	+ // cur=((2.brac615temp5+prod1565temp3+prod1665temp4)/ta + (2.brac645temp5-prod5465temp1-prod6465temp2)/tb);
	+ cadd(term1,term2,term3,sum);
	+ // std::cout<<"sum: ("<<sum[0]<<","<<sum[1]<<","<<sum[2]<<","<<sum[3]<<")\n";
	+ cur[0]=sum[0];
	+ cur[1]=sum[1];
	+ cur[2]=sum[2];
	+ cur[3]=sum[3];
	+ }
	+ }
	+
	+ void jWbar (CLHEP::HepLorentzVector pout, bool helout, CLHEP::HepLorentzVector pe, bool hele, CLHEP::HepLorentzVector pnu, bool helnu, CLHEP::HepLorentzVector pin, bool helin, current cur)
	+ {
	+ // NOTA BENE: Conventions for W+ --> e+ nu, so that nu is lepton(6), e is anti-lepton(5)
	+ // Need to swap e and nu for events with W- --> e- nubar!
	+ if (helin==helout && hele==helnu) {
	+ CLHEP::HepLorentzVector qa=pout+pe+pnu;
	+ CLHEP::HepLorentzVector qb=pin-pe-pnu;
	+ double ta(qa.m2()),tb(qb.m2());
	+
	+ current t65,vout,vin,temp2,temp3,temp5;
	+ joo(pnu,helnu,pe,hele,t65);
	+ vout[0]=pout.e();
	+ vout[1]=pout.x();
	+ vout[2]=pout.y();
	+ vout[3]=pout.z();
	+ vin[0]=pin.e();
	+ vin[1]=pin.x();
	+ vin[2]=pin.y();
	+ vin[3]=pin.z();
	+
	+ COM brac615=cdot(t65,vout);
	+ COM brac645=cdot(t65,vin);
	+
	+ // prod1565 and prod6465 are zero for Ws (not Zs)!!
	+ joo(pe,helout,pout,helout,temp2); // temp2 is <5\|alpha\|1>
	+ COM prod5165=cdot(temp2,t65);
	+ jio(pin,helin,pnu,helin,temp3); // temp3 is <4\|alpha\|6>
	+ COM prod4665=cdot(temp3,t65);
	+
	+ joo(pnu,helout,pout,helout,temp2); // temp2 is now <6\|mu\|1>
	+ jio(pin,helin,pe,helin,temp3); // temp3 is now <4\|mu\|5>
	+ jio(pin,helin,pout,helout,temp5); // temp5 is <4\|mu\|1>
	+
	+ current term1,term2,term3,sum;
	+ cmult(-2.brac615/ta-2.brac645/tb,temp5,term1);
	+ cmult(-prod5165/ta,temp3,term2);
	+ cmult(prod4665/tb,temp2,term3);
	+
	+ // cur=((2.brac615Current(pout,helout,pin,helin)+prod1565Current(pe,helin,pin,helin)+prod1665Current(pnu,helin,pin,helin))/ta + (2.brac645Current(pout,helout,pin,helin)-prod5465CurrentOutOut(pout,helout,pe,helout)-prod6465CurrentOutOut(pout,helout,pnu,helout))/tb);
	+ // cur=((2.brac615temp5+prod1565temp3+prod1665temp4)/ta + (2.brac645temp5-prod5465temp1-prod6465temp2)/tb);
	+ cadd(term1,term2,term3,sum);
	+ // std::cout<<"term1: ("<<temp5[0]<<" "<<temp5[1]<<" "<<temp5[2]<<" "<<temp5[3]<<")"<<std::endl;
	+ // std::cout<<"sum: ("<<sum[0]<<","<<sum[1]<<","<<sum[2]<<","<<sum[3]<<")\n";
	+ cur[0]=sum[0];
	+ cur[1]=sum[1];
	+ cur[2]=sum[2];
	+ cur[3]=sum[3];
	+ }
	+ }
	+
	+
	CCurrent jW (CLHEP::HepLorentzVector pout, bool helout, CLHEP::HepLorentzVector pe, bool hele, CLHEP::HepLorentzVector pnu, bool helnu, CLHEP::HepLorentzVector pin, bool helin)
	{

	COM cur[4];

	cur[0]=0.;
	cur[1]=0.;
	cur[2]=0.;
	cur[3]=0.;
	CCurrent sum(0.,0.,0.,0.);

	// NOTA BENE: Conventions for W+ --> e+ nu, so that nu is lepton(6), e is anti-lepton(5)
	// Need to swap e and nu for events with W- --> e- nubar!
	if (helin==helout && hele==helnu) {
	CLHEP::HepLorentzVector qa=pout+pe+pnu;
	CLHEP::HepLorentzVector qb=pin-pe-pnu;
	double ta(qa.m2()),tb(qb.m2());

	CCurrent temp2,temp3,temp5;
	CCurrent t65 = joo(pnu,helnu,pe,hele);
	CCurrent vout(pout.e(),pout.x(),pout.y(),pout.z());
	CCurrent vin(pin.e(),pin.x(),pin.y(),pin.z());

	COM brac615=t65.dot(vout);
	COM brac645=t65.dot(vin);


	// prod1565 and prod6465 are zero for Ws (not Zs)!!
	temp2 = joo(pout,helout,pnu,helout);
	COM prod1665=temp2.dot(t65);
	temp3 = j(pe,helin,pin,helin);
	COM prod5465=temp3.dot(t65);

	temp2=joo(pout,helout,pe,helout);
	temp3=j(pnu,helnu,pin,helin);
	temp5=j(pout,helout,pin,helin);

	CCurrent term1,term2,term3;
	term1=(2.brac615/ta+2.brac645/tb)*temp5;
	term2=(prod1665/ta)*temp3;
	term3=(-prod5465/tb)*temp2;

	sum=term1+term2+term3;
	}

	return sum;
	}

	CCurrent jWbar (CLHEP::HepLorentzVector pout, bool helout, CLHEP::HepLorentzVector pe, bool hele, CLHEP::HepLorentzVector pnu, bool helnu, CLHEP::HepLorentzVector pin, bool helin)
	{

	COM cur[4];

	cur[0]=0.;
	cur[1]=0.;
	cur[2]=0.;
	cur[3]=0.;
	CCurrent sum(0.,0.,0.,0.);

	// NOTA BENE: Conventions for W+ --> e+ nu, so that nu is lepton(6), e is anti-lepton(5)
	// Need to swap e and nu for events with W- --> e- nubar!
	if (helin==helout && hele==helnu) {
	CLHEP::HepLorentzVector qa=pout+pe+pnu;
	CLHEP::HepLorentzVector qb=pin-pe-pnu;
	double ta(qa.m2()),tb(qb.m2());

	CCurrent temp2,temp3,temp5;
	CCurrent t65 = joo(pnu,helnu,pe,hele);
	CCurrent vout(pout.e(),pout.x(),pout.y(),pout.z());
	CCurrent vin(pin.e(),pin.x(),pin.y(),pin.z());

	COM brac615=t65.dot(vout);
	COM brac645=t65.dot(vin);

	// prod1565 and prod6465 are zero for Ws (not Zs)!!
	temp2 = joo(pe,helout,pout,helout); // temp2 is <5\|alpha\|1>
	COM prod5165=temp2.dot(t65);
	temp3 = jio(pin,helin,pnu,helin); // temp3 is <4\|alpha\|6>
	COM prod4665=temp3.dot(t65);

	temp2=joo(pnu,helout,pout,helout); // temp2 is now <6\|mu\|1>
	temp3=jio(pin,helin,pe,helin); // temp3 is now <4\|mu\|5>
	temp5=jio(pin,helin,pout,helout); // temp5 is <4\|mu\|1>

	CCurrent term1,term2,term3;
	term1 =(-2.brac615/ta-2.brac645/tb)*temp5;
	term2 =(-prod5165/ta)*temp3;
	term3 =(prod4665/tb)*temp2;

	sum = term1 + term2 + term3;
	}

	return sum;
	}


	// Extremal quark current with W emission. Using Tensor class rather than CCurrent
	Tensor <1,4> jW(HLV pin, HLV pout, HLV plbar, HLV pl, bool aqline){
	// Build the external quark line W Emmision
	Tensor<1,4> ABCurr = TCurrent(pl, false, plbar, false);
	Tensor<1,4> Tp4W = Construct1Tensor((pout+pl+plbar));//p4+pw
	Tensor<1,4> TpbW = Construct1Tensor((pin-pl-plbar));//pb-pw

	Tensor<3,4> J4bBlank;
	if (aqline){
	J4bBlank = T3Current(pin,false,pout,false);
	}
	else{
	J4bBlank = T3Current(pout,false,pin,false);
	}
	double t4AB = (pout+pl+plbar).m2();
	double tbAB = (pin-pl-plbar).m2();

	Tensor<2,4> J4b1 = (J4bBlank.contract(Tp4W,2))/t4AB;
	Tensor<2,4> J4b2 = (J4bBlank.contract(TpbW,2))/tbAB;

	Tensor<2,4> T4bmMom(0.);

	if (aqline){
	for(int mu=0; mu<4;mu++){
	for(int nu=0;nu<4;nu++){
	T4bmMom.Set(mu,nu, (J4b1.at(nu,mu) + J4b2.at(mu,nu))*(COM(-1,0)));
	}
	}
	}
	else{
	for(int mu=0; mu<4;mu++){
	for(int nu=0;nu<4;nu++){
	T4bmMom.Set(nu,mu, (J4b1.at(nu,mu) + J4b2.at(mu,nu)));
	}
	}
	}
	Tensor<1,4> T4bm = T4bmMom.contract(ABCurr,1);

	return T4bm;
	}



	// Relevant W+Jets Unordered Contribution Helper Functions
	// W+Jets Uno
	double jM2Wuno(CLHEP::HepLorentzVector pg, CLHEP::HepLorentzVector p1,CLHEP::HepLorentzVector plbar, CLHEP::HepLorentzVector pl, CLHEP::HepLorentzVector pa, bool h1, CLHEP::HepLorentzVector p2, CLHEP::HepLorentzVector pb, bool h2, bool pol)
	{
	static bool is_sigma_index_set(false);

	if(!is_sigma_index_set){
	//std::cout<<"Setting sigma_index...." << std::endl;
	if(init_sigma_index())
	is_sigma_index_set = true;
	else
	return 0.;
	}

	CLHEP::HepLorentzVector pW = pl+plbar;
	CLHEP::HepLorentzVector q1g=pa-pW-p1-pg;
	CLHEP::HepLorentzVector q1 = pa-p1-pW;
	CLHEP::HepLorentzVector q2 = p2-pb;

	const double taW = (pa-pW).m2();
	const double taW1 = (pa-pW-p1).m2();
	const double tb2 = (pb-p2).m2();
	const double tb2g = (pb-p2-pg).m2();
	const double s1W = (p1+pW).m2();
	const double s1gW = (p1+pW+pg).m2();
	const double s1g = (p1+pg).m2();
	const double tag = (pa-pg).m2();
	const double taWg = (pa-pW-pg).m2();

	//use p1 as ref vec in pol tensor
	Tensor<1,4> epsg = eps(pg,p2,pol);
	Tensor<1,4> epsW = TCurrent(pl,false,plbar,false);
	Tensor<1,4> j2b = TCurrent(p2,h2,pb,h2);

	Tensor<1,4> Tq1q2 = Construct1Tensor((q1+q2)/taW1 + (pb/pb.dot(pg)
	+ p2/p2.dot(pg)) * tb2/(2*tb2g));
	Tensor<1,4> Tq1g = Construct1Tensor((-pg-q1))/taW1;
	Tensor<1,4> Tq2g = Construct1Tensor((pg-q2));
	Tensor<1,4> TqaW = Construct1Tensor((pa-pW));//pa-pw
	Tensor<1,4> Tqag = Construct1Tensor((pa-pg));
	Tensor<1,4> TqaWg = Construct1Tensor((pa-pg-pW));
	Tensor<1,4> Tp1g = Construct1Tensor((p1+pg));
	Tensor<1,4> Tp1W = Construct1Tensor((p1+pW));//p1+pw
	Tensor<1,4> Tp1gW = Construct1Tensor((p1+pg+pW));//p1+pw+pg

	Tensor<2,4> g=Metric();

	Tensor<3,4> J31a = T3Current(p1, h1, pa, h1);
	Tensor<2,4> J2_qaW =J31a.contract(TqaW/taW, 2);
	Tensor<2,4> J2_p1W =J31a.contract(Tp1W/s1W, 2);
	Tensor<3,4> L1a =J2_qaW.leftprod(Tq1q2);
	Tensor<3,4> L1b =J2_p1W.leftprod(Tq1q2);
	Tensor<3,4> L2a = J2_qaW.leftprod(Tq1g);
	Tensor<3,4> L2b = J2_p1W.leftprod(Tq1g);
	Tensor<3,4> L3 = (g.rightprod(J2_qaW.contract(Tq2g,1)+J2_p1W.contract(Tq2g,2)))/taW1;
	Tensor<3,4> L(0.);

	Tensor<5,4> J51a = T5Current(p1, h1, pa, h1);

	Tensor<4,4> J_qaW = J51a.contract(TqaW,4);
	Tensor<4,4> J_qag = J51a.contract(Tqag,4);
	Tensor<4,4> J_p1gW = J51a.contract(Tp1gW,4);

	Tensor<3,4> U1a = J_qaW.contract(Tp1g,2);
	Tensor<3,4> U1b = J_p1gW.contract(Tp1g,2);
	Tensor<3,4> U1c = J_p1gW.contract(Tp1W,2);
	Tensor<3,4> U1(0.);

	Tensor<3,4> U2a = J_qaW.contract(TqaWg,2);
	Tensor<3,4> U2b = J_qag.contract(TqaWg,2);
	Tensor<3,4> U2c = J_qag.contract(Tp1W,2);
	Tensor<3,4> U2(0.);

	for(int nu=0; nu<4;nu++){
	for(int mu=0;mu<4;mu++){
	for(int rho=0;rho<4;rho++){
	L.Set(nu, mu, rho, L1a.at(nu,mu,rho) + L1b.at(nu,rho,mu)
	+ L2a.at(mu,nu,rho) + L2b.at(mu,rho,nu) + L3.at(mu,nu,rho));
	U1.Set(nu, mu, rho, U1a.at(nu, mu, rho) / (s1g*taW)
	+ U1b.at(nu,rho,mu) / (s1gs1gW) + U1c.at(rho,nu,mu) / (s1Ws1gW));
	U2.Set(nu,mu,rho,U2a.at(mu,nu,rho) / (taWg*taW)
	+ U2b.at(mu,rho,nu) / (taWgtag) + U2c.at(rho,mu,nu) / (s1Wtag));
	}
	}
	}

	COM X = ((((U1-L).contract(epsW,3)).contract(j2b,2)).contract(epsg,1)).at(0);
	COM Y = ((((U2+L).contract(epsW,3)).contract(j2b,2)).contract(epsg,1)).at(0);

	double amp = HEJ::C_AHEJ::C_FHEJ::C_F/2.(norm(X)+norm(Y)) - HEJ::C_F/2.(X*conj(Y)).real();

	double t1 = q1g.m2();
	double t2 = q2.m2();

	//Divide by t-channels
	amp/=(t1*t2);

	//Average over initial states
	amp/=(4.HEJ::C_AHEJ::C_A);

	return amp;
	}



	// Relevant Wqqx Helper Functions.
	//g->qxqlxl (Calculates gluon to qqx Current. See JV_\mu in WSubleading Notes)
	Tensor <1,4> gtqqxW(CLHEP::HepLorentzVector pq,CLHEP::HepLorentzVector pqbar,CLHEP::HepLorentzVector pl,CLHEP::HepLorentzVector plbar){

	double s2AB=(pl+plbar+pq).m2();
	double s3AB=(pl+plbar+pqbar).m2();

	Tensor<1,4> Tpq = Construct1Tensor(pq);
	Tensor<1,4> Tpqbar = Construct1Tensor(pqbar);
	Tensor<1,4> TAB = Construct1Tensor(pl+plbar);

	// Define llx current.
	Tensor<1,4> ABCur = TCurrent(pl, false, plbar, false);

	//blank 3 Gamma Current
	Tensor<3,4> JV23 = T3Current(pq,false,pqbar,false);

	// Components of g->qqW before W Contraction
	Tensor<2,4> JV1 = JV23.contract((Tpq + TAB),2)/(s2AB);
	Tensor<2,4> JV2 = JV23.contract((Tpqbar + TAB),2)/(s3AB);

	// g->qqW Current. Note Minus between terms due to momentum flow.
	// Also note: (-I)^2 from W vert. (I) from Quark prop.
	Tensor<1,4> JVCur = (JV1.contract(ABCur,1) - JV2.contract(ABCur,2))*COM(0.,-1.);

	return JVCur;
	}

	// Helper Functions Calculate the Crossed Contribution
	Tensor <2,4> MCrossW(CLHEP::HepLorentzVector pa,CLHEP::HepLorentzVector p1,CLHEP::HepLorentzVector pb,CLHEP::HepLorentzVector p4, CLHEP::HepLorentzVector pq,CLHEP::HepLorentzVector pqbar,CLHEP::HepLorentzVector pl,CLHEP::HepLorentzVector plbar, std::vector<HLV> partons, int nabove){

	// Useful propagator factors
	double s2AB=(pl+plbar+pq).m2();
	double s3AB=(pl+plbar+pqbar).m2();

	CLHEP::HepLorentzVector q1, q3;
	q1=pa;
	for(int i=0; i<nabove+1;i++){
	q1=q1-partons.at(i);
	}
	q3 = q1 - pq - pqbar - pl - plbar;

	double tcro1=(q3+pq).m2();
	double tcro2=(q1-pqbar).m2();

	Tensor<1,4> Tp1 = Construct1Tensor(p1);
	Tensor<1,4> Tp4 = Construct1Tensor(p4);
	Tensor<1,4> Tpa = Construct1Tensor(pa);
	Tensor<1,4> Tpb = Construct1Tensor(pb);
	Tensor<1,4> Tpq = Construct1Tensor(pq);
	Tensor<1,4> Tpqbar = Construct1Tensor(pqbar);
	Tensor<1,4> TAB = Construct1Tensor(pl+plbar);
	Tensor<1,4> Tq1 = Construct1Tensor(q1);
	Tensor<1,4> Tq3 = Construct1Tensor(q3);
	Tensor<2,4> g=Metric();

	// Define llx current.
	Tensor<1,4> ABCur = TCurrent(pl, false, plbar,false);

	//Blank 5 gamma Current
	Tensor<5,4> J523 = T5Current(pq,false,pqbar,false);

	// 4 gamma currents (with 1 contraction already).
	Tensor<4,4> J_q3q = J523.contract((Tq3+Tpq),2);
	Tensor<4,4> J_2AB = J523.contract((Tpq+TAB),2);

	// Components of Crossed Vertex Contribution
	Tensor<3,4> Xcro1 = J_q3q.contract((Tpqbar + TAB),3);
	Tensor<3,4> Xcro2 = J_q3q.contract((Tq1-Tpqbar),3);
	Tensor<3,4> Xcro3 = J_2AB.contract((Tq1-Tpqbar),3);

	// Term Denominators Taken Care of at this stage
	Tensor<2,4> Xcro1Cont = Xcro1.contract(ABCur,3)/(tcro1*s3AB);
	Tensor<2,4> Xcro2Cont = Xcro2.contract(ABCur,2)/(tcro1*tcro2);
	Tensor<2,4> Xcro3Cont = Xcro3.contract(ABCur,1)/(s2AB*tcro2);

	//Initialise the Crossed Vertex Object
	Tensor<2,4> Xcro(0.);

	for(int mu=0; mu<4;mu++){
	for(int nu=0;nu<4;nu++){
	Xcro.Set(mu,nu, -(-Xcro1Cont.at(nu,mu)+Xcro2Cont.at(nu,mu)+Xcro3Cont.at(nu,mu)));
	}
	}


	return Xcro;
	}

	// Helper Functions Calculate the Uncrossed Contribution
	Tensor <2,4> MUncrossW(CLHEP::HepLorentzVector pa, CLHEP::HepLorentzVector p1, CLHEP::HepLorentzVector pb, CLHEP::HepLorentzVector p4, CLHEP::HepLorentzVector pq,CLHEP::HepLorentzVector pqbar,CLHEP::HepLorentzVector pl,CLHEP::HepLorentzVector plbar, std::vector<HLV> partons, int nabove){

	double s2AB=(pl+plbar+pq).m2();
	double s3AB=(pl+plbar+pqbar).m2();

	CLHEP::HepLorentzVector q1, q3;
	q1=pa;
	for(int i=0; i<nabove+1;i++){
	q1=q1-partons.at(i);
	}
	q3 = q1 - pl - plbar - pq - pqbar;
	double tunc1 = (q1-pq).m2();
	double tunc2 = (q3+pqbar).m2();

	Tensor<1,4> Tp1 = Construct1Tensor(p1);
	Tensor<1,4> Tp4 = Construct1Tensor(p4);
	Tensor<1,4> Tpa = Construct1Tensor(pa);
	Tensor<1,4> Tpb = Construct1Tensor(pb);
	Tensor<1,4> Tpq = Construct1Tensor(pq);
	Tensor<1,4> Tpqbar = Construct1Tensor(pqbar);
	Tensor<1,4> TAB = Construct1Tensor(pl+plbar);
	Tensor<1,4> Tq1 = Construct1Tensor(q1);
	Tensor<1,4> Tq3 = Construct1Tensor(q3);
	Tensor<2,4> g=Metric();


	// Define llx current.
	Tensor<1,4> ABCur = TCurrent(pl, false, plbar, false);

	//Blank 5 gamma Current
	Tensor<5,4> J523 = T5Current(pq,false,pqbar,false);

	// 4 gamma currents (with 1 contraction already).
	Tensor<4,4> J_2AB = J523.contract((Tpq+TAB),2);
	Tensor<4,4> J_q1q = J523.contract((Tq1-Tpq),2);

	// 2 Contractions taken care of.
	Tensor<3,4> Xunc1 = J_2AB.contract((Tq3+Tpqbar),3);
	Tensor<3,4> Xunc2 = J_q1q.contract((Tq3+Tpqbar),3);
	Tensor<3,4> Xunc3 = J_q1q.contract((Tpqbar+TAB),3);

	// Term Denominators Taken Care of at this stage
	Tensor<2,4> Xunc1Cont = Xunc1.contract(ABCur,1)/(s2AB*tunc2);
	Tensor<2,4> Xunc2Cont = Xunc2.contract(ABCur,2)/(tunc1*tunc2);
	Tensor<2,4> Xunc3Cont = Xunc3.contract(ABCur,3)/(tunc1*s3AB);

	//Initialise the Uncrossed Vertex Object
	Tensor<2,4> Xunc(0.);

	for(int mu=0; mu<4;mu++){
	for(int nu=0;nu<4;nu++){
	Xunc.Set(mu,nu,-(- Xunc1Cont.at(mu,nu)+Xunc2Cont.at(mu,nu) +Xunc3Cont.at(mu,nu)));
	}
	}

	return Xunc;
	}


	// Helper Functions Calculate the g->qqxW (Eikonal) Contributions
	Tensor <2,4> MSymW(CLHEP::HepLorentzVector pa,CLHEP::HepLorentzVector p1,CLHEP::HepLorentzVector pb,CLHEP::HepLorentzVector p4, CLHEP::HepLorentzVector pq,CLHEP::HepLorentzVector pqbar,CLHEP::HepLorentzVector pl,CLHEP::HepLorentzVector plbar, std::vector<HLV> partons, int nabove){

	double sa2=(pa+pq).m2();
	double s12=(p1+pq).m2();
	double sa3=(pa+pqbar).m2();
	double s13=(p1+pqbar).m2();
	double saA=(pa+pl).m2();
	double s1A=(p1+pl).m2();
	double saB=(pa+plbar).m2();
	double s1B=(p1+plbar).m2();
	double sb2=(pb+pq).m2();
	double s42=(p4+pq).m2();
	double sb3=(pb+pqbar).m2();
	double s43=(p4+pqbar).m2();
	double sbA=(pb+pl).m2();
	double s4A=(p4+pl).m2();
	double sbB=(pb+plbar).m2();
	double s4B=(p4+plbar).m2();
	double s23AB=(pl+plbar+pq+pqbar).m2();

	CLHEP::HepLorentzVector q1,q3;
	q1=pa;
	for(int i=0;i<nabove+1;i++){
	q1-=partons.at(i);
	}
	q3=q1-pq-pqbar-plbar-pl;
	double t1 = (q1).m2();
	double t3 = (q3).m2();

	//Define Tensors to be used
	Tensor<1,4> Tp1 = Construct1Tensor(p1);
	Tensor<1,4> Tp4 = Construct1Tensor(p4);
	Tensor<1,4> Tpa = Construct1Tensor(pa);
	Tensor<1,4> Tpb = Construct1Tensor(pb);
	Tensor<1,4> Tpq = Construct1Tensor(pq);
	Tensor<1,4> Tpqbar = Construct1Tensor(pqbar);
	Tensor<1,4> TAB = Construct1Tensor(pl+plbar);
	Tensor<1,4> Tq1 = Construct1Tensor(q1);
	Tensor<1,4> Tq3 = Construct1Tensor(q3);
	Tensor<2,4> g=Metric();

	// g->qqW Current (Factors of sqrt2 dealt with in this function.)
	Tensor<1,4> JV = gtqqxW(pq,pqbar,pl,plbar);

	// 1a gluon emisson Contribution
	Tensor<3,4> X1a = g.rightprod(Tp1(t1/(s12+s13+s1A+s1B)) + Tpa(t1/(sa2+sa3+saA+saB)));
	Tensor<2,4> X1aCont = X1a.contract(JV,3);

	//4b gluon emission Contribution
	Tensor<3,4> X4b = g.rightprod(Tp4(t3/(s42+s43+s4A+s4B)) + Tpb(t3/(sb2+sb3+sbA+sbB)));
	Tensor<2,4> X4bCont = X4b.contract(JV,3);

	//Set up each term of 3G diagram.
	Tensor<3,4> X3g1 = g.leftprod(Tq1+Tpq+Tpqbar+TAB);
	Tensor<3,4> X3g2 = g.leftprod(Tq3-Tpq-Tpqbar-TAB);
	Tensor<3,4> X3g3 = g.leftprod((Tq1+Tq3));

	// Note the contraction of indices changes term by term
	Tensor<2,4> X3g1Cont = X3g1.contract(JV,3);
	Tensor<2,4> X3g2Cont = X3g2.contract(JV,2);
	Tensor<2,4> X3g3Cont = X3g3.contract(JV,1);

	// XSym is an amalgamation of x1a, X4b and X3g. Makes sense from a colour factor point of view.
	Tensor<2,4>Xsym(0.);

	for(int mu=0; mu<4;mu++){
	for(int nu=0;nu<4;nu++){
	Xsym.Set(mu,nu, (X3g1Cont.at(nu,mu) + X3g2Cont.at(mu,nu) - X3g3Cont.at(nu,mu))
	+ (X1aCont.at(mu,nu) - X4bCont.at(mu,nu)) );
	}
	}
	return Xsym/s23AB;
	}

	Tensor <2,4> MCross(CLHEP::HepLorentzVector pa, CLHEP::HepLorentzVector pq,CLHEP::HepLorentzVector pqbar, std::vector<HLV> partons, bool hq, int nabove){

	CLHEP::HepLorentzVector q1;
	q1=pa;
	for(int i=0;i<nabove+1;i++){
	q1-=partons.at(i);
	}

	double t2=(q1-pqbar).m2();

	Tensor<1,4> Tq1 = Construct1Tensor(q1-pqbar);

	//Blank 3 gamma Current
	Tensor<3,4> J323 = T3Current(pq,hq,pqbar,hq);

	// 2 gamma current (with 1 contraction already).
	Tensor<2,4> XCroCont = J323.contract((Tq1),2)/(t2);

	//Initialise the Crossed Vertex
	Tensor<2,4> Xcro(0.);

	for(int mu=0; mu<4;mu++){
	for(int nu=0;nu<4;nu++){
	Xcro.Set(mu,nu, (XCroCont.at(nu,mu)));
	}
	}

	return Xcro;
	}


	// Helper Functions Calculate the Uncrossed Contribution
	Tensor <2,4> MUncross(CLHEP::HepLorentzVector pa, CLHEP::HepLorentzVector pq,CLHEP::HepLorentzVector pqbar, std::vector<HLV> partons, bool hq, int nabove){

	CLHEP::HepLorentzVector q1;
	q1=pa;
	for(int i=0;i<nabove+1;i++){
	q1-=partons.at(i);
	}
	double t2 = (q1-pq).m2();

	Tensor<1,4> Tq1 = Construct1Tensor(q1-pq);

	//Blank 3 gamma Current
	Tensor<3,4> J323 = T3Current(pq,hq,pqbar,hq);

	// 2 gamma currents (with 1 contraction already).
	Tensor<2,4> XUncCont = J323.contract((Tq1),2)/t2;

	//Initialise the Uncrossed Vertex
	Tensor<2,4> Xunc(0.);

	for(int mu=0; mu<4;mu++){
	for(int nu=0;nu<4;nu++){
	Xunc.Set(mu,nu,-(XUncCont.at(mu,nu)));
	}
	}

	return Xunc;
	}


	// Helper Functions Calculate the Eikonal Contributions
	Tensor <2,4> MSym(CLHEP::HepLorentzVector pa,CLHEP::HepLorentzVector p1,CLHEP::HepLorentzVector pb,CLHEP::HepLorentzVector p4, CLHEP::HepLorentzVector pq,CLHEP::HepLorentzVector pqbar, std::vector<HLV> partons, bool hq, int nabove){

	CLHEP::HepLorentzVector q1, q3;
	q1=pa;
	for(int i=0;i<nabove+1;i++){
	q1-=partons.at(i);
	}
	q3 = q1-pq-pqbar;
	double t1 = (q1).m2();
	double t3 = (q3).m2();

	double s23 = (pq+pqbar).m2();
	double sa2 = (pa+pq).m2();
	double sa3 = (pa+pqbar).m2();
	double s12 = (p1+pq).m2();
	double s13 = (p1+pqbar).m2();
	double sb2 = (pb+pq).m2();
	double sb3 = (pb+pqbar).m2();
	double s42 = (p4+pq).m2();
	double s43 = (p4+pqbar).m2();

	//Define Tensors to be used
	Tensor<1,4> Tp1 = Construct1Tensor(p1);
	Tensor<1,4> Tp4 = Construct1Tensor(p4);
	Tensor<1,4> Tpa = Construct1Tensor(pa);
	Tensor<1,4> Tpb = Construct1Tensor(pb);
	Tensor<1,4> Tpq = Construct1Tensor(pq);
	Tensor<1,4> Tpqbar = Construct1Tensor(pqbar);
	Tensor<1,4> Tq1 = Construct1Tensor(q1);
	Tensor<1,4> Tq3 = Construct1Tensor(q3);
	Tensor<2,4> g=Metric();

	Tensor<1,4> qqxCur = TCurrent(pq, hq, pqbar, hq);

	// // 1a gluon emisson Contribution
	Tensor<3,4> X1a = g.rightprod(Tp1(t1/(s12+s13))+Tpa(t1/(sa2+sa3)));
	Tensor<2,4> X1aCont = X1a.contract(qqxCur,3);

	// //4b gluon emission Contribution
	Tensor<3,4> X4b = g.rightprod(Tp4(t3/(s42+s43)) + Tpb(t3/(sb2+sb3)));
	Tensor<2,4> X4bCont = X4b.contract(qqxCur,3);

	// New Formulation Corresponding to New Analytics
	Tensor<3,4> X3g1 = g.leftprod(Tq1+Tpq+Tpqbar);
	Tensor<3,4> X3g2 = g.leftprod(Tq3-Tpq-Tpqbar);
	Tensor<3,4> X3g3 = g.leftprod((Tq1+Tq3));

	// Note the contraction of indices changes term by term
	Tensor<2,4> X3g1Cont = X3g1.contract(qqxCur,3);
	Tensor<2,4> X3g2Cont = X3g2.contract(qqxCur,2);
	Tensor<2,4> X3g3Cont = X3g3.contract(qqxCur,1);

	Tensor<2,4>Xsym(0.);

	for(int mu=0; mu<4;mu++){
	for(int nu=0;nu<4;nu++){
	Xsym.Set(mu, nu, COM(0,1) * ( (X3g1Cont.at(nu,mu) + X3g2Cont.at(mu,nu)
	- X3g3Cont.at(nu,mu)) + (X1aCont.at(mu,nu) - X4bCont.at(mu,nu)) ) );
	}
	}
	return Xsym/s23;
	}
	} // Anonymous Namespace helper functions

	-//Functions which can be called elsewhere (declarations in currents.hh).
	+// W+Jets FKL Contributions
	+double jMWqQ (CLHEP::HepLorentzVector p1out, CLHEP::HepLorentzVector pe, CLHEP::HepLorentzVector pnu,CLHEP::HepLorentzVector p1in, CLHEP::HepLorentzVector p2out, CLHEP::HepLorentzVector p2in)
	+// Calculates the square of the current contractions for qQ->qenuQ scattering
	+// p1: quark (with W emittance)
	+// p2: Quark
	+{
	+ current mj1m,mj2p,mj2m;
	+ CLHEP::HepLorentzVector q1=p1in-p1out-pe-pnu;
	+ CLHEP::HepLorentzVector q2=-(p2in-p2out);
	+
	+ jW(p1out,false,pe,false,pnu,false,p1in,false,mj1m);
	+ joi(p2out,true,p2in,true,mj2p);
	+ joi(p2out,false,p2in,false,mj2m);
	+
	+ COM Mmp=cdot(mj1m,mj2p);
	+
	+ // mj1m.mj2m
	+ COM Mmm=cdot(mj1m,mj2m);
	+
	+ // sum of spinor strings \|\|^2
	+ double a2Mmp=abs2(Mmp);
	+ double a2Mmm=abs2(Mmm);
	+
	+ // Leave division by colour and Helicity avg until Tree files
	+ // Leave multi. of couplings to later
	+ // Multiply by Cf^2
	+ return HEJ::C_FHEJ::C_F(a2Mmp+a2Mmm)/(q1.m2()*q2.m2());
	+
	+}
	+
	+double jMWqQbar (CLHEP::HepLorentzVector p1out, CLHEP::HepLorentzVector pe, CLHEP::HepLorentzVector pnu,CLHEP::HepLorentzVector p1in, CLHEP::HepLorentzVector p2out, CLHEP::HepLorentzVector p2in)
	+// Calculates the square of the current contractions for qQ->qenuQ scattering
	+// p1: quark (with W emittance)
	+// p2: Quark
	+{
	+ current mj1m,mj2p,mj2m;
	+ CLHEP::HepLorentzVector q1=p1in-p1out-pe-pnu;
	+ CLHEP::HepLorentzVector q2=-(p2in-p2out);
	+
	+ jW(p1out,false,pe,false,pnu,false,p1in,false,mj1m);
	+ jio(p2in,true,p2out,true,mj2p);
	+ jio(p2in,false,p2out,false,mj2m);
	+
	+ COM Mmp=cdot(mj1m,mj2p);
	+
	+ // mj1m.mj2m
	+ COM Mmm=cdot(mj1m,mj2m);
	+
	+ // sum of spinor strings \|\|^2
	+ double a2Mmp=abs2(Mmp);
	+ double a2Mmm=abs2(Mmm);
	+
	+ // Leave division by colour and Helicity avg until Tree files
	+ // Leave multi. of couplings to later
	+ // Multiply by Cf^2
	+ return HEJ::C_FHEJ::C_F(a2Mmp+a2Mmm)/(q1.m2()*q2.m2());
	+
	+}
	+
	+double jMWqbarQ (CLHEP::HepLorentzVector p1out, CLHEP::HepLorentzVector pe, CLHEP::HepLorentzVector pnu,CLHEP::HepLorentzVector p1in, CLHEP::HepLorentzVector p2out, CLHEP::HepLorentzVector p2in)
	+// Calculates the square of the current contractions for qQ->qenuQ scattering
	+// p1: quark (with W emittance)
	+// p2: Quark
	+{
	+ current mj1m,mj2p,mj2m;
	+ CLHEP::HepLorentzVector q1=p1in-p1out-pe-pnu;
	+ CLHEP::HepLorentzVector q2=-(p2in-p2out);
	+
	+ jWbar(p1out,false,pe,false,pnu,false,p1in,false,mj1m);
	+ joi(p2out,true,p2in,true,mj2p);
	+ joi(p2out,false,p2in,false,mj2m);
	+
	+ COM Mmp=cdot(mj1m,mj2p);
	+
	+ // mj1m.mj2m
	+ COM Mmm=cdot(mj1m,mj2m);
	+
	+ // sum of spinor strings \|\|^2
	+ double a2Mmp=abs2(Mmp);
	+ double a2Mmm=abs2(Mmm);
	+
	+ // Leave division by colour and Helicity avg until Tree files
	+ // Leave multi. of couplings to later
	+ // Multiply by Cf^2
	+ return HEJ::C_FHEJ::C_F(a2Mmp+a2Mmm)/(q1.m2()*q2.m2());
	+
	+}
	+
	+double jMWqbarQbar (CLHEP::HepLorentzVector p1out, CLHEP::HepLorentzVector pe, CLHEP::HepLorentzVector pnu,CLHEP::HepLorentzVector p1in, CLHEP::HepLorentzVector p2out, CLHEP::HepLorentzVector p2in)
	+// Calculates the square of the current contractions for qQ->qenuQ scattering
	+// p1: quark (with W emittance)
	+// p2: Quark
	+{
	+ current mj1m,mj2p,mj2m;
	+ CLHEP::HepLorentzVector q1=p1in-p1out-pe-pnu;
	+ CLHEP::HepLorentzVector q2=-(p2in-p2out);
	+
	+ jWbar(p1out,false,pe,false,pnu,false,p1in,false,mj1m);
	+ jio(p2in,true,p2out,true,mj2p);
	+ jio(p2in,false,p2out,false,mj2m);
	+
	+ COM Mmp=cdot(mj1m,mj2p);
	+
	+ // mj1m.mj2m
	+ COM Mmm=cdot(mj1m,mj2m);
	+
	+ // sum of spinor strings \|\|^2
	+ double a2Mmp=abs2(Mmp);
	+ double a2Mmm=abs2(Mmm);
	+
	+ // Leave division by colour and Helicity avg until Tree files
	+ // Leave multi. of couplings to later
	+ // Multiply by Cf^2
	+ return HEJ::C_FHEJ::C_F(a2Mmp+a2Mmm)/(q1.m2()*q2.m2());
	+
	+}
	+
	+double jMWqg (CLHEP::HepLorentzVector p1out, CLHEP::HepLorentzVector pe, CLHEP::HepLorentzVector pnu,CLHEP::HepLorentzVector p1in, CLHEP::HepLorentzVector p2out, CLHEP::HepLorentzVector p2in)
	+// Calculates the square of the current contractions for qg->qenug scattering
	+// p1: quark
	+// p2: gluon
	+{
	+ CLHEP::HepLorentzVector q1=p1in-p1out-pe-pnu;
	+ CLHEP::HepLorentzVector q2=-(p2in-p2out);
	+ current mj1m,mj2p,mj2m;
	+
	+ jW(p1out,false,pe,false,pnu,false,p1in,false,mj1m);
	+
	+ joi(p2out,true,p2in,true,mj2p);
	+ joi(p2out,false,p2in,false,mj2m);
	+
	+ // mj1m.mj2p
	+ COM Mmp=cdot(mj1m,mj2p);
	+
	+ // mj1m.mj2m
	+ COM Mmm=cdot(mj1m,mj2m);
	+
	+ const double K = K_g(p2out, p2in);
	+
	+ // sum of spinor strings \|\|^2
	+ double a2Mmp=abs2(Mmp);
	+ double a2Mmm=abs2(Mmm);
	+ double sst = K/HEJ::C_A*(a2Mmp+a2Mmm);
	+
	+ // Leave division by colour and Helicity avg until Tree files
	+ // Leave multi. of couplings to later
	+ // Multiply by Cf*Ca=4
	+ return HEJ::C_FHEJ::C_Asst/(q1.m2()*q2.m2());
	+
	+}
	+
	+double jMWqbarg (CLHEP::HepLorentzVector p1out, CLHEP::HepLorentzVector pe, CLHEP::HepLorentzVector pnu,CLHEP::HepLorentzVector p1in, CLHEP::HepLorentzVector p2out, CLHEP::HepLorentzVector p2in)
	+// Calculates the square of the current contractions for qg->qenug scattering
	+// p1: quark
	+// p2: gluon
	+{
	+ CLHEP::HepLorentzVector q1=p1in-p1out-pe-pnu;
	+ CLHEP::HepLorentzVector q2=-(p2in-p2out);
	+ current mj1m,mj2p,mj2m;
	+
	+ jWbar(p1out,false,pe,false,pnu,false,p1in,false,mj1m);
	+
	+ joi(p2out,true,p2in,true,mj2p);
	+ joi(p2out,false,p2in,false,mj2m);
	+
	+ // mj1m.mj2p
	+ COM Mmp=cdot(mj1m,mj2p);
	+
	+ // mj1m.mj2m
	+ COM Mmm=cdot(mj1m,mj2m);
	+
	+ const double K = K_g(p2out, p2in);
	+
	+ // sum of spinor strings \|\|^2
	+ double a2Mmp=abs2(Mmp);
	+ double a2Mmm=abs2(Mmm);
	+ double sst = K/HEJ::C_A*(a2Mmp+a2Mmm);
	+
	+// // Leave division by colour and Helicity avg until Tree files
	+ // Leave multi. of couplings to later
	+ // Multiply by Cf*Ca=4
	+ return HEJ::C_FHEJ::C_Asst/(q1.m2()*q2.m2());
	+
	+}
	+

	// W+Jets Unordered Contributions
	//qQ->qQWg_unob
	double junobMWqQg (CLHEP::HepLorentzVector p1out, CLHEP::HepLorentzVector pe, CLHEP::HepLorentzVector pnu,CLHEP::HepLorentzVector p1in, CLHEP::HepLorentzVector p2out, CLHEP::HepLorentzVector p2in, CLHEP::HepLorentzVector pg)
	// Calculates the square of the current contractions for qQ->qenuQ scattering
	// p1: quark (with W emittance)
	// p2: Quark
	{
	CCurrent mj1m,mj2p,mj2m;
	CLHEP::HepLorentzVector q1=p1in-p1out-pe-pnu;
	CLHEP::HepLorentzVector q2=-(p2in-p2out-pg);
	CLHEP::HepLorentzVector q3=-(p2in-p2out);

	mj1m=jW(p1out,false,pe,false,pnu,false,p1in,false);
	mj2p=j(p2out,true,p2in,true);
	mj2m=j(p2out,false,p2in,false);


	// Dot products of these which occur again and again
	COM MWmp=mj1m.dot(mj2p); // And now for the Higgs ones
	COM MWmm=mj1m.dot(mj2m);

	CCurrent jgbm,jgbp,j2gm,j2gp;
	j2gp=joo(p2out,true,pg,true);
	j2gm=joo(p2out,false,pg,false);
	jgbp=j(pg,true,p2in,true);
	jgbm=j(pg,false,p2in,false);

	CCurrent qsum(q2+q3);

	CCurrent Lmp,Lmm,Lpp,Lpm,U1mp,U1mm,U1pp,U1pm,U2mp,U2mm,U2pp,U2pm,p1o(p1out),p1i(p1in);
	CCurrent p2o(p2out);
	CCurrent p2i(p2in);


	Lmm=((-1.)qsum(MWmm) + (-2.mj1m.dot(pg))mj2m+2.mj2m.dot(pg)mj1m+(p1o/pg.dot(p1out) + p1i/pg.dot(p1in))(q2.m2()MWmm/2.))/q3.m2();
	Lmp=((-1.)qsum(MWmp) + (-2.mj1m.dot(pg))mj2p+2.mj2p.dot(pg)mj1m+(p1o/pg.dot(p1out) + p1i/pg.dot(p1in))(q2.m2()MWmp/2.))/q3.m2();

	U1mm=(jgbm.dot(mj1m)j2gm+2.p2o*MWmm)/(p2out+pg).m2();
	U1mp=(jgbp.dot(mj1m)j2gp+2.p2o*MWmp)/(p2out+pg).m2();

	U2mm=((-1.)j2gm.dot(mj1m)jgbm+2.p2iMWmm)/(p2in-pg).m2();
	U2mp=((-1.)j2gp.dot(mj1m)jgbp+2.p2iMWmp)/(p2in-pg).m2();


	double amm,amp;

	amm=HEJ::C_F(2.vre(Lmm-U1mm,Lmm+U2mm))+2.HEJ::C_FHEJ::C_F/3.*vabs2(U1mm+U2mm);
	amp=HEJ::C_F(2.vre(Lmp-U1mp,Lmp+U2mp))+2.HEJ::C_FHEJ::C_F/3.*vabs2(U1mp+U2mp);

	double ampsq=-(amm+amp);

	// Now add the t-channels
	double th=q2.m2()*q1.m2();
	ampsq/=th;
	ampsq/=16.;

	return ampsq;


	}

	//qQbar->qQbarWg_unob
	double junobMWqQbarg (CLHEP::HepLorentzVector p1out, CLHEP::HepLorentzVector pe, CLHEP::HepLorentzVector pnu,CLHEP::HepLorentzVector p1in, CLHEP::HepLorentzVector p2out, CLHEP::HepLorentzVector p2in, CLHEP::HepLorentzVector pg)
	// Calculates the square of the current contractions for qQ->qenuQ scattering
	// p1: quark (with W emittance)
	// p2: Quark
	{
	CCurrent mj1m,mj2p,mj2m;
	CLHEP::HepLorentzVector q1=p1in-p1out-pe-pnu;
	CLHEP::HepLorentzVector q2=-(p2in-p2out-pg);
	CLHEP::HepLorentzVector q3=-(p2in-p2out);

	mj1m=jW(p1out,false,pe,false,pnu,false,p1in,false);
	mj2p=jio(p2in,true,p2out,true);
	mj2m=jio(p2in,false,p2out,false);


	// Dot products of these which occur again and again
	COM MWmp=mj1m.dot(mj2p); // And now for the Higgs ones
	COM MWmm=mj1m.dot(mj2m);

	CCurrent jgbm,jgbp,j2gm,j2gp;
	j2gp=joo(pg,true,p2out,true);
	j2gm=joo(pg,false,p2out,false);
	jgbp=jio(p2in,true,pg,true);
	jgbm=jio(p2in,false,pg,false);

	CCurrent qsum(q2+q3);

	CCurrent Lmp,Lmm,Lpp,Lpm,U1mp,U1mm,U1pp,U1pm,U2mp,U2mm,U2pp,U2pm,p1o(p1out),p1i(p1in);
	CCurrent p2o(p2out);
	CCurrent p2i(p2in);


	Lmm=((-1.)qsum(MWmm) + (-2.mj1m.dot(pg))mj2m+2.mj2m.dot(pg)mj1m+(p1o/pg.dot(p1out) + p1i/pg.dot(p1in))(q2.m2()MWmm/2.))/q3.m2();
	Lmp=((-1.)qsum(MWmp) + (-2.mj1m.dot(pg))mj2p+2.mj2p.dot(pg)mj1m+(p1o/pg.dot(p1out) + p1i/pg.dot(p1in))(q2.m2()MWmp/2.))/q3.m2();

	U1mm=(jgbm.dot(mj1m)j2gm+2.p2o*MWmm)/(p2out+pg).m2();
	U1mp=(jgbp.dot(mj1m)j2gp+2.p2o*MWmp)/(p2out+pg).m2();

	U2mm=((-1.)j2gm.dot(mj1m)jgbm+2.p2iMWmm)/(p2in-pg).m2();
	U2mp=((-1.)j2gp.dot(mj1m)jgbp+2.p2iMWmp)/(p2in-pg).m2();

	double amm,amp;

	amm=HEJ::C_F(2.vre(Lmm-U1mm,Lmm+U2mm))+2.HEJ::C_FHEJ::C_F/3.*vabs2(U1mm+U2mm);
	amp=HEJ::C_F(2.vre(Lmp-U1mp,Lmp+U2mp))+2.HEJ::C_FHEJ::C_F/3.*vabs2(U1mp+U2mp);

	double ampsq=-(amm+amp);

	// Now add the t-channels
	double th=q2.m2()*q1.m2();
	ampsq/=th;
	ampsq/=16.;

	return ampsq;


	}

	//qbarQ->qbarQWg_unob
	double junobMWqbarQg (CLHEP::HepLorentzVector p1out, CLHEP::HepLorentzVector pe, CLHEP::HepLorentzVector pnu,CLHEP::HepLorentzVector p1in, CLHEP::HepLorentzVector p2out, CLHEP::HepLorentzVector p2in, CLHEP::HepLorentzVector pg)
	// Calculates the square of the current contractions for qQ->qenuQ scattering
	// p1: quark (with W emittance)
	// p2: Quark
	{
	CCurrent mj1m,mj2p,mj2m;
	CLHEP::HepLorentzVector q1=p1in-p1out-pe-pnu;
	CLHEP::HepLorentzVector q2=-(p2in-p2out-pg);
	CLHEP::HepLorentzVector q3=-(p2in-p2out);

	mj1m=jWbar(p1out,false,pe,false,pnu,false,p1in,false);
	mj2p=j(p2out,true,p2in,true);
	mj2m=j(p2out,false,p2in,false);


	// Dot products of these which occur again and again
	COM MWmp=mj1m.dot(mj2p); // And now for the Higgs ones
	COM MWmm=mj1m.dot(mj2m);

	CCurrent jgbm,jgbp,j2gm,j2gp;
	j2gp=joo(p2out,true,pg,true);
	j2gm=joo(p2out,false,pg,false);
	jgbp=j(pg,true,p2in,true);
	jgbm=j(pg,false,p2in,false);

	CCurrent qsum(q2+q3);

	CCurrent Lmp,Lmm,Lpp,Lpm,U1mp,U1mm,U1pp,U1pm,U2mp,U2mm,U2pp,U2pm,p1o(p1out),p1i(p1in);
	CCurrent p2o(p2out);
	CCurrent p2i(p2in);


	Lmm=((-1.)qsum(MWmm) + (-2.mj1m.dot(pg))mj2m+2.mj2m.dot(pg)mj1m+(p1o/pg.dot(p1out) + p1i/pg.dot(p1in))(q2.m2()MWmm/2.))/q3.m2();
	Lmp=((-1.)qsum(MWmp) + (-2.mj1m.dot(pg))mj2p+2.mj2p.dot(pg)mj1m+(p1o/pg.dot(p1out) + p1i/pg.dot(p1in))(q2.m2()MWmp/2.))/q3.m2();

	U1mm=(jgbm.dot(mj1m)j2gm+2.p2o*MWmm)/(p2out+pg).m2();
	U1mp=(jgbp.dot(mj1m)j2gp+2.p2o*MWmp)/(p2out+pg).m2();

	U2mm=((-1.)j2gm.dot(mj1m)jgbm+2.p2iMWmm)/(p2in-pg).m2();
	U2mp=((-1.)j2gp.dot(mj1m)jgbp+2.p2iMWmp)/(p2in-pg).m2();


	double amm,amp;

	amm=HEJ::C_F(2.vre(Lmm-U1mm,Lmm+U2mm))+2.HEJ::C_FHEJ::C_F/3.*vabs2(U1mm+U2mm);
	amp=HEJ::C_F(2.vre(Lmp-U1mp,Lmp+U2mp))+2.HEJ::C_FHEJ::C_F/3.*vabs2(U1mp+U2mp);

	double ampsq=-(amm+amp);

	// Now add the t-channels
	double th=q2.m2()*q1.m2();
	ampsq/=th;
	ampsq/=16.;

	return ampsq;


	}

	//qbarQbar->qbarQbarWg_unob
	double junobMWqbarQbarg (CLHEP::HepLorentzVector p1out, CLHEP::HepLorentzVector pe, CLHEP::HepLorentzVector pnu,CLHEP::HepLorentzVector p1in, CLHEP::HepLorentzVector p2out, CLHEP::HepLorentzVector p2in, CLHEP::HepLorentzVector pg)
	// Calculates the square of the current contractions for qQ->qenuQ scattering
	// p1: quark (with W emittance)
	// p2: Quark
	{
	CCurrent mj1m,mj2p,mj2m;
	CLHEP::HepLorentzVector q1=p1in-p1out-pe-pnu;
	CLHEP::HepLorentzVector q2=-(p2in-p2out-pg);
	CLHEP::HepLorentzVector q3=-(p2in-p2out);

	mj1m=jWbar(p1out,false,pe,false,pnu,false,p1in,false);
	mj2p=jio(p2in,true,p2out,true);
	mj2m=jio(p2in,false,p2out,false);


	// Dot products of these which occur again and again
	COM MWmp=mj1m.dot(mj2p); // And now for the Higgs ones
	COM MWmm=mj1m.dot(mj2m);

	CCurrent jgbm,jgbp,j2gm,j2gp;
	j2gp=joo(pg,true,p2out,true);
	j2gm=joo(pg,false,p2out,false);
	jgbp=jio(p2in,true,pg,true);
	jgbm=jio(p2in,false,pg,false);

	CCurrent qsum(q2+q3);

	CCurrent Lmp,Lmm,Lpp,Lpm,U1mp,U1mm,U1pp,U1pm,U2mp,U2mm,U2pp,U2pm,p1o(p1out),p1i(p1in);
	CCurrent p2o(p2out);
	CCurrent p2i(p2in);


	Lmm=((-1.)qsum(MWmm) + (-2.mj1m.dot(pg))mj2m+2.mj2m.dot(pg)mj1m+(p1o/pg.dot(p1out) + p1i/pg.dot(p1in))(q2.m2()MWmm/2.))/q3.m2();
	Lmp=((-1.)qsum(MWmp) + (-2.mj1m.dot(pg))mj2p+2.mj2p.dot(pg)mj1m+(p1o/pg.dot(p1out) + p1i/pg.dot(p1in))(q2.m2()MWmp/2.))/q3.m2();

	U1mm=(jgbm.dot(mj1m)j2gm+2.p2o*MWmm)/(p2out+pg).m2();
	U1mp=(jgbp.dot(mj1m)j2gp+2.p2o*MWmp)/(p2out+pg).m2();

	U2mm=((-1.)j2gm.dot(mj1m)jgbm+2.p2iMWmm)/(p2in-pg).m2();
	U2mp=((-1.)j2gp.dot(mj1m)jgbp+2.p2iMWmp)/(p2in-pg).m2();


	double amm,amp;

	amm=HEJ::C_F(2.vre(Lmm-U1mm,Lmm+U2mm))+2.HEJ::C_FHEJ::C_F/3.*vabs2(U1mm+U2mm);
	amp=HEJ::C_F(2.vre(Lmp-U1mp,Lmp+U2mp))+2.HEJ::C_FHEJ::C_F/3.*vabs2(U1mp+U2mp);

	double ampsq=-(amm+amp);

	// Now add the t-channels
	double th=q2.m2()*q1.m2();
	ampsq/=th;
	ampsq/=16.;

	return ampsq;


	}

	////////////////////////////////////////////////////////////////////
	//qQ->qQWg_unof
	double junofMWgqQ (CLHEP::HepLorentzVector pg,CLHEP::HepLorentzVector p1out,CLHEP::HepLorentzVector p1in, CLHEP::HepLorentzVector p2out, CLHEP::HepLorentzVector pe, CLHEP::HepLorentzVector pnu, CLHEP::HepLorentzVector p2in)
	// Calculates the square of the current contractions for qQ->qenuQ scattering
	// p1: quark (with W emittance)
	// p2: Quark
	{
	CCurrent mj2m,mj1p,mj1m;
	CLHEP::HepLorentzVector q1=p1in-p1out;
	CLHEP::HepLorentzVector qg=p1in-p1out-pg;
	CLHEP::HepLorentzVector q2=-(p2in-p2out-pe-pnu);

	mj2m=jW(p2out,false,pe,false,pnu,false,p2in,false);
	mj1p=j(p1out,true,p1in,true);
	mj1m=j(p1out,false,p1in,false);


	// Dot products of these which occur again and again
	COM MWpm=mj1p.dot(mj2m); // And now for the Higgs ones
	COM MWmm=mj1m.dot(mj2m);

	CCurrent jgam,jgap,j2gm,j2gp;
	j2gp=joo(p1out,true,pg,true);
	j2gm=joo(p1out,false,pg,false);
	jgap=j(pg,true,p1in,true);
	jgam=j(pg,false,p1in,false);

	CCurrent qsum(q1+qg);

	CCurrent Lmp,Lmm,Lpp,Lpm,U1mp,U1mm,U1pp,U1pm,U2mp,U2mm,U2pp,U2pm,p2o(p2out),p2i(p2in);
	CCurrent p1o(p1out);
	CCurrent p1i(p1in);

	Lmm=(qsum(MWmm) + (-2.mj2m.dot(pg))mj1m+2.mj1m.dot(pg)mj2m+(p2o/pg.dot(p2out) + p2i/pg.dot(p2in))(qg.m2()*MWmm/2.))/q1.m2();
	Lpm=(qsum(MWpm) + (-2.mj2m.dot(pg))mj1p+2.mj1p.dot(pg)mj2m+(p2o/pg.dot(p2out) + p2i/pg.dot(p2in))(qg.m2()*MWpm/2.))/q1.m2();


	U1mm=(jgam.dot(mj2m)j2gm+2.p1o*MWmm)/(p1out+pg).m2();
	U1pm=(jgap.dot(mj2m)j2gp+2.p1o*MWpm)/(p1out+pg).m2();

	U2mm=((-1.)j2gm.dot(mj2m)jgam+2.p1iMWmm)/(p1in-pg).m2();
	U2pm=((-1.)j2gp.dot(mj2m)jgap+2.p1iMWpm)/(p1in-pg).m2();

	double amm,apm;
	amm=HEJ::C_F(2.vre(Lmm-U1mm,Lmm+U2mm))+2.HEJ::C_FHEJ::C_F/3.*vabs2(U1mm+U2mm);
	apm=HEJ::C_F(2.vre(Lpm-U1pm,Lpm+U2pm))+2.HEJ::C_FHEJ::C_F/3.*vabs2(U1pm+U2pm);

	double ampsq=-(apm+amm);

	// Now add the t-channels
	double th=q2.m2()*qg.m2();
	ampsq/=th;
	ampsq/=16.;

	return ampsq;


	}

	//qQbar->qQbarWg_unof
	double junofMWgqQbar (CLHEP::HepLorentzVector pg,CLHEP::HepLorentzVector p1out,CLHEP::HepLorentzVector p1in, CLHEP::HepLorentzVector p2out, CLHEP::HepLorentzVector pe, CLHEP::HepLorentzVector pnu, CLHEP::HepLorentzVector p2in)
	// Calculates the square of the current contractions for qQ->qenuQ scattering
	// p1: quark (with W emittance)
	// p2: Quark
	{
	CCurrent mj2m,mj1p,mj1m;
	CLHEP::HepLorentzVector q1=p1in-p1out;
	CLHEP::HepLorentzVector qg=p1in-p1out-pg;
	CLHEP::HepLorentzVector q2=-(p2in-p2out-pe-pnu);

	mj2m=jWbar(p2out,false,pe,false,pnu,false,p2in,false);
	mj1p=j(p1out,true,p1in,true);
	mj1m=j(p1out,false,p1in,false);


	// Dot products of these which occur again and again
	COM MWpm=mj1p.dot(mj2m); // And now for the Higgs ones
	COM MWmm=mj1m.dot(mj2m);

	CCurrent jgam,jgap,j2gm,j2gp;
	j2gp=joo(p1out,true,pg,true);
	j2gm=joo(p1out,false,pg,false);
	jgap=j(pg,true,p1in,true);
	jgam=j(pg,false,p1in,false);

	CCurrent qsum(q1+qg);

	CCurrent Lmp,Lmm,Lpp,Lpm,U1mp,U1mm,U1pp,U1pm,U2mp,U2mm,U2pp,U2pm,p2o(p2out),p2i(p2in);
	CCurrent p1o(p1out);
	CCurrent p1i(p1in);

	Lmm=(qsum(MWmm) + (-2.mj2m.dot(pg))mj1m+2.mj1m.dot(pg)mj2m+(p2o/pg.dot(p2out) + p2i/pg.dot(p2in))(qg.m2()*MWmm/2.))/q1.m2();
	Lpm=(qsum(MWpm) + (-2.mj2m.dot(pg))mj1p+2.mj1p.dot(pg)mj2m+(p2o/pg.dot(p2out) + p2i/pg.dot(p2in))(qg.m2()*MWpm/2.))/q1.m2();


	U1mm=(jgam.dot(mj2m)j2gm+2.p1o*MWmm)/(p1out+pg).m2();
	U1pm=(jgap.dot(mj2m)j2gp+2.p1o*MWpm)/(p1out+pg).m2();

	U2mm=((-1.)j2gm.dot(mj2m)jgam+2.p1iMWmm)/(p1in-pg).m2();
	U2pm=((-1.)j2gp.dot(mj2m)jgap+2.p1iMWpm)/(p1in-pg).m2();

	double amm,apm;

	amm=HEJ::C_F(2.vre(Lmm-U1mm,Lmm+U2mm))+2.HEJ::C_FHEJ::C_F/3.*vabs2(U1mm+U2mm);
	apm=HEJ::C_F(2.vre(Lpm-U1pm,Lpm+U2pm))+2.HEJ::C_FHEJ::C_F/3.*vabs2(U1pm+U2pm);

	double ampsq=-(apm+amm);

	// Now add the t-channels
	double th=q2.m2()*qg.m2();
	ampsq/=th;
	ampsq/=16.;

	return ampsq;
	}

	//qbarQ->qbarQWg_unof
	double junofMWgqbarQ (CLHEP::HepLorentzVector pg,CLHEP::HepLorentzVector p1out,CLHEP::HepLorentzVector p1in, CLHEP::HepLorentzVector p2out, CLHEP::HepLorentzVector pe, CLHEP::HepLorentzVector pnu, CLHEP::HepLorentzVector p2in)
	// Calculates the square of the current contractions for qQ->qenuQ scattering
	// p1: quark (with W emittance)
	// p2: Quark
	{
	CCurrent mj2m,mj1p,mj1m;
	CLHEP::HepLorentzVector q1=p1in-p1out;
	CLHEP::HepLorentzVector qg=p1in-p1out-pg;
	CLHEP::HepLorentzVector q2=-(p2in-p2out-pe-pnu);

	mj2m=jW(p2out,false,pe,false,pnu,false,p2in,false);
	mj1p=jio(p1in,true,p1out,true);
	mj1m=jio(p1in,false,p1out,false);


	// Dot products of these which occur again and again
	COM MWpm=mj1p.dot(mj2m); // And now for the Higgs ones
	COM MWmm=mj1m.dot(mj2m);

	CCurrent jgam,jgap,j2gm,j2gp;
	j2gp=joo(pg,true,p1out,true);
	j2gm=joo(pg,false,p1out,false);
	jgap=jio(p1in,true,pg,true);
	jgam=jio(p1in,false,pg,false);

	CCurrent qsum(q1+qg);

	CCurrent Lmp,Lmm,Lpp,Lpm,U1mp,U1mm,U1pp,U1pm,U2mp,U2mm,U2pp,U2pm,p2o(p2out),p2i(p2in);
	CCurrent p1o(p1out);
	CCurrent p1i(p1in);

	Lmm=(qsum(MWmm) + (-2.mj2m.dot(pg))mj1m+2.mj1m.dot(pg)mj2m+(p2o/pg.dot(p2out) + p2i/pg.dot(p2in))(qg.m2()*MWmm/2.))/q1.m2();
	Lpm=(qsum(MWpm) + (-2.mj2m.dot(pg))mj1p+2.mj1p.dot(pg)mj2m+(p2o/pg.dot(p2out) + p2i/pg.dot(p2in))(qg.m2()*MWpm/2.))/q1.m2();


	U1mm=(jgam.dot(mj2m)j2gm+2.p1o*MWmm)/(p1out+pg).m2();
	U1pm=(jgap.dot(mj2m)j2gp+2.p1o*MWpm)/(p1out+pg).m2();

	U2mm=((-1.)j2gm.dot(mj2m)jgam+2.p1iMWmm)/(p1in-pg).m2();
	U2pm=((-1.)j2gp.dot(mj2m)jgap+2.p1iMWpm)/(p1in-pg).m2();

	double amm,apm;
	amm=HEJ::C_F(2.vre(Lmm-U1mm,Lmm+U2mm))+2.HEJ::C_FHEJ::C_F/3.*vabs2(U1mm+U2mm);
	apm=HEJ::C_F(2.vre(Lpm-U1pm,Lpm+U2pm))+2.HEJ::C_FHEJ::C_F/3.*vabs2(U1pm+U2pm);

	double ampsq=-(apm+amm);

	// Now add the t-channels
	double th=q2.m2()*qg.m2();
	ampsq/=th;
	ampsq/=16.;

	return ampsq;


	}

	//qbarQbar->qbarQbarWg_unof
	double junofMWgqbarQbar (CLHEP::HepLorentzVector pg,CLHEP::HepLorentzVector p1out,CLHEP::HepLorentzVector p1in, CLHEP::HepLorentzVector p2out, CLHEP::HepLorentzVector pe, CLHEP::HepLorentzVector pnu, CLHEP::HepLorentzVector p2in)
	// Calculates the square of the current contractions for qQ->qenuQ scattering
	// p1: quark (with W emittance)
	// p2: Quark
	{
	CCurrent mj2m,mj1p,mj1m;
	CLHEP::HepLorentzVector q1=p1in-p1out;
	CLHEP::HepLorentzVector qg=p1in-p1out-pg;
	CLHEP::HepLorentzVector q2=-(p2in-p2out-pe-pnu);

	mj2m=jWbar(p2out,false,pe,false,pnu,false,p2in,false);
	mj1p=jio(p1in,true,p1out,true);
	mj1m=jio(p1in,false,p1out,false);


	// Dot products of these which occur again and again
	COM MWpm=mj1p.dot(mj2m); // And now for the Higgs ones
	COM MWmm=mj1m.dot(mj2m);

	CCurrent jgam,jgap,j2gm,j2gp;
	j2gp=joo(pg,true,p1out,true);
	j2gm=joo(pg,false,p1out,false);
	jgap=jio(p1in,true,pg,true);
	jgam=jio(p1in,false,pg,false);

	CCurrent qsum(q1+qg);

	CCurrent Lmp,Lmm,Lpp,Lpm,U1mp,U1mm,U1pp,U1pm,U2mp,U2mm,U2pp,U2pm,p2o(p2out),p2i(p2in);
	CCurrent p1o(p1out);
	CCurrent p1i(p1in);

	Lmm=(qsum(MWmm) + (-2.mj2m.dot(pg))mj1m+2.mj1m.dot(pg)mj2m+(p2o/pg.dot(p2out) + p2i/pg.dot(p2in))(qg.m2()*MWmm/2.))/q1.m2();
	Lpm=(qsum(MWpm) + (-2.mj2m.dot(pg))mj1p+2.mj1p.dot(pg)mj2m+(p2o/pg.dot(p2out) + p2i/pg.dot(p2in))(qg.m2()*MWpm/2.))/q1.m2();

	U1mm=(jgam.dot(mj2m)j2gm+2.p1o*MWmm)/(p1out+pg).m2();
	U1pm=(jgap.dot(mj2m)j2gp+2.p1o*MWpm)/(p1out+pg).m2();

	U2mm=((-1.)j2gm.dot(mj2m)jgam+2.p1iMWmm)/(p1in-pg).m2();
	U2pm=((-1.)j2gp.dot(mj2m)jgap+2.p1iMWpm)/(p1in-pg).m2();

	double amm,apm;

	amm=HEJ::C_F(2.vre(Lmm-U1mm,Lmm+U2mm))+2.HEJ::C_FHEJ::C_F/3.*vabs2(U1mm+U2mm);
	apm=HEJ::C_F(2.vre(Lpm-U1pm,Lpm+U2pm))+2.HEJ::C_FHEJ::C_F/3.*vabs2(U1pm+U2pm);



	double ampsq=-(apm+amm);


	// Now add the t-channels
	double th=q2.m2()*qg.m2();
	ampsq/=th;
	ampsq/=16.;
	return ampsq;


	}



	///TODO make this comment more visible
	/// Naming scheme jM2-Wuno-g-({q/qbar}{Q/Qbar/g})
	///TODO Spit naming for more complicated functions?
	/// e.g. jM2WqqtoqQQq -> jM2_Wqq_to_qQQq
	double jM2WunogqQ(CLHEP::HepLorentzVector pg, CLHEP::HepLorentzVector p1out,CLHEP::HepLorentzVector plbar,CLHEP::HepLorentzVector pl, CLHEP::HepLorentzVector p1in, CLHEP::HepLorentzVector p2out, CLHEP::HepLorentzVector p2in)
	{
	//COM temp;
	double ME2mpp=0.;
	double ME2mpm=0.;
	double ME2mmp=0.;
	double ME2mmm=0.;
	double ME2;

	ME2mpp = jM2Wuno(pg, p1out,plbar,pl,p1in,false,p2out,p2in,true,true);
	ME2mpm = jM2Wuno(pg, p1out,plbar,pl,p1in,false,p2out,p2in,true,false);
	ME2mmp = jM2Wuno(pg, p1out,plbar,pl,p1in,false,p2out,p2in,false,true);
	ME2mmm = jM2Wuno(pg, p1out,plbar,pl,p1in,false,p2out,p2in,false,false);

	//Helicity sum
	ME2 = ME2mpp + ME2mpm + ME2mmp + ME2mmm;

	return ME2;

	}

	//same as function above but actually obtaining the antiquark line by crossing symmetry, where p1out and p1in are expected to be negative.
	//should give same result as jM2WunogqbarQ below (verified)
	double jM2WunogqQ_crossqQ(CLHEP::HepLorentzVector pg, CLHEP::HepLorentzVector p1out,CLHEP::HepLorentzVector plbar,CLHEP::HepLorentzVector pl, CLHEP::HepLorentzVector p1in, CLHEP::HepLorentzVector p2out, CLHEP::HepLorentzVector p2in)
	{
	//COM temp;
	double ME2mpp=0.;
	double ME2mpm=0.;
	double ME2mmp=0.;
	double ME2mmm=0.;
	double ME2;

	ME2mpp = jM2Wuno(pg, p1out,plbar,pl,p1in,false,p2out,p2in,true,true);
	ME2mpm = jM2Wuno(pg, p1out,plbar,pl,p1in,false,p2out,p2in,true,false);
	ME2mmp = jM2Wuno(pg, p1out,plbar,pl,p1in,false,p2out,p2in,false,true);
	ME2mmm = jM2Wuno(pg, p1out,plbar,pl,p1in,false,p2out,p2in,false,false);

	//Helicity sum
	ME2 = ME2mpp + ME2mpm + ME2mmp + ME2mmm;

	return ME2;

	}

	double jM2WunogqQbar(CLHEP::HepLorentzVector pg, CLHEP::HepLorentzVector p1out,CLHEP::HepLorentzVector plbar,CLHEP::HepLorentzVector pl, CLHEP::HepLorentzVector p1in, CLHEP::HepLorentzVector p2out, CLHEP::HepLorentzVector p2in)
	{
	//COM temp;
	double ME2mpp=0.;
	double ME2mpm=0.;
	double ME2mmp=0.;
	double ME2mmm=0.;
	double ME2;

	ME2mpp = jM2Wuno(pg, p1out,plbar,pl,p1in,false,p2out,p2in,true,true);
	ME2mpm = jM2Wuno(pg, p1out,plbar,pl,p1in,false,p2out,p2in,true,false);
	ME2mmp = jM2Wuno(pg, p1out,plbar,pl,p1in,false,p2out,p2in,false,true);
	ME2mmm = jM2Wuno(pg, p1out,plbar,pl,p1in,false,p2out,p2in,false,false);

	//Helicity sum
	ME2 = ME2mpp + ME2mpm + ME2mmp + ME2mmm;

	return ME2;

	}

	double jM2Wunogqg(CLHEP::HepLorentzVector pg, CLHEP::HepLorentzVector p1out,CLHEP::HepLorentzVector plbar,CLHEP::HepLorentzVector pl, CLHEP::HepLorentzVector p1in, CLHEP::HepLorentzVector p2out, CLHEP::HepLorentzVector p2in)
	{
	//COM temp;
	double ME2mpp=0.;
	double ME2mpm=0.;
	double ME2mmp=0.;
	double ME2mmm=0.;
	double ME2;

	ME2mpp = jM2Wuno(pg, p1out,plbar,pl,p1in,false,p2out,p2in,true,true);
	ME2mpm = jM2Wuno(pg, p1out,plbar,pl,p1in,false,p2out,p2in,true,false);
	ME2mmp = jM2Wuno(pg, p1out,plbar,pl,p1in,false,p2out,p2in,false,true);
	ME2mmm = jM2Wuno(pg, p1out,plbar,pl,p1in,false,p2out,p2in,false,false);

	//Helicity sum
	ME2 = ME2mpp + ME2mpm + ME2mmp + ME2mmm;

	double ratio; // p2-/pb- in the notes
	if (p2in.pz()>0.) // if the gluon is the positive
	ratio=p2out.plus()/p2in.plus();
	else // the gluon is the negative
	ratio=p2out.minus()/p2in.minus();

	double cam = ( (HEJ::C_A - 1/HEJ::C_A)*(ratio + 1./ratio)/2. + 1/HEJ::C_A)/HEJ::C_F;
	ME2*=cam;

	return ME2;

	}

	double jM2WunogqbarQ(CLHEP::HepLorentzVector pg, CLHEP::HepLorentzVector p1out,CLHEP::HepLorentzVector plbar,CLHEP::HepLorentzVector pl, CLHEP::HepLorentzVector p1in, CLHEP::HepLorentzVector p2out, CLHEP::HepLorentzVector p2in)
	{
	//COM temp;
	double ME2mpp=0.;
	double ME2mpm=0.;
	double ME2mmp=0.;
	double ME2mmm=0.;
	double ME2;

	ME2mpp = jM2Wuno(pg, p1out,plbar,pl,p1in,true,p2out,p2in,true,true);
	ME2mpm = jM2Wuno(pg, p1out,plbar,pl,p1in,true,p2out,p2in,true,false);
	ME2mmp = jM2Wuno(pg, p1out,plbar,pl,p1in,true,p2out,p2in,false,true);
	ME2mmm = jM2Wuno(pg, p1out,plbar,pl,p1in,true,p2out,p2in,false,false);

	//Helicity sum
	ME2 = ME2mpp + ME2mpm + ME2mmp + ME2mmm;

	return ME2;

	}

	double jM2WunogqbarQbar(CLHEP::HepLorentzVector pg, CLHEP::HepLorentzVector p1out,CLHEP::HepLorentzVector plbar,CLHEP::HepLorentzVector pl, CLHEP::HepLorentzVector p1in, CLHEP::HepLorentzVector p2out, CLHEP::HepLorentzVector p2in)
	{
	//COM temp;
	double ME2mpp=0.;
	double ME2mpm=0.;
	double ME2mmp=0.;
	double ME2mmm=0.;
	double ME2;

	ME2mpp = jM2Wuno(pg, p1out,plbar,pl,p1in,true,p2out,p2in,true,true);
	ME2mpm = jM2Wuno(pg, p1out,plbar,pl,p1in,true,p2out,p2in,true,false);
	ME2mmp = jM2Wuno(pg, p1out,plbar,pl,p1in,true,p2out,p2in,false,true);
	ME2mmm = jM2Wuno(pg, p1out,plbar,pl,p1in,true,p2out,p2in,false,false);

	//Helicity sum
	ME2 = ME2mpp + ME2mpm + ME2mmp + ME2mmm;

	return ME2;

	}

	double jM2Wunogqbarg(CLHEP::HepLorentzVector pg, CLHEP::HepLorentzVector p1out,CLHEP::HepLorentzVector plbar,CLHEP::HepLorentzVector pl, CLHEP::HepLorentzVector p1in, CLHEP::HepLorentzVector p2out, CLHEP::HepLorentzVector p2in)
	{
	//COM temp;
	double ME2mpp=0.;
	double ME2mpm=0.;
	double ME2mmp=0.;
	double ME2mmm=0.;
	double ME2;

	ME2mpp = jM2Wuno(pg, p1out,plbar,pl,p1in,true,p2out,p2in,true,true);
	ME2mpm = jM2Wuno(pg, p1out,plbar,pl,p1in,true,p2out,p2in,true,false);
	ME2mmp = jM2Wuno(pg, p1out,plbar,pl,p1in,true,p2out,p2in,false,true);
	ME2mmm = jM2Wuno(pg, p1out,plbar,pl,p1in,true,p2out,p2in,false,false);

	//Helicity sum
	ME2 = ME2mpp + ME2mpm + ME2mmp + ME2mmm;

	double ratio; // p2-/pb- in the notes
	if (p2in.pz()>0.) // if the gluon is the positive
	ratio=p2out.plus()/p2in.plus();
	else // the gluon is the negative
	ratio=p2out.minus()/p2in.minus();

	double cam = ( (HEJ::C_A - 1/HEJ::C_A)*(ratio + 1./ratio)/2. + 1/HEJ::C_A)/HEJ::C_F;
	ME2*=cam;

	return ME2;

	}


	// W+Jets qqxExtremal
	// W+Jets qqxExtremal Currents - wqq emission
	double jM2WgQtoqbarqQ(CLHEP::HepLorentzVector pgin, CLHEP::HepLorentzVector pqout,CLHEP::HepLorentzVector plbar,CLHEP::HepLorentzVector pl, CLHEP::HepLorentzVector pqbarout, CLHEP::HepLorentzVector p2out, CLHEP::HepLorentzVector p2in)
	{
	//COM temp;
	double ME2mpp=0.;
	double ME2mpm=0.;
	double ME2mmp=0.;
	double ME2mmm=0.;
	double ME2;

	ME2mpp = jM2Wuno(-pgin, pqout,plbar,pl,-pqbarout,false,p2out,p2in,true,true);
	ME2mpm = jM2Wuno(-pgin, pqout,plbar,pl,-pqbarout,false,p2out,p2in,true,false);
	ME2mmp = jM2Wuno(-pgin, pqout,plbar,pl,-pqbarout,false,p2out,p2in,false,true);
	ME2mmm = jM2Wuno(-pgin, pqout,plbar,pl,-pqbarout,false,p2out,p2in,false,false);

	//Helicity sum
	ME2 = ME2mpp + ME2mpm + ME2mmp + ME2mmm;

	//Correct colour averaging
	ME2*=(3.0/8.0);

	return ME2;

	}

	double jM2WgQtoqqbarQ(CLHEP::HepLorentzVector pgin, CLHEP::HepLorentzVector pqbarout,CLHEP::HepLorentzVector plbar,CLHEP::HepLorentzVector pl, CLHEP::HepLorentzVector pqout, CLHEP::HepLorentzVector p2out, CLHEP::HepLorentzVector p2in){

	//COM temp;
	double ME2mpp=0.;
	double ME2mpm=0.;
	double ME2mmp=0.;
	double ME2mmm=0.;
	double ME2;

	ME2mpp = jM2Wuno(-pgin, pqbarout,plbar,pl,-pqout,true,p2out,p2in,true,true);
	ME2mpm = jM2Wuno(-pgin, pqbarout,plbar,pl,-pqout,true,p2out,p2in,true,false);
	ME2mmp = jM2Wuno(-pgin, pqbarout,plbar,pl,-pqout,true,p2out,p2in,false,true);
	ME2mmm = jM2Wuno(-pgin, pqbarout,plbar,pl,-pqout,true,p2out,p2in,false,false);

	//Helicity sum
	ME2 = ME2mpp + ME2mpm + ME2mmp + ME2mmm;

	//Correct colour averaging
	ME2*=(3.0/8.0);

	return ME2;

	}


	double jM2Wggtoqbarqg(CLHEP::HepLorentzVector pgin, CLHEP::HepLorentzVector pqout,CLHEP::HepLorentzVector plbar,CLHEP::HepLorentzVector pl, CLHEP::HepLorentzVector pqbarout, CLHEP::HepLorentzVector p2out, CLHEP::HepLorentzVector p2in)
	{
	//COM temp;
	double ME2mpp=0.;
	double ME2mpm=0.;
	double ME2mmp=0.;
	double ME2mmm=0.;
	double ME2;

	ME2mpp = jM2Wuno(-pgin, pqout,plbar,pl,-pqbarout,false,p2out,p2in,true,true);
	ME2mpm = jM2Wuno(-pgin, pqout,plbar,pl,-pqbarout,false,p2out,p2in,true,false);
	ME2mmp = jM2Wuno(-pgin, pqout,plbar,pl,-pqbarout,false,p2out,p2in,false,true);
	ME2mmm = jM2Wuno(-pgin, pqout,plbar,pl,-pqbarout,false,p2out,p2in,false,false);

	//Helicity sum
	ME2 = ME2mpp + ME2mpm + ME2mmp + ME2mmm;

	double ratio; // p2-/pb- in the notes
	if (p2in.pz()>0.) // if the gluon is the positive
	ratio=p2out.plus()/p2in.plus();
	else // the gluon is the negative
	ratio=p2out.minus()/p2in.minus();

	double cam = ( (HEJ::C_A - 1/HEJ::C_A)*(ratio + 1./ratio)/2. + 1/HEJ::C_A)/HEJ::C_F;
	ME2*=cam;

	//Correct colour averaging
	ME2*=(3.0/8.0);

	return ME2;
	}

	double jM2Wggtoqqbarg(CLHEP::HepLorentzVector pgin, CLHEP::HepLorentzVector pqbarout,CLHEP::HepLorentzVector plbar,CLHEP::HepLorentzVector pl, CLHEP::HepLorentzVector pqout, CLHEP::HepLorentzVector p2out, CLHEP::HepLorentzVector p2in){

	//COM temp;
	double ME2mpp=0.;
	double ME2mpm=0.;
	double ME2mmp=0.;
	double ME2mmm=0.;
	double ME2;

	ME2mpp = jM2Wuno(-pgin, pqbarout,plbar,pl,-pqout,true,p2out,p2in,true,true);
	ME2mpm = jM2Wuno(-pgin, pqbarout,plbar,pl,-pqout,true,p2out,p2in,true,false);
	ME2mmp = jM2Wuno(-pgin, pqbarout,plbar,pl,-pqout,true,p2out,p2in,false,true);
	ME2mmm = jM2Wuno(-pgin, pqbarout,plbar,pl,-pqout,true,p2out,p2in,false,false);

	//Helicity sum
	ME2 = ME2mpp + ME2mpm + ME2mmp + ME2mmm;

	double ratio; // p2-/pb- in the notes
	if (p2in.pz()>0.) // if the gluon is the positive
	ratio=p2out.plus()/p2in.plus();
	else // the gluon is the negative
	ratio=p2out.minus()/p2in.minus();

	double cam = ( (HEJ::C_A - 1/HEJ::C_A)*(ratio + 1./ratio)/2. + 1/HEJ::C_A)/HEJ::C_F;
	ME2*=cam;

	//Correct colour averaging
	ME2*=(3.0/8.0);

	return ME2;

	}


	namespace {
	//Function to calculate Term 1 in Equation 3.23 in James Cockburn's Thesis.
	Tensor<1,4> qggm1(CLHEP::HepLorentzVector pb, CLHEP::HepLorentzVector p2, CLHEP::HepLorentzVector p3, bool hel2, bool helg, CLHEP::HepLorentzVector refmom){

	double t1 = (p3-pb)*(p3-pb);
	Tensor<1,4> Tp3 = Construct1Tensor((p3));//p3
	Tensor<1,4> Tpb = Construct1Tensor((pb));//pb
	// Gauge choice in polarisation tensor. (see JC's Thesis)
	Tensor<1,4> epsg = eps(pb, refmom, helg);
	Tensor<3,4> qqCurBlank = T3Current(p2,hel2,p3,hel2);
	Tensor<2,4> qqCur = qqCurBlank.contract(Tp3-Tpb,2);
	Tensor<1,4> gqqCur = qqCur.contract(epsg,2)/t1;

	return gqqCur;
	}

	//Function to calculate Term 2 in Equation 3.23 in James Cockburn's Thesis.
	Tensor<1,4> qggm2(CLHEP::HepLorentzVector pb, CLHEP::HepLorentzVector p2, CLHEP::HepLorentzVector p3, bool hel2, bool helg, CLHEP::HepLorentzVector refmom){

	double t1 = (p2-pb)*(p2-pb);
	Tensor<1,4> Tp3 = Construct1Tensor((p3));//p3
	Tensor<1,4> Tpb = Construct1Tensor((pb));//pb
	// Gauge choice in polarisation tensor. (see JC's Thesis)
	Tensor<1,4> epsg = eps(pb,refmom, helg);
	Tensor<3,4> qqCurBlank = T3Current(p2,hel2,p3,hel2);
	Tensor<2,4> qqCur = qqCurBlank.contract(Tp3-Tpb,2);
	Tensor<1,4> gqqCur = qqCur.contract(epsg,1)/t1;

	return gqqCur;
	}

	//Function to calculate Term 3 in Equation 3.23 in James Cockburn's Thesis.
	Tensor<1,4> qggm3(CLHEP::HepLorentzVector pb, CLHEP::HepLorentzVector p2, CLHEP::HepLorentzVector p3, bool hel2, bool helg, CLHEP::HepLorentzVector refmom){

	double s23 = (p2+p3)*(p2+p3);
	Tensor<1,4> Tp2 = Construct1Tensor((p2));//p2
	Tensor<1,4> Tp3 = Construct1Tensor((p3));//p3
	Tensor<1,4> Tpb = Construct1Tensor((pb));//pb
	// Gauge choice in polarisation tensor. (see JC's Thesis)
	Tensor<1,4> epsg = eps(pb, refmom, helg);
	Tensor<2,4> g=Metric();
	Tensor<3,4> qqCurBlank1 = g.leftprod(Tp2+Tp3)/s23;
	Tensor<3,4> qqCurBlank2 = g.leftprod(Tpb)/s23;
	Tensor<1,4> Cur23 = TCurrent(p2,hel2, p3,hel2);

	Tensor<2,4> qqCur1 = qqCurBlank1.contract(Cur23,3);
	Tensor<2,4> qqCur2 = qqCurBlank2.contract(Cur23,3);
	Tensor<2,4> qqCur3 = qqCurBlank2.contract(Cur23,1);

	Tensor<1,4> gqqCur = (qqCur1.contract(epsg,1)
	- qqCur1.contract(epsg,2)
	+ qqCur1.contract(epsg,2))*2;
	return gqqCur;
	}
	}

	// no wqq emission
	double jM2WgqtoQQqW(CLHEP::HepLorentzVector pa, CLHEP::HepLorentzVector pb, CLHEP::HepLorentzVector p1, CLHEP::HepLorentzVector p2, CLHEP::HepLorentzVector p3,CLHEP::HepLorentzVector plbar,CLHEP::HepLorentzVector pl, bool aqlinepa){

	// 2 independent helicity choices (complex conjugation related).
	Tensor<1,4> TMmmm1 = qggm1(pb,p2,p3,false,false, pa);
	Tensor<1,4> TMmmm2 = qggm2(pb,p2,p3,false,false, pa);
	Tensor<1,4> TMmmm3 = qggm3(pb,p2,p3,false,false, pa);
	Tensor<1,4> TMpmm1 = qggm1(pb,p2,p3,false,true, pa);
	Tensor<1,4> TMpmm2 = qggm2(pb,p2,p3,false,true, pa);
	Tensor<1,4> TMpmm3 = qggm3(pb,p2,p3,false,true, pa);

	// Build the external quark line W Emmision
	Tensor<1,4> cur1a = jW(pa,p1,plbar,pl, aqlinepa);

	//Contract with the qqxCurrent.
	COM Mmmm1 = TMmmm1.contract(cur1a,1).at(0);
	COM Mmmm2 = TMmmm2.contract(cur1a,1).at(0);
	COM Mmmm3 = TMmmm3.contract(cur1a,1).at(0);
	COM Mpmm1 = TMpmm1.contract(cur1a,1).at(0);
	COM Mpmm2 = TMpmm2.contract(cur1a,1).at(0);
	COM Mpmm3 = TMpmm3.contract(cur1a,1).at(0);

	//Colour factors:
	COM cm1m1,cm2m2,cm3m3,cm1m2,cm1m3,cm2m3;
	cm1m1=8./3.;
	cm2m2=8./3.;
	cm3m3=6.;
	cm1m2 =-1./3.;
	cm1m3 = -3.*COM(0.,1.);
	cm2m3 = 3.*COM(0.,1.);

	//Sqaure and sum for each helicity config:
	double Mmmm = real(cm1m1pow(abs(Mmmm1),2)+cm2m2pow(abs(Mmmm2),2)+cm3m3pow(abs(Mmmm3),2)+2.real(cm1m2Mmmm1conj(Mmmm2))+2.real(cm1m3Mmmm1conj(Mmmm3))+2.real(cm2m3Mmmm2conj(Mmmm3)));
	double Mpmm = real(cm1m1pow(abs(Mpmm1),2)+cm2m2pow(abs(Mpmm2),2)+cm3m3pow(abs(Mpmm3),2)+2.real(cm1m2Mpmm1conj(Mpmm2))+2.real(cm1m3Mpmm1conj(Mpmm3))+2.real(cm2m3Mpmm2conj(Mpmm3)));

	return (2*(Mmmm+Mpmm)/24./4.)/(pa-p1).m2()/(p2+p3-pb).m2();
	}


	// W+Jets qqxCentral
	double jM2WqqtoqQQq(CLHEP::HepLorentzVector pa, CLHEP::HepLorentzVector pb,CLHEP::HepLorentzVector pl, CLHEP::HepLorentzVector plbar, std::vector<HLV> partons, bool aqlinepa, bool aqlinepb, bool qqxmarker, int nabove)
	{

	static bool is_sigma_index_set(false);
	if(!is_sigma_index_set){
	if(init_sigma_index())
	is_sigma_index_set = true;
	else
	return 0.;}

	HLV pq, pqbar, p1, p4;
	if (qqxmarker){
	pqbar = partons[nabove+1];
	pq = partons[nabove+2];}
	else{
	pq = partons[nabove+1];
	pqbar = partons[nabove+2];}

	p1 = partons.front();
	p4 = partons.back();

	Tensor<1,4> T1am, T4bm, T1ap, T4bp;
	if(!(aqlinepa)){
	T1ap = TCurrent(p1, true, pa, true);
	T1am = TCurrent(p1, false, pa, false);}
	else if(aqlinepa){
	T1ap = TCurrent(pa, true, p1, true);
	T1am = TCurrent(pa, false, p1, false);}
	if(!(aqlinepb)){
	T4bp = TCurrent(p4, true, pb, true);
	T4bm = TCurrent(p4, false, pb, false);}
	else if(aqlinepb){
	T4bp = TCurrent(pb, true, p4, true);
	T4bm = TCurrent(pb, false, p4, false);}

	// Calculate the 3 separate contributions to the effective vertex
	Tensor<2,4> Xunc = MUncrossW(pa, p1, pb, p4, pq, pqbar, pl, plbar, partons, nabove);
	Tensor<2,4> Xcro = MCrossW( pa, p1, pb, p4, pq, pqbar, pl, plbar, partons, nabove);
	Tensor<2,4> Xsym = MSymW( pa, p1, pb, p4, pq, pqbar, pl, plbar, partons, nabove);

	// 4 Different Helicity Choices (Differs from Pure Jet Case, where there is also the choice in qqbar helicity.
	// (- - hel choice)
	COM M_mmUnc = (((Xunc).contract(T1am,1)).contract(T4bm,1)).at(0);
	COM M_mmCro = (((Xcro).contract(T1am,1)).contract(T4bm,1)).at(0);
	COM M_mmSym = (((Xsym).contract(T1am,1)).contract(T4bm,1)).at(0);
	// (- + hel choice)
	COM M_mpUnc = (((Xunc).contract(T1am,1)).contract(T4bp,1)).at(0);
	COM M_mpCro = (((Xcro).contract(T1am,1)).contract(T4bp,1)).at(0);
	COM M_mpSym = (((Xsym).contract(T1am,1)).contract(T4bp,1)).at(0);
	// (+ - hel choice)
	COM M_pmUnc = (((Xunc).contract(T1ap,1)).contract(T4bm,1)).at(0);
	COM M_pmCro = (((Xcro).contract(T1ap,1)).contract(T4bm,1)).at(0);
	COM M_pmSym = (((Xsym).contract(T1ap,1)).contract(T4bm,1)).at(0);
	// (+ + hel choice)
	COM M_ppUnc = (((Xunc).contract(T1ap,1)).contract(T4bp,1)).at(0);
	COM M_ppCro = (((Xcro).contract(T1ap,1)).contract(T4bp,1)).at(0);
	COM M_ppSym = (((Xsym).contract(T1ap,1)).contract(T4bp,1)).at(0);

	//Colour factors:
	COM cmsms,cmumu,cmcmc,cmsmu,cmsmc,cmumc;
	cmsms=3.;
	cmumu=4./3.;
	cmcmc=4./3.;
	cmsmu =3./2.*COM(0.,1.);
	cmsmc = -3./2.*COM(0.,1.);
	cmumc = -1./6.;

	// Work Out Interference in each case of helicity:
	double amp_mm = real(cmsms*pow(abs(M_mmSym),2)
	+cmumu*pow(abs(M_mmUnc),2)
	+cmcmc*pow(abs(M_mmCro),2)
	+2.real(cmsmuM_mmSym*conj(M_mmUnc))
	+2.real(cmsmcM_mmSym*conj(M_mmCro))
	+2.real(cmumcM_mmUnc*conj(M_mmCro)));

	double amp_mp = real(cmsms*pow(abs(M_mpSym),2)
	+cmumu*pow(abs(M_mpUnc),2)
	+cmcmc*pow(abs(M_mpCro),2)
	+2.real(cmsmuM_mpSym*conj(M_mpUnc))
	+2.real(cmsmcM_mpSym*conj(M_mpCro))
	+2.real(cmumcM_mpUnc*conj(M_mpCro)));

	double amp_pm = real(cmsms*pow(abs(M_pmSym),2)
	+cmumu*pow(abs(M_pmUnc),2)
	+cmcmc*pow(abs(M_pmCro),2)
	+2.real(cmsmuM_pmSym*conj(M_pmUnc))
	+2.real(cmsmcM_pmSym*conj(M_pmCro))
	+2.real(cmumcM_pmUnc*conj(M_pmCro)));

	double amp_pp = real(cmsms*pow(abs(M_ppSym),2)
	+cmumu*pow(abs(M_ppUnc),2)
	+cmcmc*pow(abs(M_ppCro),2)
	+2.real(cmsmuM_ppSym*conj(M_ppUnc))
	+2.real(cmsmcM_ppSym*conj(M_ppCro))
	+2.real(cmumcM_ppUnc*conj(M_ppCro)));

	double amp=((amp_mm+amp_mp+amp_pm+amp_pp)/(9.*4.));



	CLHEP::HepLorentzVector q1,q3;
	q1=pa;
	for(int i=0;i<nabove+1;i++){
	q1-=partons.at(i);
	}
	q3 = q1 - pq - pqbar - pl - plbar;

	double t1 = (q1).m2();
	double t3 = (q3).m2();

	//Divide by t-channels
	amp/=(t1t1t3*t3);

	return amp;
	}

	// no wqq emission
	double jM2WqqtoqQQqW(CLHEP::HepLorentzVector pa, CLHEP::HepLorentzVector pb,CLHEP::HepLorentzVector pl,CLHEP::HepLorentzVector plbar, std::vector<CLHEP::HepLorentzVector> partons, bool aqlinepa, bool aqlinepb, bool qqxmarker, int nabove, int nbelow, bool forwards){

	static bool is_sigma_index_set(false);
	if(!is_sigma_index_set){
	if(init_sigma_index())
	is_sigma_index_set = true;
	else
	return 0.;
	}

	if (!forwards){ //If Emission from Leg a instead, flip process.
	HLV dummymom = pa;
	bool dummybool= aqlinepa;
	int dummyint = nabove;
	pa = pb;
	pb = dummymom;
	std::reverse(partons.begin(),partons.end());
	qqxmarker = !(qqxmarker);
	aqlinepa = aqlinepb;
	aqlinepb = dummybool;
	nabove = nbelow;
	nbelow = dummyint;
	}

	HLV pq, pqbar, p1,p4;
	if (qqxmarker){
	pqbar = partons[nabove+1];
	pq = partons[nabove+2];}
	else{
	pq = partons[nabove+1];
	pqbar = partons[nabove+2];}

	p1 = partons.front();
	p4 = partons.back();

	Tensor<1,4> T1am(0.), T1ap(0.);
	if(!(aqlinepa)){
	T1ap = TCurrent(p1, true, pa, true);
	T1am = TCurrent(p1, false, pa, false);}
	else if(aqlinepa){
	T1ap = TCurrent(pa, true, p1, true);
	T1am = TCurrent(pa, false, p1, false);}

	Tensor <1,4> T4bm = jW(pb, p4, plbar, pl, aqlinepb);

	// Calculate the 3 separate contributions to the effective vertex
	Tensor<2,4> Xunc_m = MUncross(pa, pq, pqbar,partons, false, nabove);
	Tensor<2,4> Xcro_m = MCross( pa, pq, pqbar,partons, false, nabove);
	Tensor<2,4> Xsym_m = MSym( pa, p1, pb, p4, pq, pqbar, partons, false, nabove);

	Tensor<2,4> Xunc_p = MUncross(pa, pq, pqbar,partons, true, nabove);
	Tensor<2,4> Xcro_p = MCross( pa, pq, pqbar,partons, true, nabove);
	Tensor<2,4> Xsym_p = MSym( pa, p1, pb, p4, pq, pqbar, partons, true, nabove);


	// (- - hel choice)
	COM M_mmUnc = (((Xunc_m).contract(T1am,1)).contract(T4bm,1)).at(0);
	COM M_mmCro = (((Xcro_m).contract(T1am,1)).contract(T4bm,1)).at(0);
	COM M_mmSym = (((Xsym_m).contract(T1am,1)).contract(T4bm,1)).at(0);
	// (- + hel choice)
	COM M_mpUnc = (((Xunc_p).contract(T1am,1)).contract(T4bm,1)).at(0);
	COM M_mpCro = (((Xcro_p).contract(T1am,1)).contract(T4bm,1)).at(0);
	COM M_mpSym = (((Xsym_p).contract(T1am,1)).contract(T4bm,1)).at(0);
	// (+ - hel choice)
	COM M_pmUnc = (((Xunc_m).contract(T1ap,1)).contract(T4bm,1)).at(0);
	COM M_pmCro = (((Xcro_m).contract(T1ap,1)).contract(T4bm,1)).at(0);
	COM M_pmSym = (((Xsym_m).contract(T1ap,1)).contract(T4bm,1)).at(0);
	// (+ + hel choice)
	COM M_ppUnc = (((Xunc_p).contract(T1ap,1)).contract(T4bm,1)).at(0);
	COM M_ppCro = (((Xcro_p).contract(T1ap,1)).contract(T4bm,1)).at(0);
	COM M_ppSym = (((Xsym_p).contract(T1ap,1)).contract(T4bm,1)).at(0);

	//Colour factors:
	COM cmsms,cmumu,cmcmc,cmsmu,cmsmc,cmumc;
	cmsms=3.;
	cmumu=4./3.;
	cmcmc=4./3.;
	cmsmu =3./2.*COM(0.,1.);
	cmsmc = -3./2.*COM(0.,1.);
	cmumc = -1./6.;

	// Work Out Interference in each case of helicity:
	double amp_mm = real(cmsms*pow(abs(M_mmSym),2)
	+cmumu*pow(abs(M_mmUnc),2)
	+cmcmc*pow(abs(M_mmCro),2)
	+2.real(cmsmuM_mmSym*conj(M_mmUnc))
	+2.real(cmsmcM_mmSym*conj(M_mmCro))
	+2.real(cmumcM_mmUnc*conj(M_mmCro)));

	double amp_mp = real(cmsms*pow(abs(M_mpSym),2)
	+cmumu*pow(abs(M_mpUnc),2)
	+cmcmc*pow(abs(M_mpCro),2)
	+2.real(cmsmuM_mpSym*conj(M_mpUnc))
	+2.real(cmsmcM_mpSym*conj(M_mpCro))
	+2.real(cmumcM_mpUnc*conj(M_mpCro)));

	double amp_pm = real(cmsms*pow(abs(M_pmSym),2)
	+cmumu*pow(abs(M_pmUnc),2)
	+cmcmc*pow(abs(M_pmCro),2)
	+2.real(cmsmuM_pmSym*conj(M_pmUnc))
	+2.real(cmsmcM_pmSym*conj(M_pmCro))
	+2.real(cmumcM_pmUnc*conj(M_pmCro)));

	double amp_pp = real(cmsms*pow(abs(M_ppSym),2)
	+cmumu*pow(abs(M_ppUnc),2)
	+cmcmc*pow(abs(M_ppCro),2)
	+2.real(cmsmuM_ppSym*conj(M_ppUnc))
	+2.real(cmsmcM_ppSym*conj(M_ppCro))
	+2.real(cmumcM_ppUnc*conj(M_ppCro)));

	double amp=((amp_mm+amp_mp+amp_pm+amp_pp)/(9.*4.));

	CLHEP::HepLorentzVector q1,q3;
	q1=pa;
	for(int i=0;i<nabove+1;i++){
	q1-=partons.at(i);
	}
	q3 = q1 - pq - pqbar;

	double t1 = (q1).m2();
	double t3 = (q3).m2();

	//Divide by t-channels
	amp/=(t1t1t3*t3);

	return amp;
	}
	diff --git a/src/currents.cc b/src/currents.cc
	index 18a6152..f1407ab 100644
	--- a/src/currents.cc
	+++ b/src/currents.cc
	@@ -1,3497 +1,3210 @@
	//////////////////////////////////////////////////
	//////////////////////////////////////////////////
	// This source code is Copyright (2012) of //
	// Jeppe R. Andersen and Jennifer M. Smillie //
	// and is distributed under the //
	// Gnu Public License version 2 //
	// http://www.gnu.org/licenses/gpl-2.0.html //
	// You are allowed to distribute and alter the //
	// source under the conditions of the GPLv2 //
	// as long as this copyright notice //
	// is unaltered and distributed with the source //
	// Any use should comply with the //
	// MCNET GUIDELINES //
	// for Event Generator Authors and Users //
	// as distributed with this source code //
	//////////////////////////////////////////////////
	//////////////////////////////////////////////////
	#include "HEJ/currents.hh"

	#include <limits>

	#include "HEJ/Constants.hh"
	#include "HEJ/utility.hh"
	#include "HEJ/PDG_codes.hh"

	const COM looprwfactor = (COM(0.,1.)M_PIM_PI)/pow((2.*M_PI),4);
	constexpr double infinity = std::numeric_limits<double>::infinity();

	#ifdef HEJ_BUILD_WITH_QCDLOOP
	#include "qcdloop/qcdloop.h"
	#endif

	#include <iostream>
	#include <utility>

	namespace {
	// Loop integrals
	#ifdef HEJ_BUILD_WITH_QCDLOOP

	COM B0DD(CLHEP::HepLorentzVector q, double mq)
	{
	static std::vector<std::complex<double>> result(3);
	static auto ql_B0 = [](){
	ql::Bubble<std::complex<double>,double,double> ql_B0;
	ql_B0.setCacheSize(100);
	return ql_B0;
	}();
	static std::vector<double> masses(2);
	static std::vector<double> momenta(1);
	for(auto & m: masses) m = mq*mq;
	momenta.front() = q.m2();
	ql_B0.integral(result, 1, masses, momenta);
	return result[0];
	}
	COM C0DD(CLHEP::HepLorentzVector q1, CLHEP::HepLorentzVector q2, double mq)
	{
	static std::vector<std::complex<double>> result(3);
	static auto ql_C0 = [](){
	ql::Triangle<std::complex<double>,double,double> ql_C0;
	ql_C0.setCacheSize(100);
	return ql_C0;
	}();
	static std::vector<double> masses(3);
	static std::vector<double> momenta(3);
	for(auto & m: masses) m = mq*mq;
	momenta[0] = q1.m2();
	momenta[1] = q2.m2();
	momenta[2] = (q1+q2).m2();
	ql_C0.integral(result, 1, masses, momenta);
	return result[0];
	}
	COM D0DD(CLHEP::HepLorentzVector q1,CLHEP::HepLorentzVector q2, CLHEP::HepLorentzVector q3, double mq)
	{
	static std::vector<std::complex<double>> result(3);
	static auto ql_D0 = [](){
	ql::Box<std::complex<double>,double,double> ql_D0;
	ql_D0.setCacheSize(100);
	return ql_D0;
	}();
	static std::vector<double> masses(4);
	static std::vector<double> momenta(6);
	for(auto & m: masses) m = mq*mq;
	momenta[0] = q1.m2();
	momenta[1] = q2.m2();
	momenta[2] = q3.m2();
	momenta[3] = (q1+q2+q3).m2();
	momenta[4] = (q1+q2).m2();
	momenta[5] = (q2+q3).m2();
	ql_D0.integral(result, 1, masses, momenta);
	return result[0];
	}

	COM A1(CLHEP::HepLorentzVector q1, CLHEP::HepLorentzVector q2, double mt)
	// As given in Eq. (B.2) of VDD
	{
	double q12,q22,Q2;
	CLHEP::HepLorentzVector Q;
	double Delta3,mt2;
	COM ans(COM(0.,0.));

	q12=q1.m2();
	q22=q2.m2();
	Q=-q1-q2; // Define all momenta ingoing as in appendix of VDD
	Q2=Q.m2();

	Delta3=q12q12+q22q22+Q2Q2-2q12q22-2q12Q2-2q22*Q2;
	if (mt < 0.)
	std::cerr<<"Problem in A1! mt = "<<mt<<std::endl;
	mt2=mt*mt;

	ans=looprwfactorCOM(0,-1)C0DD(q1,q2,mt)( 4.mt2/Delta3*(Q2-q12-q22)
	-1.-4.q12q22/Delta3-12.q12q22Q2/Delta3/Delta3(q12+q22-Q2) )
	- looprwfactorCOM(0,-1)( B0DD(q2,mt)-B0DD(Q,mt) )
	* ( 2.q22/Delta3+12.q12q22/Delta3/Delta3(q22-q12+Q2) )
	- looprwfactorCOM(0,-1)( B0DD(q1,mt)-B0DD(Q,mt) )
	* ( 2.q12/Delta3+12.q12q22/Delta3/Delta3(q12-q22+Q2) )
	- 2./Delta3/16/M_PI/M_PI*(q12+q22-Q2);

	return ans;

	}


	COM A2(CLHEP::HepLorentzVector q1, CLHEP::HepLorentzVector q2, double mt)
	// As given in Eq. (B.2) of VDD, but with high energy limit
	// of invariants taken.
	{
	double q12,q22,Q2;
	CLHEP::HepLorentzVector Q;
	double Delta3,mt2;
	COM ans(COM(0.,0.));

	if (mt < 0.)
	std::cerr<<"Problem in A2! mt = "<<mt<<std::endl;
	mt2=mt*mt;

	q12=q1.m2();
	q22=q2.m2();
	Q=-q1-q2; // Define all momenta ingoing as in appendix of VDD
	Q2=Q.m2();

	Delta3=q12q12+q22q22+Q2Q2-2q12q22-2q12Q2-2q22*Q2;
	ans=looprwfactorCOM(0,-1)C0DD(q1,q2,mt)( 2.mt2+1./2.*(q12+q22-Q2)
	+2.q12q22*Q2/Delta3 )
	+looprwfactorCOM(0,-1)(B0DD(q2,mt)-B0DD(Q,mt))
	q22(q22-q12-Q2)/Delta3
	+looprwfactorCOM(0,-1)(B0DD(q1,mt)-B0DD(Q,mt))
	q12(q12-q22-Q2)/Delta3+1./16/M_PI/M_PI;

	return ans;
	}

	#else // no QCDloop

	COM A1(CLHEP::HepLorentzVector, CLHEP::HepLorentzVector, double) {
	throw std::logic_error{"A1 called without QCDloop support"};
	}

	COM A2(CLHEP::HepLorentzVector, CLHEP::HepLorentzVector, double) {
	throw std::logic_error{"A2 called without QCDloop support"};
	}

	#endif

	void to_current(const CLHEP::HepLorentzVector & q, current & ret){
	ret[0]=q.e();
	ret[1]=q.x();
	ret[2]=q.y();
	ret[3]=q.z();
	}

	constexpr double C_A = 3.;
	constexpr double C_F = 4./3.;
	- using ParticleID = HEJ::pid::ParticleID;
	+ // using ParticleID = HEJ::pid::ParticleID;
	+
	+
	+} // namespace anonymous

	// Colour acceleration multiplier for gluons see eq. (7) in arXiv:0910.5113
	// TODO: this is not a current and should be moved somewhere else
	double K_g(double p1minus, double paminus) {
	- return 1./2.(p1minus/paminus + paminus/p1minus)(C_A - 1./C_A) + 1./C_A;
	+ return 1./2.(p1minus/paminus + paminus/p1minus)(HEJ::C_A - 1./HEJ::C_A) + 1./HEJ::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());
	}

	-} // namespace anonymous
	-

	CCurrent CCurrent::operator+(const CCurrent& other)
	{
	COM result_c0=c0 + other.c0;
	COM result_c1=c1 + other.c1;
	COM result_c2=c2 + other.c2;
	COM result_c3=c3 + other.c3;

	return CCurrent(result_c0,result_c1,result_c2,result_c3);
	}

	CCurrent CCurrent::operator-(const CCurrent& other)
	{
	COM result_c0=c0 - other.c0;
	COM result_c1=c1 - other.c1;
	COM result_c2=c2 - other.c2;
	COM result_c3=c3 - other.c3;

	return CCurrent(result_c0,result_c1,result_c2,result_c3);
	}

	CCurrent CCurrent::operator*(const double x)
	{
	COM result_c0=x*CCurrent::c0;
	COM result_c1=x*CCurrent::c1;
	COM result_c2=x*CCurrent::c2;
	COM result_c3=x*CCurrent::c3;

	return CCurrent(result_c0,result_c1,result_c2,result_c3);
	}

	CCurrent CCurrent::operator/(const double x)
	{
	COM result_c0=CCurrent::c0/x;
	COM result_c1=CCurrent::c1/x;
	COM result_c2=CCurrent::c2/x;
	COM result_c3=CCurrent::c3/x;

	return CCurrent(result_c0,result_c1,result_c2,result_c3);
	}

	CCurrent CCurrent::operator*(const COM x)
	{
	COM result_c0=x*CCurrent::c0;
	COM result_c1=x*CCurrent::c1;
	COM result_c2=x*CCurrent::c2;
	COM result_c3=x*CCurrent::c3;

	return CCurrent(result_c0,result_c1,result_c2,result_c3);
	}

	CCurrent CCurrent::operator/(const COM x)
	{
	COM result_c0=(CCurrent::c0)/x;
	COM result_c1=(CCurrent::c1)/x;
	COM result_c2=(CCurrent::c2)/x;
	COM result_c3=(CCurrent::c3)/x;

	return CCurrent(result_c0,result_c1,result_c2,result_c3);
	}

	std::ostream& operator <<(std::ostream& os, const CCurrent& cur)
	{
	os << "("<<cur.c0<< " ; "<<cur.c1<<" , "<<cur.c2<<" , "<<cur.c3<<")";
	return os;
	}

	CCurrent operator * ( double x, CCurrent& m)
	{
	return m*x;
	}

	CCurrent operator * ( COM x, CCurrent& m)
	{
	return m*x;
	}

	CCurrent operator / ( double x, CCurrent& m)
	{
	return m/x;
	}

	CCurrent operator / ( COM x, CCurrent& m)
	{
	return m/x;
	}

	COM CCurrent::dot(CLHEP::HepLorentzVector p1)
	{
	// Current goes (E,px,py,pz)
	// std::cout<<"current = ("<<c0<<","<<c1<<","<<c2<<","<<c3<<")\n";
	// Vector goes (px,py,pz,E)
	// std::cout<<"vector = ("<<p1[0]<<","<<p1[1]<<","<<p1[2]<<","<<p1[3]<<")\n";
	return p1[3]c0-p1[0]c1-p1[1]c2-p1[2]c3;
	}

	COM CCurrent::dot(CCurrent p1)
	{
	return p1.c0c0-p1.c1c1-p1.c2c2-p1.c3c3;
	}

	//Current Functions

	// Current for <outgoing state \| mu \| incoming state>
	/// @TODO always use this instead of "j"
	/// @TODO isn't this jio with flipt helicities?
	void joi(HLV pout, bool helout, HLV pin, bool helin, current &cur) {
	cur[0]=0.;
	cur[1]=0.;
	cur[2]=0.;
	cur[3]=0.;

	const double sqpop = sqrt(pout.plus());
	const double sqpom = sqrt(pout.minus());
	const COM poperp = pout.x() + COM(0, 1) * pout.y();

	if (helout != helin) {
	throw std::invalid_argument{"Non-matching helicities"};
	} else if (helout == false) { // negative helicity
	if (pin.plus() > pin.minus()) { // if forward
	const double sqpip = sqrt(pin.plus());
	cur[0] = sqpop * sqpip;
	cur[1] = sqpom * sqpip * poperp / abs(poperp);
	cur[2] = -COM(0,1) * cur[1];
	cur[3] = cur[0];
	} else { // if backward
	const double sqpim = sqrt(pin.minus());
	cur[0] = -sqpom * sqpim * poperp / abs(poperp);
	cur[1] = -sqpim * sqpop;
	cur[2] = COM(0,1) * cur[1];
	cur[3] = -cur[0];
	}
	} else { // positive helicity
	if (pin.plus() > pin.minus()) { // if forward
	const double sqpip = sqrt(pin.plus());
	cur[0] = sqpop * sqpip;
	cur[1] = sqpom * sqpip * conj(poperp) / abs(poperp);
	cur[2] = COM(0,1) * cur[1];
	cur[3] = cur[0];
	} else { // if backward
	const double sqpim = sqrt(pin.minus());
	cur[0] = -sqpom * sqpim * conj(poperp) / abs(poperp);
	cur[1] = -sqpim * sqpop;
	cur[2] = -COM(0,1) * cur[1];
	cur[3] = -cur[0];
	}
	}
	}

	CCurrent joi (HLV pout, bool helout, HLV pin, bool helin)
	{
	current cur;
	joi(pout, helout, pin, helin, cur);
	return CCurrent(cur[0],cur[1],cur[2],cur[3]);
	}

	/// @TODO remove this
	void j (HLV pout, bool helout, HLV pin, bool helin,current &cur) {
	joi(pout, helout, pin, helin, cur);
	}

	/// @TODO remove this
	CCurrent j (HLV pout, bool helout, HLV pin, bool helin)
	{
	return joi(pout, helout, pin, helin);
	}


	// Current for <incoming state \| mu \| outgoing state>
	void jio(HLV pin, bool helin, HLV pout, bool helout, current &cur) {

	cur[0] = 0.0;
	cur[1] = 0.0;
	cur[2] = 0.0;
	cur[3] = 0.0;
	const double sqpop = sqrt(pout.plus());
	const double sqpom = sqrt(pout.minus());
	const COM poperp = pout.x() + COM(0, 1) * pout.y();


	if (helout != helin) {
	throw std::invalid_argument{"Non-matching helicities"};
	} else if (helout == false) { // negative helicity
	if (pin.plus() > pin.minus()) { // if forward
	const double sqpip = sqrt(pin.plus());
	cur[0] = sqpop * sqpip;
	cur[1] = sqpom * sqpip * conj(poperp) / abs(poperp);
	cur[2] = COM(0,1) * cur[1];
	cur[3] = cur[0];
	} else { // if backward
	const double sqpim = sqrt(pin.minus());
	cur[0] = -sqpom * sqpim * conj(poperp) / abs(poperp);
	cur[1] = -sqpim * sqpop;
	cur[2] = -COM(0,1) * cur[1];
	cur[3] = -cur[0];
	}
	} else { // positive helicity
	if (pin.plus() > pin.minus()) { // if forward
	const double sqpip = sqrt(pin.plus());
	cur[0] = sqpop * sqpip;
	cur[1] = sqpom * sqpip * poperp / abs(poperp);
	cur[2] = -COM(0,1) * cur[1];
	cur[3] = cur[0];
	} else { // if backward
	const double sqpim = sqrt(pin.minus());
	cur[0] = -sqpom * sqpim * poperp / abs(poperp);
	cur[1] = -sqpim * sqpop;
	cur[2] = COM(0,1) * cur[1];
	cur[3] = -cur[0];
	}
	}
	}

	CCurrent jio (HLV pin, bool helin, HLV pout, bool helout)
	{
	current cur;
	jio(pin, helin, pout, helout, cur);
	return CCurrent(cur[0],cur[1],cur[2],cur[3]);
	}


	// Current for <outgoing state \| mu \| outgoing state>
	void joo(HLV pi, bool heli, HLV pj, bool helj, current &cur) {

	// Zero our current
	cur[0] = 0.0;
	cur[1] = 0.0;
	cur[2] = 0.0;
	cur[3] = 0.0;
	if (heli!=helj) {
	throw std::invalid_argument{"Non-matching helicities"};
	} else if ( heli == true ) { // If positive helicity swap momenta
	std::swap(pi,pj);
	}

	const double sqpjp = sqrt(pj.plus());
	const double sqpjm = sqrt(pj.minus());
	const double sqpip = sqrt(pi.plus());
	const double sqpim = sqrt(pi.minus());

	const COM piperp = pi.x() + COM(0,1) * pi.y();
	const COM pjperp = pj.x() + COM(0,1) * pj.y();
	const COM phasei = piperp / abs(piperp);
	const COM phasej = pjperp / abs(pjperp);

	cur[0] = sqpim * sqpjm * phasei * conj(phasej) + sqpip * sqpjp;
	cur[1] = sqpim * sqpjp * phasei + sqpip * sqpjm * conj(phasej);
	cur[2] = -COM(0, 1) * (sqpim * sqpjp * phasei - sqpip * sqpjm * conj(phasej));
	cur[3] = -sqpim * sqpjm * phasei * conj(phasej) + sqpip * sqpjp;
	}

	CCurrent joo (HLV pi, bool heli, HLV pj, bool helj)
	{
	current cur;
	joo(pi, heli, pj, helj, cur);
	return CCurrent(cur[0],cur[1],cur[2],cur[3]);
	}

	namespace {
	/// @TODO unused function
	// double jM2 (CLHEP::HepLorentzVector p1out, bool hel1out, CLHEP::HepLorentzVector p1in, bool hel1in, CLHEP::HepLorentzVector p2out, bool hel2out, CLHEP::HepLorentzVector p2in, bool hel2in)
	// {
	// CLHEP::HepLorentzVector q1=p1in-p1out;
	// CLHEP::HepLorentzVector q2=-(p2in-p2out);
	// current C1,C2;
	// j (p1out,hel1out,p1in,hel1in, C1);
	// j (p2out,hel2out,p2in,hel2in, C2);

	// std::cout << "# From Currents, C1 : ("<<C1[0]<<","<<C1[1]<<","<<C1[2]<<","<<C1[3]<<"\n";
	// std::cout << "# From Currents, C2 : ("<<C2[0]<<","<<C2[1]<<","<<C2[2]<<","<<C2[3]<<"\n";

	// COM M=cdot(C1,C2);

	// return (Mconj(M)).real()/(q1.m2()q2.m2());
	// }

	- void jW (CLHEP::HepLorentzVector pout, bool helout, CLHEP::HepLorentzVector pe, bool hele, CLHEP::HepLorentzVector pnu, bool helnu, CLHEP::HepLorentzVector pin, bool helin, current cur)
	- {
	- // NOTA BENE: Conventions for W+ --> e+ nu, so that nu is lepton(6), e is anti-lepton(5)
	- // Need to swap e and nu for events with W- --> e- nubar!
	- if (helin==helout && hele==helnu) {
	- CLHEP::HepLorentzVector qa=pout+pe+pnu;
	- CLHEP::HepLorentzVector qb=pin-pe-pnu;
	- double ta(qa.m2()),tb(qb.m2());
	-
	- current t65,vout,vin,temp2,temp3,temp5;
	- joo(pnu,helnu,pe,hele,t65);
	- vout[0]=pout.e();
	- vout[1]=pout.x();
	- vout[2]=pout.y();
	- vout[3]=pout.z();
	- vin[0]=pin.e();
	- vin[1]=pin.x();
	- vin[2]=pin.y();
	- vin[3]=pin.z();
	-
	- COM brac615=cdot(t65,vout);
	- COM brac645=cdot(t65,vin);
	-
	- // prod1565 and prod6465 are zero for Ws (not Zs)!!
	- // noalias(temp)=prod(trans(CurrentOutOut(pout,helout,pnu,helout)),metric);
	- joo(pout,helout,pnu,helout,temp2);
	- // noalias(temp2)=prod(temp,ctemp);
	- COM prod1665=cdot(temp2,t65);
	- // noalias(temp)=prod(trans(Current(pe,helin,pin,helin)),metric);
	- // noalias(temp2)=prod(temp,ctemp);
	- joi(pe,helin,pin,helin,temp3);
	- COM prod5465=cdot(temp3,t65);
	- // noalias(temp)=prod(trans(Current(pnu,helin,pin,helin)),metric);
	- // noalias(temp2)=prod(temp,ctemp);
	-
	- joo(pout,helout,pe,helout,temp2);
	- joi(pnu,helnu,pin,helin,temp3);
	- joi(pout,helout,pin,helin,temp5);
	-
	- current term1,term2,term3,sum;
	- cmult(2.brac615/ta+2.brac645/tb,temp5,term1);
	- cmult(prod1665/ta,temp3,term2);
	- cmult(-prod5465/tb,temp2,term3);
	-
	- // cur=((2.brac615Current(pout,helout,pin,helin)+prod1565Current(pe,helin,pin,helin)+prod1665Current(pnu,helin,pin,helin))/ta + (2.brac645Current(pout,helout,pin,helin)-prod5465CurrentOutOut(pout,helout,pe,helout)-prod6465CurrentOutOut(pout,helout,pnu,helout))/tb);
	- // cur=((2.brac615temp5+prod1565temp3+prod1665temp4)/ta + (2.brac645temp5-prod5465temp1-prod6465temp2)/tb);
	- cadd(term1,term2,term3,sum);
	- // std::cout<<"sum: ("<<sum[0]<<","<<sum[1]<<","<<sum[2]<<","<<sum[3]<<")\n";
	- cur[0]=sum[0];
	- cur[1]=sum[1];
	- cur[2]=sum[2];
	- cur[3]=sum[3];
	- }
	- }
	-
	- void jWbar (CLHEP::HepLorentzVector pout, bool helout, CLHEP::HepLorentzVector pe, bool hele, CLHEP::HepLorentzVector pnu, bool helnu, CLHEP::HepLorentzVector pin, bool helin, current cur)
	- {
	- // NOTA BENE: Conventions for W+ --> e+ nu, so that nu is lepton(6), e is anti-lepton(5)
	- // Need to swap e and nu for events with W- --> e- nubar!
	- if (helin==helout && hele==helnu) {
	- CLHEP::HepLorentzVector qa=pout+pe+pnu;
	- CLHEP::HepLorentzVector qb=pin-pe-pnu;
	- double ta(qa.m2()),tb(qb.m2());
	-
	- current t65,vout,vin,temp2,temp3,temp5;
	- joo(pnu,helnu,pe,hele,t65);
	- vout[0]=pout.e();
	- vout[1]=pout.x();
	- vout[2]=pout.y();
	- vout[3]=pout.z();
	- vin[0]=pin.e();
	- vin[1]=pin.x();
	- vin[2]=pin.y();
	- vin[3]=pin.z();
	-
	- COM brac615=cdot(t65,vout);
	- COM brac645=cdot(t65,vin);
	-
	- // prod1565 and prod6465 are zero for Ws (not Zs)!!
	- joo(pe,helout,pout,helout,temp2); // temp2 is <5\|alpha\|1>
	- COM prod5165=cdot(temp2,t65);
	- jio(pin,helin,pnu,helin,temp3); // temp3 is <4\|alpha\|6>
	- COM prod4665=cdot(temp3,t65);
	-
	- joo(pnu,helout,pout,helout,temp2); // temp2 is now <6\|mu\|1>
	- jio(pin,helin,pe,helin,temp3); // temp3 is now <4\|mu\|5>
	- jio(pin,helin,pout,helout,temp5); // temp5 is <4\|mu\|1>
	-
	- current term1,term2,term3,sum;
	- cmult(-2.brac615/ta-2.brac645/tb,temp5,term1);
	- cmult(-prod5165/ta,temp3,term2);
	- cmult(prod4665/tb,temp2,term3);
	-
	- // cur=((2.brac615Current(pout,helout,pin,helin)+prod1565Current(pe,helin,pin,helin)+prod1665Current(pnu,helin,pin,helin))/ta + (2.brac645Current(pout,helout,pin,helin)-prod5465CurrentOutOut(pout,helout,pe,helout)-prod6465CurrentOutOut(pout,helout,pnu,helout))/tb);
	- // cur=((2.brac615temp5+prod1565temp3+prod1665temp4)/ta + (2.brac645temp5-prod5465temp1-prod6465temp2)/tb);
	- cadd(term1,term2,term3,sum);
	- // std::cout<<"term1: ("<<temp5[0]<<" "<<temp5[1]<<" "<<temp5[2]<<" "<<temp5[3]<<")"<<std::endl;
	- // std::cout<<"sum: ("<<sum[0]<<","<<sum[1]<<","<<sum[2]<<","<<sum[3]<<")\n";
	- cur[0]=sum[0];
	- cur[1]=sum[1];
	- cur[2]=sum[2];
	- cur[3]=sum[3];
	- }
	- }
	} // namespace anonymous

	-double jMWqQ (CLHEP::HepLorentzVector p1out, CLHEP::HepLorentzVector pe, CLHEP::HepLorentzVector pnu,CLHEP::HepLorentzVector p1in, CLHEP::HepLorentzVector p2out, CLHEP::HepLorentzVector p2in)
	-// Calculates the square of the current contractions for qQ->qenuQ scattering
	-// p1: quark (with W emittance)
	-// p2: Quark
	-{
	- current mj1m,mj2p,mj2m;
	- CLHEP::HepLorentzVector q1=p1in-p1out-pe-pnu;
	- CLHEP::HepLorentzVector q2=-(p2in-p2out);
	-
	- jW(p1out,false,pe,false,pnu,false,p1in,false,mj1m);
	- joi(p2out,true,p2in,true,mj2p);
	- joi(p2out,false,p2in,false,mj2m);
	-
	- COM Mmp=cdot(mj1m,mj2p);
	-
	- // mj1m.mj2m
	- COM Mmm=cdot(mj1m,mj2m);
	-
	- // sum of spinor strings \|\|^2
	- double a2Mmp=abs2(Mmp);
	- double a2Mmm=abs2(Mmm);
	-
	- // Leave division by colour and Helicity avg until Tree files
	- // Leave multi. of couplings to later
	- // Multiply by Cf^2
	- return C_FC_F(a2Mmp+a2Mmm)/(q1.m2()*q2.m2());
	-
	-}
	-
	-double jMWqQbar (CLHEP::HepLorentzVector p1out, CLHEP::HepLorentzVector pe, CLHEP::HepLorentzVector pnu,CLHEP::HepLorentzVector p1in, CLHEP::HepLorentzVector p2out, CLHEP::HepLorentzVector p2in)
	-// Calculates the square of the current contractions for qQ->qenuQ scattering
	-// p1: quark (with W emittance)
	-// p2: Quark
	-{
	- current mj1m,mj2p,mj2m;
	- CLHEP::HepLorentzVector q1=p1in-p1out-pe-pnu;
	- CLHEP::HepLorentzVector q2=-(p2in-p2out);
	-
	- jW(p1out,false,pe,false,pnu,false,p1in,false,mj1m);
	- jio(p2in,true,p2out,true,mj2p);
	- jio(p2in,false,p2out,false,mj2m);
	-
	- COM Mmp=cdot(mj1m,mj2p);
	-
	- // mj1m.mj2m
	- COM Mmm=cdot(mj1m,mj2m);
	-
	- // sum of spinor strings \|\|^2
	- double a2Mmp=abs2(Mmp);
	- double a2Mmm=abs2(Mmm);
	-
	- // Leave division by colour and Helicity avg until Tree files
	- // Leave multi. of couplings to later
	- // Multiply by Cf^2
	- return C_FC_F(a2Mmp+a2Mmm)/(q1.m2()*q2.m2());
	-
	-}
	-
	-double jMWqbarQ (CLHEP::HepLorentzVector p1out, CLHEP::HepLorentzVector pe, CLHEP::HepLorentzVector pnu,CLHEP::HepLorentzVector p1in, CLHEP::HepLorentzVector p2out, CLHEP::HepLorentzVector p2in)
	-// Calculates the square of the current contractions for qQ->qenuQ scattering
	-// p1: quark (with W emittance)
	-// p2: Quark
	-{
	- current mj1m,mj2p,mj2m;
	- CLHEP::HepLorentzVector q1=p1in-p1out-pe-pnu;
	- CLHEP::HepLorentzVector q2=-(p2in-p2out);
	-
	- jWbar(p1out,false,pe,false,pnu,false,p1in,false,mj1m);
	- joi(p2out,true,p2in,true,mj2p);
	- joi(p2out,false,p2in,false,mj2m);
	-
	- COM Mmp=cdot(mj1m,mj2p);
	-
	- // mj1m.mj2m
	- COM Mmm=cdot(mj1m,mj2m);
	-
	- // sum of spinor strings \|\|^2
	- double a2Mmp=abs2(Mmp);
	- double a2Mmm=abs2(Mmm);
	-
	- // Leave division by colour and Helicity avg until Tree files
	- // Leave multi. of couplings to later
	- // Multiply by Cf^2
	- return C_FC_F(a2Mmp+a2Mmm)/(q1.m2()*q2.m2());
	-
	-}
	-
	-double jMWqbarQbar (CLHEP::HepLorentzVector p1out, CLHEP::HepLorentzVector pe, CLHEP::HepLorentzVector pnu,CLHEP::HepLorentzVector p1in, CLHEP::HepLorentzVector p2out, CLHEP::HepLorentzVector p2in)
	-// Calculates the square of the current contractions for qQ->qenuQ scattering
	-// p1: quark (with W emittance)
	-// p2: Quark
	-{
	- current mj1m,mj2p,mj2m;
	- CLHEP::HepLorentzVector q1=p1in-p1out-pe-pnu;
	- CLHEP::HepLorentzVector q2=-(p2in-p2out);
	-
	- jWbar(p1out,false,pe,false,pnu,false,p1in,false,mj1m);
	- jio(p2in,true,p2out,true,mj2p);
	- jio(p2in,false,p2out,false,mj2m);
	-
	- COM Mmp=cdot(mj1m,mj2p);
	-
	- // mj1m.mj2m
	- COM Mmm=cdot(mj1m,mj2m);
	-
	- // sum of spinor strings \|\|^2
	- double a2Mmp=abs2(Mmp);
	- double a2Mmm=abs2(Mmm);
	-
	- // Leave division by colour and Helicity avg until Tree files
	- // Leave multi. of couplings to later
	- // Multiply by Cf^2
	- return C_FC_F(a2Mmp+a2Mmm)/(q1.m2()*q2.m2());
	-
	-}
	-
	-double jMWqg (CLHEP::HepLorentzVector p1out, CLHEP::HepLorentzVector pe, CLHEP::HepLorentzVector pnu,CLHEP::HepLorentzVector p1in, CLHEP::HepLorentzVector p2out, CLHEP::HepLorentzVector p2in)
	-// Calculates the square of the current contractions for qg->qenug scattering
	-// p1: quark
	-// p2: gluon
	-{
	- CLHEP::HepLorentzVector q1=p1in-p1out-pe-pnu;
	- CLHEP::HepLorentzVector q2=-(p2in-p2out);
	- current mj1m,mj2p,mj2m;
	-
	- jW(p1out,false,pe,false,pnu,false,p1in,false,mj1m);
	-
	- joi(p2out,true,p2in,true,mj2p);
	- joi(p2out,false,p2in,false,mj2m);
	-
	- // mj1m.mj2p
	- COM Mmp=cdot(mj1m,mj2p);
	-
	- // mj1m.mj2m
	- COM Mmm=cdot(mj1m,mj2m);
	-
	- const double K = K_g(p2out, p2in);
	-
	- // sum of spinor strings \|\|^2
	- double a2Mmp=abs2(Mmp);
	- double a2Mmm=abs2(Mmm);
	- double sst = K/C_A*(a2Mmp+a2Mmm);
	-
	- // Leave division by colour and Helicity avg until Tree files
	- // Leave multi. of couplings to later
	- // Multiply by Cf*Ca=4
	- return C_FC_Asst/(q1.m2()*q2.m2());
	-
	-}
	-
	-double jMWqbarg (CLHEP::HepLorentzVector p1out, CLHEP::HepLorentzVector pe, CLHEP::HepLorentzVector pnu,CLHEP::HepLorentzVector p1in, CLHEP::HepLorentzVector p2out, CLHEP::HepLorentzVector p2in)
	-// Calculates the square of the current contractions for qg->qenug scattering
	-// p1: quark
	-// p2: gluon
	-{
	- CLHEP::HepLorentzVector q1=p1in-p1out-pe-pnu;
	- CLHEP::HepLorentzVector q2=-(p2in-p2out);
	- current mj1m,mj2p,mj2m;
	-
	- jWbar(p1out,false,pe,false,pnu,false,p1in,false,mj1m);
	-
	- joi(p2out,true,p2in,true,mj2p);
	- joi(p2out,false,p2in,false,mj2m);
	-
	- // mj1m.mj2p
	- COM Mmp=cdot(mj1m,mj2p);
	-
	- // mj1m.mj2m
	- COM Mmm=cdot(mj1m,mj2m);
	-
	- const double K = K_g(p2out, p2in);
	-
	- // sum of spinor strings \|\|^2
	- double a2Mmp=abs2(Mmp);
	- double a2Mmm=abs2(Mmm);
	- double sst = K/C_A*(a2Mmp+a2Mmm);
	-
	-// // Leave division by colour and Helicity avg until Tree files
	- // Leave multi. of couplings to later
	- // Multiply by Cf*Ca=4
	- return C_FC_Asst/(q1.m2()*q2.m2());
	-
	-}
	-
	double jM2qQ (CLHEP::HepLorentzVector p1out, CLHEP::HepLorentzVector p1in, CLHEP::HepLorentzVector p2out, CLHEP::HepLorentzVector p2in)
	{
	// std::cerr<<"Current: "<<p1out<<" "<<p1in<<" "<<p2out<<" "<<p2in<<std::endl;

	CLHEP::HepLorentzVector q1=p1in-p1out;
	CLHEP::HepLorentzVector q2=-(p2in-p2out);
	// std::cerr<<"Current: "<<q1.m2()<<" "<<q2.m2()<<std::endl;
	current mj1m,mj1p,mj2m,mj2p;
	joi(p1out,true,p1in,true,mj1p);
	joi(p1out,false,p1in,false,mj1m);
	joi(p2out,true,p2in,true,mj2p);
	joi(p2out,false,p2in,false,mj2m);

	COM Mmp=cdot(mj1m,mj2p);
	COM Mmm=cdot(mj1m,mj2m);
	COM Mpp=cdot(mj1p,mj2p);
	COM Mpm=cdot(mj1p,mj2m);

	double sst=abs2(Mmm)+abs2(Mmp)+abs2(Mpp)+abs2(Mpm);

	// Multiply by Cf^2
	return HEJ::C_FHEJ::C_F(sst)/(q1.m2()*q2.m2());
	}

	double jM2qQbar (CLHEP::HepLorentzVector p1out, CLHEP::HepLorentzVector p1in, CLHEP::HepLorentzVector p2out, CLHEP::HepLorentzVector p2in)
	{
	CLHEP::HepLorentzVector q1=p1in-p1out;
	CLHEP::HepLorentzVector q2=-(p2in-p2out);
	current mj1m,mj1p,mj2m,mj2p;
	joi(p1out,true,p1in,true,mj1p);
	joi(p1out,false,p1in,false,mj1m);
	jio(p2in,true,p2out,true,mj2p);
	jio(p2in,false,p2out,false,mj2m);

	COM Mmp=cdot(mj1m,mj2p);
	COM Mmm=cdot(mj1m,mj2m);
	COM Mpp=cdot(mj1p,mj2p);
	COM Mpm=cdot(mj1p,mj2m);

	double sumsq=abs2(Mmm)+abs2(Mmp)+abs2(Mpp)+abs2(Mpm);

	// Multiply by Cf^2
	return C_FC_F(sumsq)/(q1.m2()*q2.m2());
	}

	double jM2qbarQbar (CLHEP::HepLorentzVector p1out, CLHEP::HepLorentzVector p1in, CLHEP::HepLorentzVector p2out, CLHEP::HepLorentzVector p2in)
	{
	CLHEP::HepLorentzVector q1=p1in-p1out;
	CLHEP::HepLorentzVector q2=-(p2in-p2out);
	current mj1m,mj1p,mj2m,mj2p;
	jio(p1in,true,p1out,true,mj1p);
	jio(p1in,false,p1out,false,mj1m);
	jio(p2in,true,p2out,true,mj2p);
	jio(p2in,false,p2out,false,mj2m);

	COM Mmp=cdot(mj1m,mj2p);
	COM Mmm=cdot(mj1m,mj2m);
	COM Mpp=cdot(mj1p,mj2p);
	COM Mpm=cdot(mj1p,mj2m);

	double sumsq=abs2(Mmm)+abs2(Mmp)+abs2(Mpp)+abs2(Mpm);

	// Multiply by Cf^2
	return C_FC_F(sumsq)/(q1.m2()*q2.m2());
	}

	double jM2qg (CLHEP::HepLorentzVector p1out, CLHEP::HepLorentzVector p1in, CLHEP::HepLorentzVector p2out, CLHEP::HepLorentzVector p2in)
	// Calculates the square of the current contractions for qg scattering
	// p1: quark
	// p2: gluon
	{
	CLHEP::HepLorentzVector q1=p1in-p1out;
	CLHEP::HepLorentzVector q2=-(p2in-p2out);

	current mj1m,mj1p,mj2m,mj2p;
	joi(p1out,true,p1in,true,mj1p);
	joi(p1out,false,p1in,false,mj1m);
	joi(p2out,true,p2in,true,mj2p);
	joi(p2out,false,p2in,false,mj2m);

	COM Mmp=cdot(mj1m,mj2p);
	COM Mmm=cdot(mj1m,mj2m);
	COM Mpp=cdot(mj1p,mj2p);
	COM Mpm=cdot(mj1p,mj2m);

	const double K = K_g(p2out, p2in);

	// sum of spinor strings \|\|^2
	double a2Mmp=abs2(Mmp);
	double a2Mmm=abs2(Mmm);
	double a2Mpp=abs2(Mpp);
	double a2Mpm=abs2(Mpm);
	double sst = K/C_A*(a2Mpp+a2Mpm+a2Mmp+a2Mmm);

	// Cf*Ca=4
	return C_FC_Asst/(q1.m2()*q2.m2());

	}

	double jM2qbarg (CLHEP::HepLorentzVector p1out, CLHEP::HepLorentzVector p1in, CLHEP::HepLorentzVector p2out, CLHEP::HepLorentzVector p2in)
	// Calculates the square of the current contractions for qg scattering
	// p1: quark
	// p2: gluon
	{
	CLHEP::HepLorentzVector q1=p1in-p1out;
	CLHEP::HepLorentzVector q2=-(p2in-p2out);

	current mj1m,mj1p,mj2m,mj2p;
	jio(p1in,true,p1out,true,mj1p);
	jio(p1in,false,p1out,false,mj1m);
	joi(p2out,true,p2in,true,mj2p);
	joi(p2out,false,p2in,false,mj2m);

	COM Mmp=cdot(mj1m,mj2p);
	COM Mmm=cdot(mj1m,mj2m);
	COM Mpp=cdot(mj1p,mj2p);
	COM Mpm=cdot(mj1p,mj2m);

	const double K = K_g(p2out, p2in);

	// sum of spinor strings \|\|^2
	double a2Mmp=abs2(Mmp);
	double a2Mmm=abs2(Mmm);
	double a2Mpp=abs2(Mpp);
	double a2Mpm=abs2(Mpm);
	double sst = K/C_A*(a2Mpp+a2Mpm+a2Mmp+a2Mmm);

	// Cf*Ca=4
	return C_FC_Asst/(q1.m2()*q2.m2());

	}

	double jM2gg (CLHEP::HepLorentzVector p1out, CLHEP::HepLorentzVector p1in, CLHEP::HepLorentzVector p2out, CLHEP::HepLorentzVector p2in)
	// Calculates the square of the current contractions for gg scattering
	// p1: gluon
	// p2: gluon
	{
	CLHEP::HepLorentzVector q1=p1in-p1out;
	CLHEP::HepLorentzVector q2=-(p2in-p2out);

	current mj1m,mj1p,mj2m,mj2p;
	joi(p1out,true,p1in,true,mj1p);
	joi(p1out,false,p1in,false,mj1m);
	joi(p2out,true,p2in,true,mj2p);
	joi(p2out,false,p2in,false,mj2m);

	COM Mmp=cdot(mj1m,mj2p);
	COM Mmm=cdot(mj1m,mj2m);
	COM Mpp=cdot(mj1p,mj2p);
	COM Mpm=cdot(mj1p,mj2m);

	const double K_g1 = K_g(p1out, p1in);
	const double K_g2 = K_g(p2out, p2in);

	// sum of spinor strings \|\|^2
	double a2Mmp=abs2(Mmp);
	double a2Mmm=abs2(Mmm);
	double a2Mpp=abs2(Mpp);
	double a2Mpm=abs2(Mpm);
	double sst = K_g1/C_AK_g2/C_A(a2Mpp+a2Mpm+a2Mmp+a2Mmm);
	// Ca*Ca=9
	return C_AC_Asst/(q1.m2()*q2.m2());
	}

	namespace {
	/**
	* @brief Higgs vertex contracted with current @param C1 and @param C2
	*/
	COM cHdot(const current & C1, const current & C2, const current & q1,
	const current & q2, double mt, bool incBot, double mb)
	{
	if (mt == infinity) {
	return (cdot(C1,C2)cdot(q1,q2)-cdot(C1,q2)cdot(C2,q1))/(6M_PIHEJ::vev);
	}
	else {
	CLHEP::HepLorentzVector vq1,vq2;
	vq1.set(q1[1].real(),q1[2].real(),q1[3].real(),q1[0].real());
	vq2.set(q2[1].real(),q2[2].real(),q2[3].real(),q2[0].real());
	// first minus sign obtained because of q1-difference to VDD
	// std::cout<<"A1 : " << A1(-vq1,vq2)<<std::endl;
	// std::cout<<"A2 : " << A2(-vq1,vq2)<<std::endl;
	if(!(incBot))
	// Factor is because 4 mt^2 g^2/HEJ::vev A1 -> 16 pi mt^2/HEJ::vev alphas,
	// and we divide by a factor 4 at the amp sqaured level later
	// which I absorb here (i.e. I divide by 2)
	/// @TODO move factor 1/2 from S to \|ME\|^2 => consistent with general notation
	return 8.M_PImtmt/HEJ::vev(-cdot(C1,q2)cdot(C2,q1)A1(-vq1,vq2,mt)-cdot(C1,C2)*A2(-vq1,vq2,mt));
	else
	return 8.M_PImtmt/HEJ::vev(-cdot(C1,q2)cdot(C2,q1)A1(-vq1,vq2,mt)-cdot(C1,C2)*A2(-vq1,vq2,mt))
	+ 8.M_PImbmb/HEJ::vev(-cdot(C1,q2)cdot(C2,q1)A1(-vq1,vq2,mb)-cdot(C1,C2)*A2(-vq1,vq2,mb));
	}
	}
	} // namespace anonymous

	double MH2qQ (CLHEP::HepLorentzVector p1out, CLHEP::HepLorentzVector p1in,
	CLHEP::HepLorentzVector p2out, CLHEP::HepLorentzVector p2in,
	CLHEP::HepLorentzVector q1, CLHEP::HepLorentzVector q2,
	double mt, bool incBot, double mb)
	{
	// CLHEP::HepLorentzVector q1=p1in-p1out;
	// CLHEP::HepLorentzVector q2=-(p2in-p2out);
	current j1p,j1m,j2p,j2m, q1v, q2v;

	joi (p1out,true,p1in,true,j1p);
	joi (p1out,false,p1in,false,j1m);

	joi (p2out,true,p2in,true,j2p);
	joi (p2out,false,p2in,false,j2m);

	to_current(q1, q1v);
	to_current(q2, q2v);

	COM Mmp=cHdot(j1m,j2p,q1v,q2v,mt, incBot, mb);
	COM Mmm=cHdot(j1m,j2m,q1v,q2v,mt, incBot, mb);
	COM Mpp=cHdot(j1p,j2p,q1v,q2v,mt, incBot, mb);
	COM Mpm=cHdot(j1p,j2m,q1v,q2v,mt, incBot, mb);

	double sst=abs2(Mmp)+abs2(Mmm)+abs2(Mpp)+abs2(Mpm);
	// return (4./3.)(4./3.)sst/((p1in-p1out).m2()(p2in-p2out).m2()q1.m2()*q2.m2());
	return sst/((p1in-p1out).m2()(p2in-p2out).m2()q1.m2()*q2.m2());
	}

	double MH2qQbar (CLHEP::HepLorentzVector p1out, CLHEP::HepLorentzVector p1in, CLHEP::HepLorentzVector p2out, CLHEP::HepLorentzVector p2in, CLHEP::HepLorentzVector q1, CLHEP::HepLorentzVector q2, double mt, bool incBot, double mb)
	{
	// CLHEP::HepLorentzVector q1=p1in-p1out;
	// CLHEP::HepLorentzVector q2=-(p2in-p2out);
	current j1p,j1m,j2p,j2m,q1v,q2v;

	joi (p1out,true,p1in,true,j1p);
	joi (p1out,false,p1in,false,j1m);

	jio (p2in,true,p2out,true,j2p);
	jio (p2in,false,p2out,false,j2m);

	to_current(q1, q1v);
	to_current(q2, q2v);

	COM Mmp=cHdot(j1m,j2p,q1v,q2v,mt, incBot, mb);
	COM Mmm=cHdot(j1m,j2m,q1v,q2v,mt, incBot, mb);
	COM Mpp=cHdot(j1p,j2p,q1v,q2v,mt, incBot, mb);
	COM Mpm=cHdot(j1p,j2m,q1v,q2v,mt, incBot, mb);

	double sst=abs2(Mmp)+abs2(Mmm)+abs2(Mpp)+abs2(Mpm);
	// return (4./3.)(4./3.)sst/((p1in-p1out).m2()(p2in-p2out).m2()q1.m2()*q2.m2());
	return sst/((p1in-p1out).m2()(p2in-p2out).m2()q1.m2()*q2.m2());
	}

	double MH2qbarQ (CLHEP::HepLorentzVector p1out, CLHEP::HepLorentzVector p1in, CLHEP::HepLorentzVector p2out, CLHEP::HepLorentzVector p2in, CLHEP::HepLorentzVector q1, CLHEP::HepLorentzVector q2, double mt, bool incBot, double mb)
	{
	// CLHEP::HepLorentzVector q1=p1in-p1out;
	// CLHEP::HepLorentzVector q2=-(p2in-p2out);
	current j1p,j1m,j2p,j2m,q1v,q2v;

	jio (p1in,true,p1out,true,j1p);
	jio (p1in,false,p1out,false,j1m);

	joi (p2out,true,p2in,true,j2p);
	joi (p2out,false,p2in,false,j2m);

	to_current(q1, q1v);
	to_current(q2, q2v);

	COM Mmp=cHdot(j1m,j2p,q1v,q2v,mt, incBot, mb);
	COM Mmm=cHdot(j1m,j2m,q1v,q2v,mt, incBot, mb);
	COM Mpp=cHdot(j1p,j2p,q1v,q2v,mt, incBot, mb);
	COM Mpm=cHdot(j1p,j2m,q1v,q2v,mt, incBot, mb);

	double sst=abs2(Mmp)+abs2(Mmm)+abs2(Mpp)+abs2(Mpm);
	// return (4./3.)(4./3.)sst/((p1in-p1out).m2()(p2in-p2out).m2()q1.m2()*q2.m2());
	return sst/((p1in-p1out).m2()(p2in-p2out).m2()q1.m2()*q2.m2());
	}

	double MH2qbarQbar (CLHEP::HepLorentzVector p1out, CLHEP::HepLorentzVector p1in, CLHEP::HepLorentzVector p2out, CLHEP::HepLorentzVector p2in, CLHEP::HepLorentzVector q1, CLHEP::HepLorentzVector q2, double mt, bool incBot, double mb)
	{
	// CLHEP::HepLorentzVector q1=p1in-p1out;
	// CLHEP::HepLorentzVector q2=-(p2in-p2out);
	current j1p,j1m,j2p,j2m,q1v,q2v;

	jio (p1in,true,p1out,true,j1p);
	jio (p1in,false,p1out,false,j1m);

	jio (p2in,true,p2out,true,j2p);
	jio (p2in,false,p2out,false,j2m);

	to_current(q1, q1v);
	to_current(q2, q2v);

	COM Mmp=cHdot(j1m,j2p,q1v,q2v,mt, incBot, mb);
	COM Mmm=cHdot(j1m,j2m,q1v,q2v,mt, incBot, mb);
	COM Mpp=cHdot(j1p,j2p,q1v,q2v,mt, incBot, mb);
	COM Mpm=cHdot(j1p,j2m,q1v,q2v,mt, incBot, mb);

	double sst=abs2(Mmp)+abs2(Mmm)+abs2(Mpp)+abs2(Mpm);
	// return (4./3.)(4./3.)sst/((p1in-p1out).m2()(p2in-p2out).m2()q1.m2()*q2.m2());
	return sst/((p1in-p1out).m2()(p2in-p2out).m2()q1.m2()*q2.m2());
	}

	double MH2qg (CLHEP::HepLorentzVector p1out, CLHEP::HepLorentzVector p1in, CLHEP::HepLorentzVector p2out, CLHEP::HepLorentzVector p2in, CLHEP::HepLorentzVector q1, CLHEP::HepLorentzVector q2, double mt, bool incBot, double mb)
	// q~p1 g~p2 (i.e. ALWAYS p1 for quark, p2 for gluon)
	// should be called with q1 meant to be contracted with p2 in first part of vertex
	// (i.e. if g is backward, q1 is forward)
	{
	current j1p,j1m,j2p,j2m,q1v,q2v;

	joi (p1out,true,p1in,true,j1p);
	joi (p1out,false,p1in,false,j1m);

	joi (p2out,true,p2in,true,j2p);
	joi (p2out,false,p2in,false,j2m);

	to_current(q1, q1v);
	to_current(q2, q2v);

	// First, calculate the non-flipping amplitudes:

	COM Mpp=cHdot(j1p,j2p,q1v,q2v,mt, incBot, mb);
	COM Mpm=cHdot(j1p,j2m,q1v,q2v,mt, incBot, mb);
	COM Mmp=cHdot(j1m,j2p,q1v,q2v,mt, incBot, mb);
	COM Mmm=cHdot(j1m,j2m,q1v,q2v,mt, incBot, mb);

	//cout << "Bits in MH2qg: " << Mpp << " " << Mpm << " " << Mmp << " " << Mmm << endl;

	const double K = K_g(p2out, p2in);

	double sst=K/C_A*(abs2(Mmp)+abs2(Mmm)+abs2(Mpp)+abs2(Mpm));

	// Cf*Ca=4
	// return 4.sst/((p1in-p1out).m2()(p2in-p2out).m2()q1.m2()q2.m2());
	return sst/((p1in-p1out).m2()(p2in-p2out).m2()q1.m2()*q2.m2());
	}

	double MH2qbarg (CLHEP::HepLorentzVector p1out, CLHEP::HepLorentzVector p1in, CLHEP::HepLorentzVector p2out, CLHEP::HepLorentzVector p2in, CLHEP::HepLorentzVector q1, CLHEP::HepLorentzVector q2, double mt, bool incBot, double mb)
	// qbar~p1 g~p2 (i.e. ALWAYS p1 for anti-quark, p2 for gluon)
	// should be called with q1 meant to be contracted with p2 in first part of vertex
	// (i.e. if g is backward, q1 is forward)
	{
	current j1p,j1m,j2p,j2m,q1v,q2v;

	jio (p1in,true,p1out,true,j1p);
	jio (p1in,false,p1out,false,j1m);

	joi (p2out,true,p2in,true,j2p);
	joi (p2out,false,p2in,false,j2m);

	to_current(q1, q1v);
	to_current(q2, q2v);

	// First, calculate the non-flipping amplitudes:

	COM amp,amm,apm,app;
	app=cHdot(j1p,j2p,q1v,q2v,mt, incBot, mb);
	apm=cHdot(j1p,j2m,q1v,q2v,mt, incBot, mb);
	amp=cHdot(j1m,j2p,q1v,q2v,mt, incBot, mb);
	amm=cHdot(j1m,j2m,q1v,q2v,mt, incBot, mb);

	double MH2sum = abs2(app)+abs2(amm)+abs2(apm)+abs2(amp);

	const double K = K_g(p2out, p2in);
	MH2sum*=K/C_A;

	// Cf*Ca=4
	// return 4.MH2sum/((p1in-p1out).m2()(p2in-p2out).m2()q1.m2()q2.m2());
	return MH2sum/((p1in-p1out).m2()(p2in-p2out).m2()q1.m2()*q2.m2());
	}

	double MH2gg (CLHEP::HepLorentzVector p1out, CLHEP::HepLorentzVector p1in, CLHEP::HepLorentzVector p2out, CLHEP::HepLorentzVector p2in, CLHEP::HepLorentzVector q1, CLHEP::HepLorentzVector q2, double mt, bool incBot, double mb)
	// g~p1 g~p2
	// should be called with q1 meant to be contracted with p2 in first part of vertex
	// (i.e. if g is backward, q1 is forward)
	{
	current j1p,j1m,j2p,j2m,q1v,q2v;

	joi (p1out,true,p1in,true,j1p);
	joi (p1out,false,p1in,false,j1m);

	joi (p2out,true,p2in,true,j2p);
	joi (p2out,false,p2in,false,j2m);

	to_current(q1, q1v);
	to_current(q2, q2v);

	// First, calculate the non-flipping amplitudes:

	COM amp,amm,apm,app;
	app=cHdot(j1p,j2p,q1v,q2v,mt, incBot, mb);
	apm=cHdot(j1p,j2m,q1v,q2v,mt, incBot, mb);
	amp=cHdot(j1m,j2p,q1v,q2v,mt, incBot, mb);
	amm=cHdot(j1m,j2m,q1v,q2v,mt, incBot, mb);

	double MH2sum = abs2(app)+abs2(amm)+abs2(apm)+abs2(amp);

	const double K_g1 = K_g(p1out, p1in);
	const double K_g2 = K_g(p2out, p2in);

	MH2sum=K_g1/C_AK_g2/C_A;

	// Ca*Ca=9
	// return 9.MH2sum/((p1in-p1out).m2()(p2in-p2out).m2()q1.m2()q2.m2());
	return MH2sum/((p1in-p1out).m2()(p2in-p2out).m2()q1.m2()*q2.m2());
	}

	// // Z's stuff
	// void jZ(HLV pin, HLV pout, HLV pem, HLV pep, bool HelPartons, bool HelLeptons, current cur) {

	// // Init current to zero
	// cur[0] = 0.0;
	// cur[1] = 0.0;
	// cur[2] = 0.0;
	// cur[3] = 0.0;

	// // Temporary variables
	// COM temp;
	// current Term_1, Term_2, Term_3, Term_4, J_temp, TempCur1, TempCur2;

	// // Momentum of virtual gluons aroun weak boson emission site
	// HLV qa = pout + pep + pem;
	// HLV qb = pin - pep - pem;

	// double ta = qa.m2();
	// double tb = qb.m2();

	// // Out-Out currents:
	// current Em_Ep, Out_Em, Out_Ep;

	// // Other currents:
	// current Out_In, Em_In, Ep_In;

	// joi(pout, HelPartons, pin, HelPartons, Out_In);
	// joi(pem, HelLeptons, pin, HelPartons, Em_In);
	// joi(pep, HelLeptons, pin, HelPartons, Ep_In);

	// joo(pem, HelLeptons, pep, HelLeptons, Em_Ep);
	// joo(pout, HelPartons, pem, HelLeptons, Out_Em);
	// joo(pout, HelPartons, pep, HelLeptons, Out_Ep);

	// if (HelLeptons == HelPartons) {

	// temp = 2.0 * cdot(pout, Em_Ep);
	// cmult(temp / ta, Out_In, Term_1);

	// temp = cdot(Out_Em, Em_Ep);
	// cmult(temp / ta , Em_In, Term_2);

	// temp = 2.0 * cdot(pin, Em_Ep);
	// cmult(temp / tb, Out_In, Term_3);

	// temp = -cdot(Ep_In, Em_Ep);
	// cmult(temp / tb, Out_Ep, Term_4);

	// cadd(Term_1, Term_2, Term_3, Term_4, J_temp);

	// cur[0] = J_temp[0];
	// cur[1] = J_temp[1];
	// cur[2] = J_temp[2];
	// cur[3] = J_temp[3];
	// }

	// else {
	// if (HelPartons == true) {
	// temp = 2.0 * cdot(pout, Em_Ep);
	// cmult(temp / ta, Out_In, Term_1);

	// joo(pout, true, pep, true, TempCur1);
	// joi(pep, true, pin, true, TempCur2);

	// temp = cdot(TempCur1, Em_Ep);
	// cmult(temp / ta , TempCur2, Term_2);

	// temp = 2.0 * cdot(pin, Em_Ep);
	// cmult(temp / tb, Out_In, Term_3);

	// joo(pout, true, pem, true, TempCur1);
	// joi(pem, true, pin, true, TempCur2);

	// temp = -cdot(TempCur2, Em_Ep);
	// cmult(temp / tb, TempCur1, Term_4);

	// cadd(Term_1, Term_2, Term_3, Term_4, J_temp);

	// cur[0] = J_temp[0];
	// cur[1] = J_temp[1];
	// cur[2] = J_temp[2];
	// cur[3] = J_temp[3];
	// }

	// else {
	// temp = 2.0 * cdot(pout, Em_Ep);
	// cmult(temp / ta, Out_In, Term_1);

	// joo(pout, false, pep, false, TempCur1);
	// joi(pep, false, pin, false, TempCur2);

	// temp = cdot(TempCur1, Em_Ep);
	// cmult(temp / ta, TempCur2, Term_2);

	// temp = 2.0 * cdot(pin, Em_Ep);
	// cmult(temp / tb, Out_In, Term_3);

	// joo(pout, false, pem, false, TempCur1);
	// joi(pem, false, pin, false, TempCur2);

	// temp = -cdot(TempCur2, Em_Ep);
	// cmult(temp / tb, TempCur1, Term_4);

	// cadd(Term_1, Term_2, Term_3, Term_4, J_temp);

	// cur[0] = J_temp[0];
	// cur[1] = J_temp[1];
	// cur[2] = J_temp[2];
	// cur[3] = J_temp[3];
	// }

	// }
	// }

	// void jZbar(HLV pin, HLV pout, HLV pem, HLV pep, bool HelPartons, bool HelLeptons, current cur) {

	// // Init current to zero
	// cur[0] = 0.0;
	// cur[1] = 0.0;
	// cur[2] = 0.0;
	// cur[3] = 0.0;

	// // Temporary variables
	// COM temp;
	// current Term_1, Term_2, Term_3, Term_4, J_temp, TempCur1, TempCur2;

	// // Transfered 4-momenta
	// HLV qa = pout + pep + pem;
	// HLV qb = pin - pep - pem;

	// // The square of the transfered 4-momenta
	// double ta = qa.m2();
	// double tb = qb.m2();

	// // Out-Out currents:
	// current Em_Ep, Em_Out, Ep_Out;

	// // In-Out currents:
	// current In_Out, In_Em, In_Ep;

	// // Safe to use the currents since helicity structure is ok
	// if (HelPartons == HelLeptons) {
	// jio(pin, HelPartons, pout, HelPartons, In_Out);
	// joo(pem, HelLeptons, pep, HelLeptons, Em_Ep);
	// jio(pin, HelPartons, pem, HelLeptons, In_Em);
	// jio(pin, HelPartons, pep, HelLeptons, In_Ep);
	// joo(pem, HelLeptons, pout, HelPartons, Em_Out);
	// joo(pep, HelLeptons, pout, HelPartons, Ep_Out);
	// }

	// else {
	// jio(pin, HelPartons, pout, HelPartons, In_Out);
	// joo(pem, HelLeptons, pep, HelLeptons, Em_Ep);

	// In_Em[0] = 0.0;
	// In_Em[1] = 0.0;
	// In_Em[2] = 0.0;
	// In_Em[3] = 0.0;

	// In_Ep[0] = 0.0;
	// In_Ep[1] = 0.0;
	// In_Ep[2] = 0.0;
	// In_Ep[3] = 0.0;

	// Em_Out[0] = 0.0;
	// Em_Out[1] = 0.0;
	// Em_Out[2] = 0.0;
	// Em_Out[3] = 0.0;

	// Ep_Out[0] = 0.0;
	// Ep_Out[1] = 0.0;
	// Ep_Out[2] = 0.0;
	// Ep_Out[3] = 0.0;
	// }

	// if (HelLeptons == HelPartons) {

	// temp = 2.0 * cdot(pout, Em_Ep);
	// cmult(temp / ta, In_Out, Term_1);

	// temp = cdot(Ep_Out, Em_Ep);
	// cmult(temp / ta, In_Ep, Term_2);

	// temp = 2.0 * cdot(pin, Em_Ep);
	// cmult(temp / tb, In_Out, Term_3);

	// temp = - cdot(In_Em, Em_Ep);
	// cmult(temp / tb, Em_Out, Term_4);

	// cadd(Term_1, Term_2, Term_3, Term_4, J_temp);

	// cur[0] = J_temp[0];
	// cur[1] = J_temp[1];
	// cur[2] = J_temp[2];
	// cur[3] = J_temp[3];
	// }

	// else {
	// if (HelPartons == true) {

	// temp = 2.0 * cdot(pout, Em_Ep);
	// cmult(temp / ta, In_Out, Term_1);

	// joo(pem, true, pout, true, TempCur1);
	// jio(pin, true, pem, true, TempCur2);

	// temp = cdot(TempCur1, Em_Ep);
	// cmult(temp / ta , TempCur2, Term_2);

	// temp = 2.0 * cdot(pin, Em_Ep);
	// cmult(temp / tb, In_Out, Term_3);

	// joo(pep, true, pout, true, TempCur1);
	// jio(pin, true, pep, true, TempCur2);

	// temp = - cdot(TempCur2, Em_Ep);
	// cmult(temp / tb, TempCur1, Term_4);

	// cadd(Term_1, Term_2, Term_3, Term_4, J_temp);

	// cur[0] = J_temp[0];
	// cur[1] = J_temp[1];
	// cur[2] = J_temp[2];
	// cur[3] = J_temp[3];
	// }

	// else {

	// temp = 2.0 * cdot(pout, Em_Ep);
	// cmult(temp / ta, In_Out, Term_1);

	// joo(pem, false, pout, false, TempCur1);
	// jio(pin, false, pem, false, TempCur2);

	// temp = cdot(TempCur1, Em_Ep);
	// cmult(temp / ta , TempCur2, Term_2);

	// temp = 2.0 * cdot(pin, Em_Ep);
	// cmult(temp / tb, In_Out, Term_3);

	// joo(pep, false, pout, false, TempCur1);
	// jio(pin, false, pep, false, TempCur2);

	// temp = - cdot(TempCur2, Em_Ep);
	// cmult(temp / tb, TempCur1, Term_4);

	// cadd(Term_1, Term_2, Term_3, Term_4, J_temp);

	// cur[0] = J_temp[0];
	// cur[1] = J_temp[1];
	// cur[2] = J_temp[2];
	// cur[3] = J_temp[3];
	// }
	// }
	// }

	// // Progagators
	// COM PZ(double s) {

	// double MZ, GammaZ;

	// MZ = 9.118800e+01; // Mass of the mediating gauge boson
	// GammaZ = 2.441404e+00; // Z peak width

	// // Return Z Prop value
	// return 1.0 / (s - MZ * MZ + COM(0.0, 1.0) * GammaZ * MZ);
	// }

	// COM PG(double s) {
	// return 1.0 / s;
	// }

	// // Non-gluonic with pa emitting
	// std::vector <double> jMZqQ (HLV pa, HLV pb, HLV p1, HLV p2, HLV pep, HLV pem, std::vector <double> VProducts, std::vector < std::vector <double> > Virtuals, int aptype, int bptype, bool UseVirtuals, bool BottomLineEmit) {

	// std::vector <double> ScaledWeights;

	// double Sum;

	// // Propagator factors
	// COM PZs = PZ((pep + pem).m2());
	// COM PGs = PG((pep + pem).m2());


	// // Emitting current initialisation
	// current j1pptop, j1pmtop; // Emission from top line
	// current j1ppbot, j1pmbot; // Emission from bottom line

	// // Non-emitting current initialisation
	// current j2ptop, j2mtop; // Emission from top line
	// current j2pbot, j2mbot; // Emission from bottom line

	// // Currents for top emission
	// // Upper current calculations
	// // if a is a quark
	// if (aptype > 0) {
	// jZ(pa, p1, pem, pep, true, true, j1pptop);
	// jZ(pa, p1, pem, pep, true, false, j1pmtop);
	// }
	// // if a is an antiquark
	// else {
	// jZbar(pa, p1, pem, pep, true, true, j1pptop);
	// jZbar(pa, p1, pem, pep, true, false, j1pmtop);
	// }

	// // Lower current calculations
	// // if b is a quark
	// if (bptype > 0) {
	// joi(p2, true, pb, true, j2ptop);
	// joi(p2, false, pb, false, j2mtop);
	// }
	// // if b is an antiquark
	// else {
	// jio(pb, true, p2, true, j2ptop);
	// jio(pb, false, p2, false, j2mtop);
	// }

	// // Currents for bottom emission
	// // Lower current calculations
	// if (bptype > 0) {
	// jZ(pb, p2, pem, pep, true, true, j1ppbot);
	// jZ(pb, p2, pem, pep, true, false, j1pmbot);
	// }
	// else {
	// jZbar(pb, p2, pem, pep, true, true, j1ppbot);
	// jZbar(pb, p2, pem, pep, true, false, j1pmbot);
	// }

	// // Upper current calculations
	// if (aptype > 0) {
	// joi(p1, true, pa, true, j2pbot);
	// joi(p1, false, pa, false, j2mbot);
	// }
	// else {
	// jio(pa, true, p1, true, j2pbot);
	// jio(pa, false, p1, false, j2mbot);
	// }

	// COM Coeff[2][8];

	// if (!Interference) {

	// double ZCharge_a_P = Zq(aptype, true);
	// double ZCharge_a_M = Zq(aptype, false);
	// double ZCharge_b_P = Zq(bptype, true);
	// double ZCharge_b_M = Zq(bptype, false);

	// if (BottomLineEmit) {
	// // Emission from top-line quark (pa/p1 line)
	// Coeff[0][0] = (ZCharge_a_P * Zep * PZs * RWeak + Gq(aptype) * PGs) * cdot(j1pptop, j2ptop);
	// Coeff[0][1] = (ZCharge_a_P * Zep * PZs * RWeak + Gq(aptype) * PGs) * cdot(j1pptop, j2mtop);
	// Coeff[0][2] = (ZCharge_a_P * Zem * PZs * RWeak + Gq(aptype) * PGs) * cdot(j1pmtop, j2ptop);
	// Coeff[0][3] = (ZCharge_a_P * Zem * PZs * RWeak + Gq(aptype) * PGs) * cdot(j1pmtop, j2mtop);
	// Coeff[0][4] = (ZCharge_a_M * Zem * PZs * RWeak + Gq(aptype) * PGs) * conj(cdot(j1pptop, j2ptop));
	// Coeff[0][5] = (ZCharge_a_M * Zem * PZs * RWeak + Gq(aptype) * PGs) * conj(cdot(j1pptop, j2mtop));
	// Coeff[0][6] = (ZCharge_a_M * Zep * PZs * RWeak + Gq(aptype) * PGs) * conj(cdot(j1pmtop, j2ptop));
	// Coeff[0][7] = (ZCharge_a_M * Zep * PZs * RWeak + Gq(aptype) * PGs) * conj(cdot(j1pmtop, j2mtop));
	// }

	// else {
	// // Emission from bottom-line quark (pb/p2 line)
	// Coeff[1][0] = (ZCharge_b_P * Zep * PZs * RWeak + Gq(bptype) * PGs) * cdot(j1ppbot, j2pbot);
	// Coeff[1][7] = (ZCharge_b_P * Zep * PZs * RWeak + Gq(bptype) * PGs) * cdot(j1ppbot, j2mbot);
	// Coeff[1][2] = (ZCharge_b_P * Zem * PZs * RWeak + Gq(bptype) * PGs) * cdot(j1pmbot, j2pbot);
	// Coeff[1][5] = (ZCharge_b_P * Zem * PZs * RWeak + Gq(bptype) * PGs) * cdot(j1pmbot, j2mbot);
	// Coeff[1][4] = (ZCharge_b_M * Zem * PZs * RWeak + Gq(bptype) * PGs) * conj(cdot(j1ppbot, j2pbot));
	// Coeff[1][3] = (ZCharge_b_M * Zem * PZs * RWeak + Gq(bptype) * PGs) * conj(cdot(j1ppbot, j2mbot));
	// Coeff[1][6] = (ZCharge_b_M * Zep * PZs * RWeak + Gq(bptype) * PGs) * conj(cdot(j1pmbot, j2pbot));
	// Coeff[1][1] = (ZCharge_b_M * Zep * PZs * RWeak + Gq(bptype) * PGs) * conj(cdot(j1pmbot, j2mbot));
	// }
	// }

	// // Else calculate all the possiblities
	// else {

	// double ZCharge_a_P = Zq(aptype, true);
	// double ZCharge_a_M = Zq(aptype, false);
	// double ZCharge_b_P = Zq(bptype, true);
	// double ZCharge_b_M = Zq(bptype, false);

	// // Emission from top-line quark (pa/p1 line)
	// Coeff[0][0] = (ZCharge_a_P * Zep * PZs * RWeak + Gq(aptype) * PGs) * cdot(j1pptop, j2ptop);
	// Coeff[0][1] = (ZCharge_a_P * Zep * PZs * RWeak + Gq(aptype) * PGs) * cdot(j1pptop, j2mtop);
	// Coeff[0][2] = (ZCharge_a_P * Zem * PZs * RWeak + Gq(aptype) * PGs) * cdot(j1pmtop, j2ptop);
	// Coeff[0][3] = (ZCharge_a_P * Zem * PZs * RWeak + Gq(aptype) * PGs) * cdot(j1pmtop, j2mtop);
	// Coeff[0][4] = (ZCharge_a_M * Zem * PZs * RWeak + Gq(aptype) * PGs) * conj(cdot(j1pptop, j2ptop));
	// Coeff[0][5] = (ZCharge_a_M * Zem * PZs * RWeak + Gq(aptype) * PGs) * conj(cdot(j1pptop, j2mtop));
	// Coeff[0][6] = (ZCharge_a_M * Zep * PZs * RWeak + Gq(aptype) * PGs) * conj(cdot(j1pmtop, j2ptop));
	// Coeff[0][7] = (ZCharge_a_M * Zep * PZs * RWeak + Gq(aptype) * PGs) * conj(cdot(j1pmtop, j2mtop));

	// // Emission from bottom-line quark (pb/p2 line)
	// Coeff[1][0] = (ZCharge_b_P * Zep * PZs * RWeak + Gq(bptype) * PGs) * cdot(j1ppbot, j2pbot);
	// Coeff[1][7] = (ZCharge_b_P * Zep * PZs * RWeak + Gq(bptype) * PGs) * cdot(j1ppbot, j2mbot);
	// Coeff[1][2] = (ZCharge_b_P * Zem * PZs * RWeak + Gq(bptype) * PGs) * cdot(j1pmbot, j2pbot);
	// Coeff[1][5] = (ZCharge_b_P * Zem * PZs * RWeak + Gq(bptype) * PGs) * cdot(j1pmbot, j2mbot);
	// Coeff[1][4] = (ZCharge_b_M * Zem * PZs * RWeak + Gq(bptype) * PGs) * conj(cdot(j1ppbot, j2pbot));
	// Coeff[1][3] = (ZCharge_b_M * Zem * PZs * RWeak + Gq(bptype) * PGs) * conj(cdot(j1ppbot, j2mbot));
	// Coeff[1][6] = (ZCharge_b_M * Zep * PZs * RWeak + Gq(bptype) * PGs) * conj(cdot(j1pmbot, j2pbot));
	// Coeff[1][1] = (ZCharge_b_M * Zep * PZs * RWeak + Gq(bptype) * PGs) * conj(cdot(j1pmbot, j2mbot));
	// }

	// // Find the numbers of scales
	// int ScaleCount;
	// #if calcscaleunc
	// ScaleCount = 20;
	// #else
	// ScaleCount = 1;
	// #endif

	// // For each scale...
	// for (int j = 0; j < ScaleCount; j++) {

	// Sum = 0.0;

	// // If we want to compare back to the W's code only emit from one quark and only couple to left handed particles
	// // virtuals arent here since they are calculated and included in weight() call.
	// if (!Interference) {

	// if (BottomLineEmit) for (int i = 0; i < 8; i++) Sum += abs2(Coeff[1][i]) * VProducts.at(1);
	// else for (int i = 0; i < 8; i++) Sum += abs2(Coeff[0][i]) * VProducts.at(0);
	// }

	// // Else work out the full interference
	// else {

	// // For the full calculation...
	// if (UseVirtuals) {
	// for (int i = 0; i < 8; i++) {
	// Sum += abs2(Coeff[0][i]) * VProducts.at(0) * Virtuals.at(j).at(0)
	// + abs2(Coeff[1][i]) * VProducts.at(1) * Virtuals.at(j).at(1)
	// + 2.0 * real(Coeff[0][i] * conj(Coeff[1][i])) * VProducts.at(2) * Virtuals.at(j).at(2);
	// }
	// }

	// // For the tree level calculation...
	// else {
	// for (int i = 0; i < 8; i++) {
	// Sum += abs2(Coeff[0][i]) * VProducts.at(0)
	// + abs2(Coeff[1][i]) * VProducts.at(1)
	// + 2.0 * real(Coeff[0][i] * conj(Coeff[1][i])) * VProducts.at(2);
	// }
	// }
	// }

	// // Add this to the vector to be returned with the other factors of C_A and the helicity sum/average factors.
	// ScaledWeights.push_back(Sum / 18.0);
	// }

	// // Return all the scale values
	// return ScaledWeights;
	// }

	// // Semi-gluonic with pa emitting
	// std::vector <double> jMZqg (HLV pa, HLV pb, HLV p1, HLV p2, HLV pep, HLV pem, std::vector <double> VProducts, std::vector < std::vector <double> > Virtuals, int aptype, int bptype, bool UseVirtuals, bool BottomLineEmit) {

	// COM Coeff[8];

	// double Sum;

	// std::vector <double> ScaledWeights;

	// COM PZs = PZ((pep + pem).m2());
	// COM PGs = PG((pep + pem).m2());

	// // Emitting current initialisation - Emission from top line
	// current j1pptop, j1pmtop;

	// // Non-emitting current initialisation - Emission from top line
	// current j2ptop, j2mtop;

	// // Currents for top emission
	// // Upper current calculations
	// if (aptype > 0) {
	// jZ (pa, p1, pem, pep, true, true, j1pptop);
	// jZ (pa, p1, pem, pep, true, false, j1pmtop);
	// }
	// else {
	// jZbar(pa, p1, pem, pep, true, true, j1pptop);
	// jZbar(pa, p1, pem, pep, true, false, j1pmtop);
	// }

	// // Lower current calculations
	// joi(p2, true, pb, true, j2ptop);
	// joi(p2, false, pb, false, j2mtop);

	// // Calculate all the possiblities
	// double ZCharge_a_P = Zq(aptype, true);
	// double ZCharge_a_M = Zq(aptype, false);

	// // Emission from top-line quark (pa/p1 line)
	// Coeff[0] = (ZCharge_a_P * Zep * PZs * RWeak + Gq(aptype) * PGs) * cdot(j1pptop, j2ptop);
	// Coeff[1] = (ZCharge_a_P * Zep * PZs * RWeak + Gq(aptype) * PGs) * cdot(j1pptop, j2mtop);
	// Coeff[2] = (ZCharge_a_P * Zem * PZs * RWeak + Gq(aptype) * PGs) * cdot(j1pmtop, j2ptop);
	// Coeff[3] = (ZCharge_a_P * Zem * PZs * RWeak + Gq(aptype) * PGs) * cdot(j1pmtop, j2mtop);
	// Coeff[4] = (ZCharge_a_M * Zem * PZs * RWeak + Gq(aptype) * PGs) * conj(cdot(j1pptop, j2ptop));
	// Coeff[5] = (ZCharge_a_M * Zem * PZs * RWeak + Gq(aptype) * PGs) * conj(cdot(j1pptop, j2mtop));
	// Coeff[6] = (ZCharge_a_M * Zep * PZs * RWeak + Gq(aptype) * PGs) * conj(cdot(j1pmtop, j2ptop));
	// Coeff[7] = (ZCharge_a_M * Zep * PZs * RWeak + Gq(aptype) * PGs) * conj(cdot(j1pmtop, j2mtop));

	// // Calculate gluon colour accelerated factor
	// double CAMFactor, z;

	// // If b is a forward moving gluon define z (C.F. multiple jets papers)
	// if (pb.pz() > 0) z = p2.plus() / pb.plus();
	// else z = p2.minus() / pb.minus();

	// CAMFactor = (1.0 - 1.0 / 9.0) / 2.0 * (z + 1.0 / z) + 1.0 / 9.0;

	// // Find the numbers of scales
	// int ScaleCount;
	// #if calcscaleunc
	// ScaleCount = 20;
	// #else
	// ScaleCount = 1;
	// #endif

	// // For each scale...
	// for (int j = 0; j < ScaleCount; j++) {

	// Sum = 0.0;

	// // If we dont want the interference
	// if (!Interference) for (int i = 0; i < 8; i++) Sum += abs2(Coeff[i]) * VProducts.at(0);

	// // Else work out the full interference
	// else {
	// if (UseVirtuals) {
	// for (int i = 0; i < 8; i++) Sum += abs2(Coeff[i]) * VProducts.at(0) * Virtuals.at(j).at(0);
	// }
	// else {
	// for (int i = 0; i < 8; i++) Sum += abs2(Coeff[i]) * VProducts.at(0);
	// }
	// }

	// // Add this to the vector to be returned with the other factors of C_A, the colour accelerated factor and the helicity sum/average factors.: (4/3)*3/32
	// ScaledWeights.push_back(CAMFactor * Sum / 8.0);
	// }

	// return ScaledWeights;
	// }

	// // Electroweak Charge Functions
	// double Zq (int PID, bool Helcitiy) {

	// double temp;

	// // Positive Spin
	// if (Helcitiy == true) {
	// if (PID == 1 \|\| PID == 3 \|\| PID == 5) temp = (+ 1.0 * stw2 / 3.0) / ctw;
	// if (PID == 2 \|\| PID == 4) temp = (- 2.0 * stw2 / 3.0) / ctw;
	// if (PID == -1 \|\| PID == -3 \|\| PID == -5) temp = (- 1.0 * stw2 / 3.0) / ctw;
	// if (PID == -2 \|\| PID == -4) temp = (+ 2.0 * stw2 / 3.0) / ctw;

	// // If electron or positron
	// if (PID == 7 \|\| PID == -7) temp = Zep;
	// }

	// // Negative Spin
	// else {
	// if (PID == 1 \|\| PID == 3 \|\| PID == 5) temp = (-0.5 + 1.0 * stw2 / 3.0) / ctw;
	// if (PID == 2 \|\| PID == 4) temp = ( 0.5 - 2.0 * stw2 / 3.0) / ctw;
	// if (PID == -1 \|\| PID == -3 \|\| PID == -5) temp = ( 0.5 - 1.0 * stw2 / 3.0) / ctw;
	// if (PID == -2 \|\| PID == -4) temp = (-0.5 + 2.0 * stw2 / 3.0) / ctw;

	// // If electron or positron
	// if (PID == 7 \|\| PID == -7) temp = Zem;

	// }

	// return temp;
	// }

	// double Gq (int PID) {

	// if (!VirtualPhoton) return 0.0;

	// if (PID == -1) return 1.0 * ee / 3.0;
	// if (PID == -2) return -2.0 * ee / 3.0;
	// if (PID == -3) return 1.0 * ee / 3.0;
	// if (PID == -4) return -2.0 * ee / 3.0;
	// if (PID == -5) return 1.0 * ee / 3.0;
	// if (PID == 1) return -1.0 * ee / 3.0;
	// if (PID == 2) return 2.0 * ee / 3.0;
	// if (PID == 3) return -1.0 * ee / 3.0;
	// if (PID == 4) return 2.0 * ee / 3.0;
	// if (PID == 5) return -1.0 * ee / 3.0;

	// std::cout << "ERROR! No Electroweak Charge Found at line " << __LINE__ << "..." << std::endl;
	// return 0.0;
	// }


	namespace {

	//@{
	/// @brief Higgs vertex contracted with one current

	CCurrent jH (CLHEP::HepLorentzVector pout, bool helout, CLHEP::HepLorentzVector pin,
	bool helin, CLHEP::HepLorentzVector q1, CLHEP::HepLorentzVector q2,
	double mt, bool incBot, double mb)
	{

	CCurrent j2 = joi(pout,helout,pin,helin);
	CCurrent jq2(q2.e(),q2.px(),q2.py(),q2.pz());

	if(mt == infinity)
	return ((q1.dot(q2))j2 - j2.dot(q1)jq2)/(3M_PIHEJ::vev);
	else
	{
	if(incBot)
	return (-16.M_PImbmb/HEJ::vevj2.dot(q1)jq2A1(-q1,q2,mb)-16.M_PImbmb/HEJ::vevj2*A2(-q1,q2,mb))
	+ (-16.M_PImtmt/HEJ::vevj2.dot(q1)jq2A1(-q1,q2,mt)-16.M_PImtmt/HEJ::vevj2*A2(-q1,q2,mt));
	else
	return (-16.M_PImtmt/HEJ::vevj2.dot(q1)jq2A1(-q1,q2,mt)-16.M_PImtmt/HEJ::vevj2*A2(-q1,q2,mt));
	}
	}

	CCurrent jioH (CLHEP::HepLorentzVector pin, bool helin, CLHEP::HepLorentzVector pout,
	bool helout, CLHEP::HepLorentzVector q1, CLHEP::HepLorentzVector q2,
	double mt, bool incBot, double mb)
	{

	CCurrent j2 = jio(pin,helin,pout,helout);
	CCurrent jq2(q2.e(),q2.px(),q2.py(),q2.pz());

	if(mt == infinity)
	return ((q1.dot(q2))j2 - j2.dot(q1)jq2)/(3M_PIHEJ::vev);
	else
	{
	if(incBot)
	return (-16.M_PImbmb/HEJ::vevj2.dot(q1)jq2A1(-q1,q2,mb)-16.M_PImbmb/HEJ::vevj2*A2(-q1,q2,mb))
	+ (-16.M_PImtmt/HEJ::vevj2.dot(q1)jq2A1(-q1,q2,mt)-16.M_PImtmt/HEJ::vevj2*A2(-q1,q2,mt));
	else
	return (-16.M_PImtmt/HEJ::vevj2.dot(q1)jq2A1(-q1,q2,mt)-16.M_PImtmt/HEJ::vevj2*A2(-q1,q2,mt));
	}
	}

	CCurrent jHtop (CLHEP::HepLorentzVector pout, bool helout, CLHEP::HepLorentzVector pin,
	bool helin, CLHEP::HepLorentzVector q1, CLHEP::HepLorentzVector q2,
	double mt, bool incBot, double mb)
	{

	CCurrent j1 = joi(pout,helout,pin,helin);
	CCurrent jq1(q1.e(),q1.px(),q1.py(),q1.pz());

	if(mt == infinity)
	return ((q1.dot(q2))j1 - j1.dot(q2)jq1)/(3M_PIHEJ::vev);
	else
	{
	if(incBot)
	return (-16.M_PImbmb/HEJ::vevj1.dot(q2)jq1A1(-q1,q2,mb)-16.M_PImbmb/HEJ::vevj1*A2(-q1,q2,mb))
	+ (-16.M_PImtmt/HEJ::vevj1.dot(q2)jq1A1(-q1,q2,mt)-16.M_PImtmt/HEJ::vevj1*A2(-q1,q2,mt));
	else
	return (-16.M_PImtmt/HEJ::vevj1.dot(q2)jq1A1(-q1,q2,mt)-16.M_PImtmt/HEJ::vevj1*A2(-q1,q2,mt));
	}
	}


	CCurrent jioHtop (CLHEP::HepLorentzVector pin, bool helin, CLHEP::HepLorentzVector pout,
	bool helout, CLHEP::HepLorentzVector q1, CLHEP::HepLorentzVector q2,
	double mt, bool incBot, double mb)
	{

	CCurrent j1 = jio(pin,helin,pout,helout);
	CCurrent jq1(q1.e(),q1.px(),q1.py(),q1.pz());

	if(mt == infinity)
	return ((q1.dot(q2))j1 - j1.dot(q2)jq1)/(3M_PIHEJ::vev);
	else
	{
	if(incBot)
	return (-16.M_PImbmb/HEJ::vevj1.dot(q2)jq1A1(-q1,q2,mb)-16.M_PImbmb/HEJ::vevj1*A2(-q1,q2,mb))
	+ (-16.M_PImtmt/HEJ::vevj1.dot(q2)jq1A1(-q1,q2,mt)-16.M_PImtmt/HEJ::vevj1*A2(-q1,q2,mt));
	else
	return (-16.M_PImtmt/HEJ::vevj1.dot(q2)jq1A1(-q1,q2,mt)-16.M_PImtmt/HEJ::vevj1*A2(-q1,q2,mt));
	}
	}
	//@}
	} // namespace anonymous

	double jM2unogqHQ (CLHEP::HepLorentzVector pg, CLHEP::HepLorentzVector p1out, CLHEP::HepLorentzVector p1in, CLHEP::HepLorentzVector p2out, CLHEP::HepLorentzVector p2in, CLHEP::HepLorentzVector qH1, CLHEP::HepLorentzVector qH2, double mt, bool incBot, double mb)
	{
	// This construction is taking rapidity order: pg > p1out >> p2out
	// std::cerr<<"This Uno Current: "<<p1out<<" "<<p1in<<" "<<p2out<<" "<<p2in<<" "<<pg<<std::endl;

	CLHEP::HepLorentzVector q1=p1in-p1out; // Top End
	CLHEP::HepLorentzVector q2=-(p2in-p2out); // Bottom End
	CLHEP::HepLorentzVector qg=p1in-p1out-pg; // Extra bit post-gluon

	// std::cerr<<"Current: "<<q1.m2()<<" "<<q2.m2()<<std::endl;
	CCurrent mj1m,mj1p,mj2m,mj2p,mjH2m,mjH2p;
	mj1p=joi(p1out,true,p1in,true);
	mj1m=joi(p1out,false,p1in,false);
	mjH2p=jH(p2out,true,p2in,true,qH1,qH2, mt, incBot, mb);
	mjH2m=jH(p2out,false,p2in,false,qH1,qH2, mt, incBot, mb);

	// Dot products of these which occur again and again
	COM MHmp=mj1m.dot(mjH2p); // And now for the Higgs ones
	COM MHmm=mj1m.dot(mjH2m);
	COM MHpp=mj1p.dot(mjH2p);
	COM MHpm=mj1p.dot(mjH2m);

	// std::cout<< p1out.rapidity() << " " << p2out.rapidity()<< " " << qH1 << " " << qH2 << "\n" <<MHmm << " " << MHmp << " " << MHpm << " " << MHpp << std::endl;

	// Currents with pg
	CCurrent jgam,jgap,j2gm,j2gp;
	j2gp=joo(p1out,true,pg,true);
	j2gm=joo(p1out,false,pg,false);
	jgap=joi(pg,true,p1in,true);
	jgam=joi(pg,false,p1in,false);

	CCurrent qsum(q1+qg);

	CCurrent Lmp,Lmm,Lpp,Lpm,U1mp,U1mm,U1pp,U1pm,U2mp,U2mm,U2pp,U2pm,p2o(p2out),p2i(p2in);
	CCurrent p1o(p1out);
	CCurrent p1i(p1in);

	Lmm=(qsum(MHmm) + (-2.mjH2m.dot(pg))mj1m+2.mj1m.dot(pg)mjH2m+(p2o/pg.dot(p2out) + p2i/pg.dot(p2in))(qg.m2()*MHmm/2.))/q1.m2();
	Lmp=(qsum(MHmp) + (-2.mjH2p.dot(pg))mj1m+2.mj1m.dot(pg)mjH2p+(p2o/pg.dot(p2out) + p2i/pg.dot(p2in))(qg.m2()*MHmp/2.))/q1.m2();
	Lpm=(qsum(MHpm) + (-2.mjH2m.dot(pg))mj1p+2.mj1p.dot(pg)mjH2m+(p2o/pg.dot(p2out) + p2i/pg.dot(p2in))(qg.m2()*MHpm/2.))/q1.m2();
	Lpp=(qsum(MHpp) + (-2.mjH2p.dot(pg))mj1p+2.mj1p.dot(pg)mjH2p+(p2o/pg.dot(p2out) + p2i/pg.dot(p2in))(qg.m2()*MHpp/2.))/q1.m2();

	U1mm=(jgam.dot(mjH2m)j2gm+2.p1o*MHmm)/(p1out+pg).m2();
	U1mp=(jgam.dot(mjH2p)j2gm+2.p1o*MHmp)/(p1out+pg).m2();
	U1pm=(jgap.dot(mjH2m)j2gp+2.p1o*MHpm)/(p1out+pg).m2();
	U1pp=(jgap.dot(mjH2p)j2gp+2.p1o*MHpp)/(p1out+pg).m2();
	U2mm=((-1.)j2gm.dot(mjH2m)jgam+2.p1iMHmm)/(p1in-pg).m2();
	U2mp=((-1.)j2gm.dot(mjH2p)jgam+2.p1iMHmp)/(p1in-pg).m2();
	U2pm=((-1.)j2gp.dot(mjH2m)jgap+2.p1iMHpm)/(p1in-pg).m2();
	U2pp=((-1.)j2gp.dot(mjH2p)jgap+2.p1iMHpp)/(p1in-pg).m2();

	const double cf=HEJ::C_F;
	double amm,amp,apm,app;

	amm=cf(2.vre(Lmm-U1mm,Lmm+U2mm))+2.cfcf/3.*vabs2(U1mm+U2mm);
	amp=cf(2.vre(Lmp-U1mp,Lmp+U2mp))+2.cfcf/3.*vabs2(U1mp+U2mp);
	apm=cf(2.vre(Lpm-U1pm,Lpm+U2pm))+2.cfcf/3.*vabs2(U1pm+U2pm);
	app=cf(2.vre(Lpp-U1pp,Lpp+U2pp))+2.cfcf/3.*vabs2(U1pp+U2pp);
	double ampsq=-(amm+amp+apm+app)/(q2.m2()*qH2.m2());

	// if ((vabs2(Lmm-U1mm+U2mm)+vabs2(Lmm)-vabs2(U1mm)-vabs2(U2mm))/(2*vre(Lmm-U1mm,Lmm+U2mm)) > 1.0000001)
	// std::cout << " Big Problem!! " << vabs2(Lmm-U1mm+U2mm)+vabs2(Lmm)-vabs2(U1mm)-vabs2(U2mm) << " " << 2*vre(Lmm-U1mm,Lmm+U2mm) << std::endl;
	// if ((vabs2(Lmm-U1mm+U2mm)+vabs2(Lmm)-vabs2(U1mm)-vabs2(U2mm))/(2*vre(Lmm-U1mm,Lmm+U2mm)) < 0.9999999)
	// std::cout << " Big Problem!! " << vabs2(Lmm-U1mm+U2mm)+vabs2(Lmm)-vabs2(U1mm)-vabs2(U2mm) << " " << 2*vre(Lmm-U1mm,Lmm+U2mm) << std::endl;

	// Now add the t-channels for the Higgs
	double th=qH1.m2()*qg.m2();
	ampsq/=th;
	ampsq/=16.;
	ampsq=HEJ::C_FHEJ::C_F/HEJ::C_A/HEJ::C_A; // Factor of (Cf/Ca) for each quark to match MH2qQ.
	//Higgs coupling is included in Hjets.C

	return ampsq;
	}

	double jM2unogqbarHQ (CLHEP::HepLorentzVector pg, CLHEP::HepLorentzVector p1out, CLHEP::HepLorentzVector p1in, CLHEP::HepLorentzVector p2out, CLHEP::HepLorentzVector p2in, CLHEP::HepLorentzVector qH1, CLHEP::HepLorentzVector qH2, double mt, bool incBot, double mb)
	{
	// This construction is taking rapidity order: pg > p1out >> p2out
	// std::cerr<<"This Uno Current: "<<p1out<<" "<<p1in<<" "<<p2out<<" "<<p2in<<" "<<pg<<std::endl;

	CLHEP::HepLorentzVector q1=p1in-p1out; // Top End
	CLHEP::HepLorentzVector q2=-(p2in-p2out); // Bottom End
	CLHEP::HepLorentzVector qg=p1in-p1out-pg; // Extra bit post-gluon

	// std::cerr<<"Current: "<<q1.m2()<<" "<<q2.m2()<<std::endl;
	CCurrent mj1m,mj1p,mj2m,mj2p,mjH2m,mjH2p;
	mj1p=jio(p1in,true,p1out,true);
	mj1m=jio(p1in,false,p1out,false);
	mjH2p=jH(p2out,true,p2in,true,qH1,qH2, mt, incBot, mb);
	mjH2m=jH(p2out,false,p2in,false,qH1,qH2, mt, incBot, mb);

	// Dot products of these which occur again and again
	COM MHmp=mj1m.dot(mjH2p); // And now for the Higgs ones
	COM MHmm=mj1m.dot(mjH2m);
	COM MHpp=mj1p.dot(mjH2p);
	COM MHpm=mj1p.dot(mjH2m);

	// Currents with pg
	CCurrent jgam,jgap,j2gm,j2gp;
	j2gp=joo(pg,true,p1out,true);
	j2gm=joo(pg,false,p1out,false);
	jgap=jio(p1in,true,pg,true);
	jgam=jio(p1in,false,pg,false);

	CCurrent qsum(q1+qg);

	CCurrent Lmp,Lmm,Lpp,Lpm,U1mp,U1mm,U1pp,U1pm,U2mp,U2mm,U2pp,U2pm,p2o(p2out),p2i(p2in);
	CCurrent p1o(p1out);
	CCurrent p1i(p1in);

	Lmm=(qsum(MHmm) + (-2.mjH2m.dot(pg))mj1m+2.mj1m.dot(pg)mjH2m+(p2o/pg.dot(p2out) + p2i/pg.dot(p2in))(qg.m2()*MHmm/2.))/q1.m2();
	Lmp=(qsum(MHmp) + (-2.mjH2p.dot(pg))mj1m+2.mj1m.dot(pg)mjH2p+(p2o/pg.dot(p2out) + p2i/pg.dot(p2in))(qg.m2()*MHmp/2.))/q1.m2();
	Lpm=(qsum(MHpm) + (-2.mjH2m.dot(pg))mj1p+2.mj1p.dot(pg)mjH2m+(p2o/pg.dot(p2out) + p2i/pg.dot(p2in))(qg.m2()*MHpm/2.))/q1.m2();
	Lpp=(qsum(MHpp) + (-2.mjH2p.dot(pg))mj1p+2.mj1p.dot(pg)mjH2p+(p2o/pg.dot(p2out) + p2i/pg.dot(p2in))(qg.m2()*MHpp/2.))/q1.m2();

	U1mm=(jgam.dot(mjH2m)j2gm+2.p1o*MHmm)/(p1out+pg).m2();
	U1mp=(jgam.dot(mjH2p)j2gm+2.p1o*MHmp)/(p1out+pg).m2();
	U1pm=(jgap.dot(mjH2m)j2gp+2.p1o*MHpm)/(p1out+pg).m2();
	U1pp=(jgap.dot(mjH2p)j2gp+2.p1o*MHpp)/(p1out+pg).m2();
	U2mm=((-1.)j2gm.dot(mjH2m)jgam+2.p1iMHmm)/(p1in-pg).m2();
	U2mp=((-1.)j2gm.dot(mjH2p)jgam+2.p1iMHmp)/(p1in-pg).m2();
	U2pm=((-1.)j2gp.dot(mjH2m)jgap+2.p1iMHpm)/(p1in-pg).m2();
	U2pp=((-1.)j2gp.dot(mjH2p)jgap+2.p1iMHpp)/(p1in-pg).m2();

	const double cf=HEJ::C_F;
	double amm,amp,apm,app;

	amm=cf(2.vre(Lmm-U1mm,Lmm+U2mm))+2.cfcf/3.*vabs2(U1mm+U2mm);
	amp=cf(2.vre(Lmp-U1mp,Lmp+U2mp))+2.cfcf/3.*vabs2(U1mp+U2mp);
	apm=cf(2.vre(Lpm-U1pm,Lpm+U2pm))+2.cfcf/3.*vabs2(U1pm+U2pm);
	app=cf(2.vre(Lpp-U1pp,Lpp+U2pp))+2.cfcf/3.*vabs2(U1pp+U2pp);
	double ampsq=-(amm+amp+apm+app)/(q2.m2()*qH2.m2());

	// if ((vabs2(Lmm-U1mm+U2mm)+vabs2(Lmm)-vabs2(U1mm)-vabs2(U2mm))/(2*vre(Lmm-U1mm,Lmm+U2mm)) > 1.0000001)
	// std::cout << " Big Problem!! " << vabs2(Lmm-U1mm+U2mm)+vabs2(Lmm)-vabs2(U1mm)-vabs2(U2mm) << " " << 2*vre(Lmm-U1mm,Lmm+U2mm) << std::endl;
	// if ((vabs2(Lmm-U1mm+U2mm)+vabs2(Lmm)-vabs2(U1mm)-vabs2(U2mm))/(2*vre(Lmm-U1mm,Lmm+U2mm)) < 0.9999999)
	// std::cout << " Big Problem!! " << vabs2(Lmm-U1mm+U2mm)+vabs2(Lmm)-vabs2(U1mm)-vabs2(U2mm) << " " << 2*vre(Lmm-U1mm,Lmm+U2mm) << std::endl;

	// Now add the t-channels for the Higgs
	double th=qH1.m2()*qg.m2();
	ampsq/=th;
	ampsq/=16.;
	ampsq=4.4./(9.*9.); // Factor of (Cf/Ca) for each quark to match MH2qQ.
	//Higgs coupling is included in Hjets.C

	return ampsq;
	}

	double jM2unogqHQbar (CLHEP::HepLorentzVector pg, CLHEP::HepLorentzVector p1out, CLHEP::HepLorentzVector p1in, CLHEP::HepLorentzVector p2out, CLHEP::HepLorentzVector p2in, CLHEP::HepLorentzVector qH1, CLHEP::HepLorentzVector qH2, double mt, bool incBot, double mb)
	{
	// This construction is taking rapidity order: pg > p1out >> p2out
	// std::cerr<<"This Uno Current: "<<p1out<<" "<<p1in<<" "<<p2out<<" "<<p2in<<" "<<pg<<std::endl;

	CLHEP::HepLorentzVector q1=p1in-p1out; // Top End
	CLHEP::HepLorentzVector q2=-(p2in-p2out); // Bottom End
	CLHEP::HepLorentzVector qg=p1in-p1out-pg; // Extra bit post-gluon

	// std::cerr<<"Current: "<<q1.m2()<<" "<<q2.m2()<<std::endl;
	CCurrent mj1m,mj1p,mj2m,mj2p,mjH2m,mjH2p;
	mj1p=joi(p1out,true,p1in,true);
	mj1m=joi(p1out,false,p1in,false);
	mjH2p=jioH(p2in,true,p2out,true,qH1,qH2, mt, incBot, mb);
	mjH2m=jioH(p2in,false,p2out,false,qH1,qH2, mt, incBot, mb);

	// Dot products of these which occur again and again
	COM MHmp=mj1m.dot(mjH2p); // And now for the Higgs ones
	COM MHmm=mj1m.dot(mjH2m);
	COM MHpp=mj1p.dot(mjH2p);
	COM MHpm=mj1p.dot(mjH2m);

	// Currents with pg
	CCurrent jgam,jgap,j2gm,j2gp;
	j2gp=joo(p1out,true,pg,true);
	j2gm=joo(p1out,false,pg,false);
	jgap=joi(pg,true,p1in,true);
	jgam=joi(pg,false,p1in,false);

	CCurrent qsum(q1+qg);

	CCurrent Lmp,Lmm,Lpp,Lpm,U1mp,U1mm,U1pp,U1pm,U2mp,U2mm,U2pp,U2pm,p2o(p2out),p2i(p2in);
	CCurrent p1o(p1out);
	CCurrent p1i(p1in);

	Lmm=(qsum(MHmm) + (-2.mjH2m.dot(pg))mj1m+2.mj1m.dot(pg)mjH2m+(p2o/pg.dot(p2out) + p2i/pg.dot(p2in))(qg.m2()*MHmm/2.))/q1.m2();
	Lmp=(qsum(MHmp) + (-2.mjH2p.dot(pg))mj1m+2.mj1m.dot(pg)mjH2p+(p2o/pg.dot(p2out) + p2i/pg.dot(p2in))(qg.m2()*MHmp/2.))/q1.m2();
	Lpm=(qsum(MHpm) + (-2.mjH2m.dot(pg))mj1p+2.mj1p.dot(pg)mjH2m+(p2o/pg.dot(p2out) + p2i/pg.dot(p2in))(qg.m2()*MHpm/2.))/q1.m2();
	Lpp=(qsum(MHpp) + (-2.mjH2p.dot(pg))mj1p+2.mj1p.dot(pg)mjH2p+(p2o/pg.dot(p2out) + p2i/pg.dot(p2in))(qg.m2()*MHpp/2.))/q1.m2();

	U1mm=(jgam.dot(mjH2m)j2gm+2.p1o*MHmm)/(p1out+pg).m2();
	U1mp=(jgam.dot(mjH2p)j2gm+2.p1o*MHmp)/(p1out+pg).m2();
	U1pm=(jgap.dot(mjH2m)j2gp+2.p1o*MHpm)/(p1out+pg).m2();
	U1pp=(jgap.dot(mjH2p)j2gp+2.p1o*MHpp)/(p1out+pg).m2();
	U2mm=((-1.)j2gm.dot(mjH2m)jgam+2.p1iMHmm)/(p1in-pg).m2();
	U2mp=((-1.)j2gm.dot(mjH2p)jgam+2.p1iMHmp)/(p1in-pg).m2();
	U2pm=((-1.)j2gp.dot(mjH2m)jgap+2.p1iMHpm)/(p1in-pg).m2();
	U2pp=((-1.)j2gp.dot(mjH2p)jgap+2.p1iMHpp)/(p1in-pg).m2();

	const double cf=HEJ::C_F;
	double amm,amp,apm,app;

	amm=cf(2.vre(Lmm-U1mm,Lmm+U2mm))+2.cfcf/3.*vabs2(U1mm+U2mm);
	amp=cf(2.vre(Lmp-U1mp,Lmp+U2mp))+2.cfcf/3.*vabs2(U1mp+U2mp);
	apm=cf(2.vre(Lpm-U1pm,Lpm+U2pm))+2.cfcf/3.*vabs2(U1pm+U2pm);
	app=cf(2.vre(Lpp-U1pp,Lpp+U2pp))+2.cfcf/3.*vabs2(U1pp+U2pp);
	double ampsq=-(amm+amp+apm+app)/(q2.m2()*qH2.m2());

	// if ((vabs2(Lmm-U1mm+U2mm)+vabs2(Lmm)-vabs2(U1mm)-vabs2(U2mm))/(2*vre(Lmm-U1mm,Lmm+U2mm)) > 1.0000001)
	// std::cout << " Big Problem!! " << vabs2(Lmm-U1mm+U2mm)+vabs2(Lmm)-vabs2(U1mm)-vabs2(U2mm) << " " << 2*vre(Lmm-U1mm,Lmm+U2mm) << std::endl;
	// if ((vabs2(Lmm-U1mm+U2mm)+vabs2(Lmm)-vabs2(U1mm)-vabs2(U2mm))/(2*vre(Lmm-U1mm,Lmm+U2mm)) < 0.9999999)
	// std::cout << " Big Problem!! " << vabs2(Lmm-U1mm+U2mm)+vabs2(Lmm)-vabs2(U1mm)-vabs2(U2mm) << " " << 2*vre(Lmm-U1mm,Lmm+U2mm) << std::endl;

	// Now add the t-channels for the Higgs
	double th=qH1.m2()*qg.m2();
	ampsq/=th;
	ampsq/=16.;
	ampsq=4.4./(9.*9.); // Factor of (Cf/Ca) for each quark to match MH2qQ.
	//Higgs coupling is included in Hjets.C

	return ampsq;
	}

	double jM2unogqbarHQbar (CLHEP::HepLorentzVector pg, CLHEP::HepLorentzVector p1out, CLHEP::HepLorentzVector p1in, CLHEP::HepLorentzVector p2out, CLHEP::HepLorentzVector p2in, CLHEP::HepLorentzVector qH1, CLHEP::HepLorentzVector qH2, double mt, bool incBot, double mb)
	{
	// This construction is taking rapidity order: pg > p1out >> p2out
	// std::cerr<<"This Uno Current: "<<p1out<<" "<<p1in<<" "<<p2out<<" "<<p2in<<" "<<pg<<std::endl;

	CLHEP::HepLorentzVector q1=p1in-p1out; // Top End
	CLHEP::HepLorentzVector q2=-(p2in-p2out); // Bottom End
	CLHEP::HepLorentzVector qg=p1in-p1out-pg; // Extra bit post-gluon

	// std::cerr<<"Current: "<<q1.m2()<<" "<<q2.m2()<<std::endl;
	CCurrent mj1m,mj1p,mj2m,mj2p,mjH2m,mjH2p;
	mj1p=jio(p1in,true,p1out,true);
	mj1m=jio(p1in,false,p1out,false);
	mjH2p=jioH(p2in,true,p2out,true,qH1,qH2, mt, incBot, mb);
	mjH2m=jioH(p2in,false,p2out,false,qH1,qH2, mt, incBot, mb);

	// Dot products of these which occur again and again
	COM MHmp=mj1m.dot(mjH2p); // And now for the Higgs ones
	COM MHmm=mj1m.dot(mjH2m);
	COM MHpp=mj1p.dot(mjH2p);
	COM MHpm=mj1p.dot(mjH2m);

	// Currents with pg
	CCurrent jgam,jgap,j2gm,j2gp;
	j2gp=joo(pg,true,p1out,true);
	j2gm=joo(pg,false,p1out,false);
	jgap=jio(p1in,true,pg,true);
	jgam=jio(p1in,false,pg,false);

	CCurrent qsum(q1+qg);

	CCurrent Lmp,Lmm,Lpp,Lpm,U1mp,U1mm,U1pp,U1pm,U2mp,U2mm,U2pp,U2pm,p2o(p2out),p2i(p2in);
	CCurrent p1o(p1out);
	CCurrent p1i(p1in);

	Lmm=(qsum(MHmm) + (-2.mjH2m.dot(pg))mj1m+2.mj1m.dot(pg)mjH2m+(p2o/pg.dot(p2out) + p2i/pg.dot(p2in))(qg.m2()*MHmm/2.))/q1.m2();
	Lmp=(qsum(MHmp) + (-2.mjH2p.dot(pg))mj1m+2.mj1m.dot(pg)mjH2p+(p2o/pg.dot(p2out) + p2i/pg.dot(p2in))(qg.m2()*MHmp/2.))/q1.m2();
	Lpm=(qsum(MHpm) + (-2.mjH2m.dot(pg))mj1p+2.mj1p.dot(pg)mjH2m+(p2o/pg.dot(p2out) + p2i/pg.dot(p2in))(qg.m2()*MHpm/2.))/q1.m2();
	Lpp=(qsum(MHpp) + (-2.mjH2p.dot(pg))mj1p+2.mj1p.dot(pg)mjH2p+(p2o/pg.dot(p2out) + p2i/pg.dot(p2in))(qg.m2()*MHpp/2.))/q1.m2();

	U1mm=(jgam.dot(mjH2m)j2gm+2.p1o*MHmm)/(p1out+pg).m2();
	U1mp=(jgam.dot(mjH2p)j2gm+2.p1o*MHmp)/(p1out+pg).m2();
	U1pm=(jgap.dot(mjH2m)j2gp+2.p1o*MHpm)/(p1out+pg).m2();
	U1pp=(jgap.dot(mjH2p)j2gp+2.p1o*MHpp)/(p1out+pg).m2();
	U2mm=((-1.)j2gm.dot(mjH2m)jgam+2.p1iMHmm)/(p1in-pg).m2();
	U2mp=((-1.)j2gm.dot(mjH2p)jgam+2.p1iMHmp)/(p1in-pg).m2();
	U2pm=((-1.)j2gp.dot(mjH2m)jgap+2.p1iMHpm)/(p1in-pg).m2();
	U2pp=((-1.)j2gp.dot(mjH2p)jgap+2.p1iMHpp)/(p1in-pg).m2();

	const double cf=HEJ::C_F;
	double amm,amp,apm,app;

	amm=cf(2.vre(Lmm-U1mm,Lmm+U2mm))+2.cfcf/3.*vabs2(U1mm+U2mm);
	amp=cf(2.vre(Lmp-U1mp,Lmp+U2mp))+2.cfcf/3.*vabs2(U1mp+U2mp);
	apm=cf(2.vre(Lpm-U1pm,Lpm+U2pm))+2.cfcf/3.*vabs2(U1pm+U2pm);
	app=cf(2.vre(Lpp-U1pp,Lpp+U2pp))+2.cfcf/3.*vabs2(U1pp+U2pp);
	double ampsq=-(amm+amp+apm+app)/(q2.m2()*qH2.m2());

	// if ((vabs2(Lmm-U1mm+U2mm)+vabs2(Lmm)-vabs2(U1mm)-vabs2(U2mm))/(2*vre(Lmm-U1mm,Lmm+U2mm)) > 1.0000001)
	// std::cout << " Big Problem!! " << vabs2(Lmm-U1mm+U2mm)+vabs2(Lmm)-vabs2(U1mm)-vabs2(U2mm) << " " << 2*vre(Lmm-U1mm,Lmm+U2mm) << std::endl;
	// if ((vabs2(Lmm-U1mm+U2mm)+vabs2(Lmm)-vabs2(U1mm)-vabs2(U2mm))/(2*vre(Lmm-U1mm,Lmm+U2mm)) < 0.9999999)
	// std::cout << " Big Problem!! " << vabs2(Lmm-U1mm+U2mm)+vabs2(Lmm)-vabs2(U1mm)-vabs2(U2mm) << " " << 2*vre(Lmm-U1mm,Lmm+U2mm) << std::endl;

	// Now add the t-channels for the Higgs
	double th=qH1.m2()*qg.m2();
	ampsq/=th;
	ampsq/=16.;
	//Higgs coupling is included in Hjets.C
	ampsq=4.4./(9.*9.); // Factor of (Cf/Ca) for each quark to match MH2qQ.

	return ampsq;
	}

	double jM2unogqHg (CLHEP::HepLorentzVector pg, CLHEP::HepLorentzVector p1out, CLHEP::HepLorentzVector p1in, CLHEP::HepLorentzVector p2out, CLHEP::HepLorentzVector p2in, CLHEP::HepLorentzVector qH1, CLHEP::HepLorentzVector qH2, double mt, bool incBot, double mb)
	{
	// This construction is taking rapidity order: pg > p1out >> p2out
	// std::cerr<<"This Uno Current: "<<p1out<<" "<<p1in<<" "<<p2out<<" "<<p2in<<" "<<pg<<std::endl;

	CLHEP::HepLorentzVector q1=p1in-p1out; // Top End
	CLHEP::HepLorentzVector q2=-(p2in-p2out); // Bottom End
	CLHEP::HepLorentzVector qg=p1in-p1out-pg; // Extra bit post-gluon

	CCurrent mj1m,mj1p,mj2m,mj2p,mjH2m,mjH2p;
	mj1p=joi(p1out,true,p1in,true);
	mj1m=joi(p1out,false,p1in,false);
	mjH2p=jH(p2out,true,p2in,true,qH1,qH2, mt, incBot, mb);
	mjH2m=jH(p2out,false,p2in,false,qH1,qH2, mt, incBot, mb);

	// Dot products of these which occur again and again
	COM MHmp=mj1m.dot(mjH2p); // And now for the Higgs ones
	COM MHmm=mj1m.dot(mjH2m);
	COM MHpp=mj1p.dot(mjH2p);
	COM MHpm=mj1p.dot(mjH2m);

	// Currents with pg
	CCurrent jgam,jgap,j2gm,j2gp;
	j2gp=joo(p1out,true,pg,true);
	j2gm=joo(p1out,false,pg,false);
	jgap=joi(pg,true,p1in,true);
	jgam=joi(pg,false,p1in,false);

	CCurrent qsum(q1+qg);

	CCurrent Lmp,Lmm,Lpp,Lpm,U1mp,U1mm,U1pp,U1pm,U2mp,U2mm,U2pp,U2pm,p2o(p2out),p2i(p2in);
	CCurrent p1o(p1out);
	CCurrent p1i(p1in);

	Lmm=(qsum(MHmm) + (-2.mjH2m.dot(pg))mj1m+2.mj1m.dot(pg)mjH2m+(p2o/pg.dot(p2out) + p2i/pg.dot(p2in))(qg.m2()*MHmm/2.))/q1.m2();
	Lmp=(qsum(MHmp) + (-2.mjH2p.dot(pg))mj1m+2.mj1m.dot(pg)mjH2p+(p2o/pg.dot(p2out) + p2i/pg.dot(p2in))(qg.m2()*MHmp/2.))/q1.m2();
	Lpm=(qsum(MHpm) + (-2.mjH2m.dot(pg))mj1p+2.mj1p.dot(pg)mjH2m+(p2o/pg.dot(p2out) + p2i/pg.dot(p2in))(qg.m2()*MHpm/2.))/q1.m2();
	Lpp=(qsum(MHpp) + (-2.mjH2p.dot(pg))mj1p+2.mj1p.dot(pg)mjH2p+(p2o/pg.dot(p2out) + p2i/pg.dot(p2in))(qg.m2()*MHpp/2.))/q1.m2();

	U1mm=(jgam.dot(mjH2m)j2gm+2.p1o*MHmm)/(p1out+pg).m2();
	U1mp=(jgam.dot(mjH2p)j2gm+2.p1o*MHmp)/(p1out+pg).m2();
	U1pm=(jgap.dot(mjH2m)j2gp+2.p1o*MHpm)/(p1out+pg).m2();
	U1pp=(jgap.dot(mjH2p)j2gp+2.p1o*MHpp)/(p1out+pg).m2();
	U2mm=((-1.)j2gm.dot(mjH2m)jgam+2.p1iMHmm)/(p1in-pg).m2();
	U2mp=((-1.)j2gm.dot(mjH2p)jgam+2.p1iMHmp)/(p1in-pg).m2();
	U2pm=((-1.)j2gp.dot(mjH2m)jgap+2.p1iMHpm)/(p1in-pg).m2();
	U2pp=((-1.)j2gp.dot(mjH2p)jgap+2.p1iMHpp)/(p1in-pg).m2();

	const double cf=HEJ::C_F;
	double amm,amp,apm,app;

	amm=cf(2.vre(Lmm-U1mm,Lmm+U2mm))+2.cfcf/3.*vabs2(U1mm+U2mm);
	amp=cf(2.vre(Lmp-U1mp,Lmp+U2mp))+2.cfcf/3.*vabs2(U1mp+U2mp);
	apm=cf(2.vre(Lpm-U1pm,Lpm+U2pm))+2.cfcf/3.*vabs2(U1pm+U2pm);
	app=cf(2.vre(Lpp-U1pp,Lpp+U2pp))+2.cfcf/3.*vabs2(U1pp+U2pp);
	double ampsq=-(amm+amp+apm+app)/(q2.m2()*qH2.m2());

	// if ((vabs2(Lmm-U1mm+U2mm)+vabs2(Lmm)-vabs2(U1mm)-vabs2(U2mm))/(2*vre(Lmm-U1mm,Lmm+U2mm)) > 1.0000001)
	// std::cout << " Big Problem!! " << vabs2(Lmm-U1mm+U2mm)+vabs2(Lmm)-vabs2(U1mm)-vabs2(U2mm) << " " << 2*vre(Lmm-U1mm,Lmm+U2mm) << std::endl;
	// if ((vabs2(Lmm-U1mm+U2mm)+vabs2(Lmm)-vabs2(U1mm)-vabs2(U2mm))/(2*vre(Lmm-U1mm,Lmm+U2mm)) < 0.9999999)
	// std::cout << " Big Problem!! " << vabs2(Lmm-U1mm+U2mm)+vabs2(Lmm)-vabs2(U1mm)-vabs2(U2mm) << " " << 2*vre(Lmm-U1mm,Lmm+U2mm) << std::endl;

	// Now add the t-channels for the Higgs
	double th=qH1.m2()*qg.m2();
	ampsq/=th;
	ampsq/=16.;
	ampsq=4./9.4./9.; // Factor of (Cf/Ca) for each quark to match MH2qQ.
	// here we need 2 to match with the normalization
	// gq is 9./4. times the qQ
	//Higgs coupling is included in Hjets.C

	const double K = K_g(p2out, p2in);

	return ampsqK/C_A9./4.; //ca/cf = 9/4
	}

	double jM2unogqbarHg (CLHEP::HepLorentzVector pg, CLHEP::HepLorentzVector p1out, CLHEP::HepLorentzVector p1in, CLHEP::HepLorentzVector p2out, CLHEP::HepLorentzVector p2in, CLHEP::HepLorentzVector qH1, CLHEP::HepLorentzVector qH2, double mt, bool incBot, double mb)
	{
	// This construction is taking rapidity order: pg > p1out >> p2out
	// std::cerr<<"This Uno Current: "<<p1out<<" "<<p1in<<" "<<p2out<<" "<<p2in<<" "<<pg<<std::endl;

	CLHEP::HepLorentzVector q1=p1in-p1out; // Top End
	CLHEP::HepLorentzVector q2=-(p2in-p2out); // Bottom End
	CLHEP::HepLorentzVector qg=p1in-p1out-pg; // Extra bit post-gluon

	CCurrent mj1m,mj1p,mj2m,mj2p,mjH2m,mjH2p;
	mj1p=jio(p1in,true,p1out,true);
	mj1m=jio(p1in,false,p1out,false);
	mjH2p=jH(p2out,true,p2in,true,qH1,qH2, mt, incBot, mb);
	mjH2m=jH(p2out,false,p2in,false,qH1,qH2, mt, incBot, mb);

	// Dot products of these which occur again and again
	COM MHmp=mj1m.dot(mjH2p); // And now for the Higgs ones
	COM MHmm=mj1m.dot(mjH2m);
	COM MHpp=mj1p.dot(mjH2p);
	COM MHpm=mj1p.dot(mjH2m);

	// Currents with pg
	CCurrent jgam,jgap,j2gm,j2gp;
	j2gp=joo(pg,true,p1out,true);
	j2gm=joo(pg,false,p1out,false);
	jgap=jio(p1in,true,pg,true);
	jgam=jio(p1in,false,pg,false);

	CCurrent qsum(q1+qg);

	CCurrent Lmp,Lmm,Lpp,Lpm,U1mp,U1mm,U1pp,U1pm,U2mp,U2mm,U2pp,U2pm,p2o(p2out),p2i(p2in);
	CCurrent p1o(p1out);
	CCurrent p1i(p1in);

	Lmm=(qsum(MHmm) + (-2.mjH2m.dot(pg))mj1m+2.mj1m.dot(pg)mjH2m+(p2o/pg.dot(p2out) + p2i/pg.dot(p2in))(qg.m2()*MHmm/2.))/q1.m2();
	Lmp=(qsum(MHmp) + (-2.mjH2p.dot(pg))mj1m+2.mj1m.dot(pg)mjH2p+(p2o/pg.dot(p2out) + p2i/pg.dot(p2in))(qg.m2()*MHmp/2.))/q1.m2();
	Lpm=(qsum(MHpm) + (-2.mjH2m.dot(pg))mj1p+2.mj1p.dot(pg)mjH2m+(p2o/pg.dot(p2out) + p2i/pg.dot(p2in))(qg.m2()*MHpm/2.))/q1.m2();
	Lpp=(qsum(MHpp) + (-2.mjH2p.dot(pg))mj1p+2.mj1p.dot(pg)mjH2p+(p2o/pg.dot(p2out) + p2i/pg.dot(p2in))(qg.m2()*MHpp/2.))/q1.m2();

	U1mm=(jgam.dot(mjH2m)j2gm+2.p1o*MHmm)/(p1out+pg).m2();
	U1mp=(jgam.dot(mjH2p)j2gm+2.p1o*MHmp)/(p1out+pg).m2();
	U1pm=(jgap.dot(mjH2m)j2gp+2.p1o*MHpm)/(p1out+pg).m2();
	U1pp=(jgap.dot(mjH2p)j2gp+2.p1o*MHpp)/(p1out+pg).m2();
	U2mm=((-1.)j2gm.dot(mjH2m)jgam+2.p1iMHmm)/(p1in-pg).m2();
	U2mp=((-1.)j2gm.dot(mjH2p)jgam+2.p1iMHmp)/(p1in-pg).m2();
	U2pm=((-1.)j2gp.dot(mjH2m)jgap+2.p1iMHpm)/(p1in-pg).m2();
	U2pp=((-1.)j2gp.dot(mjH2p)jgap+2.p1iMHpp)/(p1in-pg).m2();

	const double cf=HEJ::C_F;
	double amm,amp,apm,app;

	amm=cf(2.vre(Lmm-U1mm,Lmm+U2mm))+2.cfcf/3.*vabs2(U1mm+U2mm);
	amp=cf(2.vre(Lmp-U1mp,Lmp+U2mp))+2.cfcf/3.*vabs2(U1mp+U2mp);
	apm=cf(2.vre(Lpm-U1pm,Lpm+U2pm))+2.cfcf/3.*vabs2(U1pm+U2pm);
	app=cf(2.vre(Lpp-U1pp,Lpp+U2pp))+2.cfcf/3.*vabs2(U1pp+U2pp);
	double ampsq=-(amm+amp+apm+app)/(q2.m2()*qH2.m2());

	// if ((vabs2(Lmm-U1mm+U2mm)+vabs2(Lmm)-vabs2(U1mm)-vabs2(U2mm))/(2*vre(Lmm-U1mm,Lmm+U2mm)) > 1.0000001)
	// std::cout << " Big Problem!! " << vabs2(Lmm-U1mm+U2mm)+vabs2(Lmm)-vabs2(U1mm)-vabs2(U2mm) << " " << 2*vre(Lmm-U1mm,Lmm+U2mm) << std::endl;
	// if ((vabs2(Lmm-U1mm+U2mm)+vabs2(Lmm)-vabs2(U1mm)-vabs2(U2mm))/(2*vre(Lmm-U1mm,Lmm+U2mm)) < 0.9999999)
	// std::cout << " Big Problem!! " << vabs2(Lmm-U1mm+U2mm)+vabs2(Lmm)-vabs2(U1mm)-vabs2(U2mm) << " " << 2*vre(Lmm-U1mm,Lmm+U2mm) << std::endl;

	// Now add the t-channels for the Higgs
	double th=qH1.m2()*qg.m2();
	ampsq/=th;
	ampsq/=16.;
	ampsq=4./9.4./9.; // Factor of (Cf/Ca) for each quark to match MH2qQ.
	// here we need 2 to match with the normalization
	// gq is 9./4. times the qQ
	//Higgs coupling is included in Hjets.C

	const double K = K_g(p2out, p2in);

	return ampsq*K/C_F;
	}

	double jM2unobqHQg (CLHEP::HepLorentzVector p1out, CLHEP::HepLorentzVector p1in, CLHEP::HepLorentzVector pg, CLHEP::HepLorentzVector p2out, CLHEP::HepLorentzVector p2in, CLHEP::HepLorentzVector qH1, CLHEP::HepLorentzVector qH2, double mt, bool incBot, double mb)
	{
	// std::cout << "####################\n";
	// std::cout << "# p1in : "<<p1in<< " "<<p1in.plus()<<" "<<p1in.minus()<<std::endl;
	// std::cout << "# p2in : "<<p2in<< " "<<p2in.plus()<<" "<<p2in.minus()<<std::endl;
	// std::cout << "# p1out : "<<p1out<< " "<<p1out.rapidity()<<std::endl;
	// std::cout << "# (qH1-qH2) : "<<(qH1-qH2)<< " "<<(qH1-qH2).rapidity()<<std::endl;
	// std::cout << "# pg : "<<pg<< " "<<pg.rapidity()<<std::endl;
	// std::cout << "# p2out : "<<p2out<< " "<<p2out.rapidity()<<std::endl;
	// std::cout << "####################\n";

	CLHEP::HepLorentzVector q1=p1in-p1out; // Top End
	CLHEP::HepLorentzVector q2=-(p2in-p2out-pg); // Extra bit pre-gluon
	CLHEP::HepLorentzVector q3=-(p2in-p2out); // Bottom End

	// std::cerr<<"Current: "<<q1.m2()<<" "<<q2.m2()<<std::endl;
	CCurrent mjH1m,mjH1p,mj2m,mj2p;
	mjH1p=jHtop(p1out,true,p1in,true,qH1,qH2, mt, incBot, mb);
	mjH1m=jHtop(p1out,false,p1in,false,qH1,qH2, mt, incBot, mb);
	mj2p=joi(p2out,true,p2in,true);
	mj2m=joi(p2out,false,p2in,false);

	// Dot products of these which occur again and again
	COM MHmp=mjH1m.dot(mj2p); // And now for the Higgs ones
	COM MHmm=mjH1m.dot(mj2m);
	COM MHpp=mjH1p.dot(mj2p);
	COM MHpm=mjH1p.dot(mj2m);

	// Currents with pg
	CCurrent jgbm,jgbp,j2gm,j2gp;
	j2gp=joo(p2out,true,pg,true);
	j2gm=joo(p2out,false,pg,false);
	jgbp=joi(pg,true,p2in,true);
	jgbm=joi(pg,false,p2in,false);

	CCurrent qsum(q2+q3);

	CCurrent Lmp,Lmm,Lpp,Lpm,U1mp,U1mm,U1pp,U1pm,U2mp,U2mm,U2pp,U2pm,p1o(p1out),p1i(p1in);
	CCurrent p2o(p2out);
	CCurrent p2i(p2in);

	CCurrent pplus((p1in+p1out)/2.);
	CCurrent pminus((p2in+p2out)/2.);

	// COM test=pminus.dot(p1in);

	Lmm=((-1.)qsum(MHmm) + (-2.mjH1m.dot(pg))mj2m+2.mj2m.dot(pg)mjH1m
	+ (p1o/pg.dot(p1out) + p1i/pg.dot(p1in))(q2.m2()MHmm/2.))/q3.m2();
	Lmp=((-1.)qsum(MHmp) + (-2.mjH1m.dot(pg))mj2p+2.mj2p.dot(pg)mjH1m
	+(p1o/pg.dot(p1out) + p1i/pg.dot(p1in))(q2.m2()MHmp/2.))/q3.m2();
	Lpm=((-1.)qsum(MHpm) + (-2.mjH1p.dot(pg))mj2m+2.mj2m.dot(pg)mjH1p
	+(p1o/pg.dot(p1out) + p1i/pg.dot(p1in))(q2.m2()MHpm/2.))/q3.m2();
	Lpp=((-1.)qsum(MHpp) + (-2.mjH1p.dot(pg))mj2p+2.mj2p.dot(pg)mjH1p
	+(p1o/pg.dot(p1out) + p1i/pg.dot(p1in))(q2.m2()MHpp/2.))/q3.m2();
	U1mm=(jgbm.dot(mjH1m)j2gm+2.p2o*MHmm)/(p2out+pg).m2();
	U1mp=(jgbp.dot(mjH1m)j2gp+2.p2o*MHmp)/(p2out+pg).m2();
	U1pm=(jgbm.dot(mjH1p)j2gm+2.p2o*MHpm)/(p2out+pg).m2();
	U1pp=(jgbp.dot(mjH1p)j2gp+2.p2o*MHpp)/(p2out+pg).m2();
	U2mm=((-1.)j2gm.dot(mjH1m)jgbm+2.p2iMHmm)/(p2in-pg).m2();
	U2mp=((-1.)j2gp.dot(mjH1m)jgbp+2.p2iMHmp)/(p2in-pg).m2();
	U2pm=((-1.)j2gm.dot(mjH1p)jgbm+2.p2iMHpm)/(p2in-pg).m2();
	U2pp=((-1.)j2gp.dot(mjH1p)jgbp+2.p2iMHpp)/(p2in-pg).m2();

	const double cf=HEJ::C_F;
	double amm,amp,apm,app;

	amm=cf(2.vre(Lmm-U1mm,Lmm+U2mm))+2.cfcf/3.*vabs2(U1mm+U2mm);
	amp=cf(2.vre(Lmp-U1mp,Lmp+U2mp))+2.cfcf/3.*vabs2(U1mp+U2mp);
	apm=cf(2.vre(Lpm-U1pm,Lpm+U2pm))+2.cfcf/3.*vabs2(U1pm+U2pm);
	app=cf(2.vre(Lpp-U1pp,Lpp+U2pp))+2.cfcf/3.*vabs2(U1pp+U2pp);
	// 1/3. = 1/C_A ?
	double ampsq=-(amm+amp+apm+app)/(q1.m2()*qH1.m2());

	// if ((vabs2(Lmm-U1mm+U2mm)+vabs2(Lmm)-vabs2(U1mm)-vabs2(U2mm))/(2*vre(Lmm-U1mm,Lmm+U2mm)) > 1.0000001)
	// std::cout << " Big Problem!! " << vabs2(Lmm-U1mm+U2mm)+vabs2(Lmm)-vabs2(U1mm)-vabs2(U2mm) << " " << 2*vre(Lmm-U1mm,Lmm+U2mm) << std::endl;
	// if ((vabs2(Lmm-U1mm+U2mm)+vabs2(Lmm)-vabs2(U1mm)-vabs2(U2mm))/(2*vre(Lmm-U1mm,Lmm+U2mm)) < 0.9999999)
	// std::cout << " Big Problem!! " << vabs2(Lmm-U1mm+U2mm)+vabs2(Lmm)-vabs2(U1mm)-vabs2(U2mm) << " " << 2*vre(Lmm-U1mm,Lmm+U2mm) << std::endl;

	// Now add the t-channels for the Higgs
	const double th=qH2.m2()*q2.m2();
	ampsq/=th;
	ampsq/=16.;
	ampsq=HEJ::C_FHEJ::C_F/(HEJ::C_A*HEJ::C_A); // Factor of (Cf/Ca) for each quark to match MH2qQ.

	return ampsq;
	}



	double jM2unobqbarHQg (CLHEP::HepLorentzVector p1out, CLHEP::HepLorentzVector p1in, CLHEP::HepLorentzVector pg, CLHEP::HepLorentzVector p2out, CLHEP::HepLorentzVector p2in, CLHEP::HepLorentzVector qH1, CLHEP::HepLorentzVector qH2, double mt, bool incBot, double mb)
	{

	CLHEP::HepLorentzVector q1=p1in-p1out; // Top End
	CLHEP::HepLorentzVector q2=-(p2in-p2out-pg); // Extra bit pre-gluon
	CLHEP::HepLorentzVector q3=-(p2in-p2out); // Bottom End

	// std::cerr<<"Current: "<<q1.m2()<<" "<<q2.m2()<<std::endl;
	CCurrent mjH1m,mjH1p,mj2m,mj2p;
	mjH1p=jioHtop(p1in,true,p1out,true,qH1,qH2, mt, incBot, mb);
	mjH1m=jioHtop(p1in,false,p1out,false,qH1,qH2, mt, incBot, mb);
	mj2p=joi(p2out,true,p2in,true);
	mj2m=joi(p2out,false,p2in,false);

	// Dot products of these which occur again and again
	COM MHmp=mjH1m.dot(mj2p); // And now for the Higgs ones
	COM MHmm=mjH1m.dot(mj2m);
	COM MHpp=mjH1p.dot(mj2p);
	COM MHpm=mjH1p.dot(mj2m);


	// Currents with pg
	CCurrent jgbm,jgbp,j2gm,j2gp;
	j2gp=joo(p2out,true,pg,true);
	j2gm=joo(p2out,false,pg,false);
	jgbp=joi(pg,true,p2in,true);
	jgbm=joi(pg,false,p2in,false);

	CCurrent qsum(q2+q3);

	CCurrent Lmp,Lmm,Lpp,Lpm,U1mp,U1mm,U1pp,U1pm,U2mp,U2mm,U2pp,U2pm,p1o(p1out),p1i(p1in);
	CCurrent p2o(p2out);
	CCurrent p2i(p2in);

	CCurrent pplus((p1in+p1out)/2.);
	CCurrent pminus((p2in+p2out)/2.);

	// COM test=pminus.dot(p1in);


	Lmm=((-1.)qsum(MHmm) + (-2.mjH1m.dot(pg))mj2m+2.mj2m.dot(pg)mjH1m+(p1o/pg.dot(p1out) + p1i/pg.dot(p1in))(q2.m2()MHmm/2.))/q3.m2();
	Lmp=((-1.)qsum(MHmp) + (-2.mjH1m.dot(pg))mj2p+2.mj2p.dot(pg)mjH1m+(p1o/pg.dot(p1out) + p1i/pg.dot(p1in))(q2.m2()MHmp/2.))/q3.m2();
	Lpm=((-1.)qsum(MHpm) + (-2.mjH1p.dot(pg))mj2m+2.mj2m.dot(pg)mjH1p+(p1o/pg.dot(p1out) + p1i/pg.dot(p1in))(q2.m2()MHpm/2.))/q3.m2();
	Lpp=((-1.)qsum(MHpp) + (-2.mjH1p.dot(pg))mj2p+2.mj2p.dot(pg)mjH1p+(p1o/pg.dot(p1out) + p1i/pg.dot(p1in))(q2.m2()MHpp/2.))/q3.m2();
	U1mm=(jgbm.dot(mjH1m)j2gm+2.p2o*MHmm)/(p2out+pg).m2();
	U1mp=(jgbp.dot(mjH1m)j2gp+2.p2o*MHmp)/(p2out+pg).m2();
	U1pm=(jgbm.dot(mjH1p)j2gm+2.p2o*MHpm)/(p2out+pg).m2();
	U1pp=(jgbp.dot(mjH1p)j2gp+2.p2o*MHpp)/(p2out+pg).m2();
	U2mm=((-1.)j2gm.dot(mjH1m)jgbm+2.p2iMHmm)/(p2in-pg).m2();
	U2mp=((-1.)j2gp.dot(mjH1m)jgbp+2.p2iMHmp)/(p2in-pg).m2();
	U2pm=((-1.)j2gm.dot(mjH1p)jgbm+2.p2iMHpm)/(p2in-pg).m2();
	U2pp=((-1.)j2gp.dot(mjH1p)jgbp+2.p2iMHpp)/(p2in-pg).m2();

	const double cf=HEJ::C_F;
	double amm,amp,apm,app;

	amm=cf(2.vre(Lmm-U1mm,Lmm+U2mm))+2.cfcf/3.*vabs2(U1mm+U2mm);
	amp=cf(2.vre(Lmp-U1mp,Lmp+U2mp))+2.cfcf/3.*vabs2(U1mp+U2mp);
	apm=cf(2.vre(Lpm-U1pm,Lpm+U2pm))+2.cfcf/3.*vabs2(U1pm+U2pm);
	app=cf(2.vre(Lpp-U1pp,Lpp+U2pp))+2.cfcf/3.*vabs2(U1pp+U2pp);
	double ampsq=-(amm+amp+apm+app)/(q1.m2()*qH1.m2());

	// if ((vabs2(Lmm-U1mm+U2mm)+vabs2(Lmm)-vabs2(U1mm)-vabs2(U2mm))/(2*vre(Lmm-U1mm,Lmm+U2mm)) > 1.0000001)
	// std::cout << " Big Problem!! " << vabs2(Lmm-U1mm+U2mm)+vabs2(Lmm)-vabs2(U1mm)-vabs2(U2mm) << " " << 2*vre(Lmm-U1mm,Lmm+U2mm) << std::endl;
	// if ((vabs2(Lmm-U1mm+U2mm)+vabs2(Lmm)-vabs2(U1mm)-vabs2(U2mm))/(2*vre(Lmm-U1mm,Lmm+U2mm)) < 0.9999999)
	// std::cout << " Big Problem!! " << vabs2(Lmm-U1mm+U2mm)+vabs2(Lmm)-vabs2(U1mm)-vabs2(U2mm) << " " << 2*vre(Lmm-U1mm,Lmm+U2mm) << std::endl;

	// Now add the t-channels for the Higgs
	double th=qH2.m2()*q2.m2();
	ampsq/=th;
	ampsq/=16.;
	ampsq=4.4./(9.*9.); // Factor of (Cf/Ca) for each quark to match MH2qQ.
	//Higgs coupling is included in Hjets.C

	return ampsq;
	}



	double jM2unobqHQbarg (CLHEP::HepLorentzVector p1out, CLHEP::HepLorentzVector p1in, CLHEP::HepLorentzVector pg, CLHEP::HepLorentzVector p2out, CLHEP::HepLorentzVector p2in, CLHEP::HepLorentzVector qH1, CLHEP::HepLorentzVector qH2, double mt, bool incBot, double mb)
	{

	CLHEP::HepLorentzVector q1=p1in-p1out; // Top End
	CLHEP::HepLorentzVector q2=-(p2in-p2out-pg); // Extra bit pre-gluon
	CLHEP::HepLorentzVector q3=-(p2in-p2out); // Bottom End

	// std::cerr<<"Current: "<<q1.m2()<<" "<<q2.m2()<<std::endl;
	CCurrent mjH1m,mjH1p,mj2m,mj2p;
	mjH1p=jHtop(p1out,true,p1in,true,qH1,qH2,mt, incBot, mb);
	mjH1m=jHtop(p1out,false,p1in,false,qH1,qH2,mt, incBot, mb);
	mj2p=jio(p2in,true,p2out,true);
	mj2m=jio(p2in,false,p2out,false);

	// Dot products of these which occur again and again
	COM MHmp=mjH1m.dot(mj2p); // And now for the Higgs ones
	COM MHmm=mjH1m.dot(mj2m);
	COM MHpp=mjH1p.dot(mj2p);
	COM MHpm=mjH1p.dot(mj2m);


	// Currents with pg
	CCurrent jgbm,jgbp,j2gm,j2gp;
	j2gp=joo(pg,true,p2out,true);
	j2gm=joo(pg,false,p2out,false);
	jgbp=jio(p2in,true,pg,true);
	jgbm=jio(p2in,false,pg,false);

	CCurrent qsum(q2+q3);

	CCurrent Lmp,Lmm,Lpp,Lpm,U1mp,U1mm,U1pp,U1pm,U2mp,U2mm,U2pp,U2pm,p1o(p1out),p1i(p1in);
	CCurrent p2o(p2out);
	CCurrent p2i(p2in);

	CCurrent pplus((p1in+p1out)/2.);
	CCurrent pminus((p2in+p2out)/2.);

	// COM test=pminus.dot(p1in);


	Lmm=((-1.)qsum(MHmm) + (-2.mjH1m.dot(pg))mj2m+2.mj2m.dot(pg)mjH1m+(p1o/pg.dot(p1out) + p1i/pg.dot(p1in))(q2.m2()MHmm/2.))/q3.m2();
	Lmp=((-1.)qsum(MHmp) + (-2.mjH1m.dot(pg))mj2p+2.mj2p.dot(pg)mjH1m+(p1o/pg.dot(p1out) + p1i/pg.dot(p1in))(q2.m2()MHmp/2.))/q3.m2();
	Lpm=((-1.)qsum(MHpm) + (-2.mjH1p.dot(pg))mj2m+2.mj2m.dot(pg)mjH1p+(p1o/pg.dot(p1out) + p1i/pg.dot(p1in))(q2.m2()MHpm/2.))/q3.m2();
	Lpp=((-1.)qsum(MHpp) + (-2.mjH1p.dot(pg))mj2p+2.mj2p.dot(pg)mjH1p+(p1o/pg.dot(p1out) + p1i/pg.dot(p1in))(q2.m2()MHpp/2.))/q3.m2();
	U1mm=(jgbm.dot(mjH1m)j2gm+2.p2o*MHmm)/(p2out+pg).m2();
	U1mp=(jgbp.dot(mjH1m)j2gp+2.p2o*MHmp)/(p2out+pg).m2();
	U1pm=(jgbm.dot(mjH1p)j2gm+2.p2o*MHpm)/(p2out+pg).m2();
	U1pp=(jgbp.dot(mjH1p)j2gp+2.p2o*MHpp)/(p2out+pg).m2();
	U2mm=((-1.)j2gm.dot(mjH1m)jgbm+2.p2iMHmm)/(p2in-pg).m2();
	U2mp=((-1.)j2gp.dot(mjH1m)jgbp+2.p2iMHmp)/(p2in-pg).m2();
	U2pm=((-1.)j2gm.dot(mjH1p)jgbm+2.p2iMHpm)/(p2in-pg).m2();
	U2pp=((-1.)j2gp.dot(mjH1p)jgbp+2.p2iMHpp)/(p2in-pg).m2();

	const double cf=HEJ::C_F;
	double amm,amp,apm,app;

	amm=cf(2.vre(Lmm-U1mm,Lmm+U2mm))+2.cfcf/3.*vabs2(U1mm+U2mm);
	amp=cf(2.vre(Lmp-U1mp,Lmp+U2mp))+2.cfcf/3.*vabs2(U1mp+U2mp);
	apm=cf(2.vre(Lpm-U1pm,Lpm+U2pm))+2.cfcf/3.*vabs2(U1pm+U2pm);
	app=cf(2.vre(Lpp-U1pp,Lpp+U2pp))+2.cfcf/3.*vabs2(U1pp+U2pp);
	double ampsq=-(amm+amp+apm+app)/(q1.m2()*qH1.m2());

	// if ((vabs2(Lmm-U1mm+U2mm)+vabs2(Lmm)-vabs2(U1mm)-vabs2(U2mm))/(2*vre(Lmm-U1mm,Lmm+U2mm)) > 1.0000001)
	// std::cout << " Big Problem!! " << vabs2(Lmm-U1mm+U2mm)+vabs2(Lmm)-vabs2(U1mm)-vabs2(U2mm) << " " << 2*vre(Lmm-U1mm,Lmm+U2mm) << std::endl;
	// if ((vabs2(Lmm-U1mm+U2mm)+vabs2(Lmm)-vabs2(U1mm)-vabs2(U2mm))/(2*vre(Lmm-U1mm,Lmm+U2mm)) < 0.9999999)
	// std::cout << " Big Problem!! " << vabs2(Lmm-U1mm+U2mm)+vabs2(Lmm)-vabs2(U1mm)-vabs2(U2mm) << " " << 2*vre(Lmm-U1mm,Lmm+U2mm) << std::endl;

	// Now add the t-channels for the Higgs
	double th=qH2.m2()*q2.m2();
	ampsq/=th;
	ampsq/=16.;
	ampsq=4.4./(9.*9.); // Factor of (Cf/Ca) for each quark to match MH2qQ.
	//Higgs coupling is included in Hjets.C

	return ampsq;
	}



	double jM2unobqbarHQbarg (CLHEP::HepLorentzVector p1out, CLHEP::HepLorentzVector p1in, CLHEP::HepLorentzVector pg, CLHEP::HepLorentzVector p2out, CLHEP::HepLorentzVector p2in, CLHEP::HepLorentzVector qH1, CLHEP::HepLorentzVector qH2, double mt, bool incBot, double mb)
	{

	CLHEP::HepLorentzVector q1=p1in-p1out; // Top End
	CLHEP::HepLorentzVector q2=-(p2in-p2out-pg); // Extra bit pre-gluon
	CLHEP::HepLorentzVector q3=-(p2in-p2out); // Bottom End

	// std::cerr<<"Current: "<<q1.m2()<<" "<<q2.m2()<<std::endl;
	CCurrent mjH1m,mjH1p,mj2m,mj2p;
	mjH1p=jioHtop(p1in,true,p1out,true,qH1,qH2,mt, incBot, mb);
	mjH1m=jioHtop(p1in,false,p1out,false,qH1,qH2,mt, incBot, mb);
	mj2p=jio(p2in,true,p2out,true);
	mj2m=jio(p2in,false,p2out,false);

	// Dot products of these which occur again and again
	COM MHmp=mjH1m.dot(mj2p); // And now for the Higgs ones
	COM MHmm=mjH1m.dot(mj2m);
	COM MHpp=mjH1p.dot(mj2p);
	COM MHpm=mjH1p.dot(mj2m);


	// Currents with pg
	CCurrent jgbm,jgbp,j2gm,j2gp;
	j2gp=joo(pg,true,p2out,true);
	j2gm=joo(pg,false,p2out,false);
	jgbp=jio(p2in,true,pg,true);
	jgbm=jio(p2in,false,pg,false);

	CCurrent qsum(q2+q3);

	CCurrent Lmp,Lmm,Lpp,Lpm,U1mp,U1mm,U1pp,U1pm,U2mp,U2mm,U2pp,U2pm,p1o(p1out),p1i(p1in);
	CCurrent p2o(p2out);
	CCurrent p2i(p2in);

	CCurrent pplus((p1in+p1out)/2.);
	CCurrent pminus((p2in+p2out)/2.);

	// COM test=pminus.dot(p1in);


	Lmm=((-1.)qsum(MHmm) + (-2.mjH1m.dot(pg))mj2m+2.mj2m.dot(pg)mjH1m+(p1o/pg.dot(p1out) + p1i/pg.dot(p1in))(q2.m2()MHmm/2.))/q3.m2();
	Lmp=((-1.)qsum(MHmp) + (-2.mjH1m.dot(pg))mj2p+2.mj2p.dot(pg)mjH1m+(p1o/pg.dot(p1out) + p1i/pg.dot(p1in))(q2.m2()MHmp/2.))/q3.m2();
	Lpm=((-1.)qsum(MHpm) + (-2.mjH1p.dot(pg))mj2m+2.mj2m.dot(pg)mjH1p+(p1o/pg.dot(p1out) + p1i/pg.dot(p1in))(q2.m2()MHpm/2.))/q3.m2();
	Lpp=((-1.)qsum(MHpp) + (-2.mjH1p.dot(pg))mj2p+2.mj2p.dot(pg)mjH1p+(p1o/pg.dot(p1out) + p1i/pg.dot(p1in))(q2.m2()MHpp/2.))/q3.m2();
	U1mm=(jgbm.dot(mjH1m)j2gm+2.p2o*MHmm)/(p2out+pg).m2();
	U1mp=(jgbp.dot(mjH1m)j2gp+2.p2o*MHmp)/(p2out+pg).m2();
	U1pm=(jgbm.dot(mjH1p)j2gm+2.p2o*MHpm)/(p2out+pg).m2();
	U1pp=(jgbp.dot(mjH1p)j2gp+2.p2o*MHpp)/(p2out+pg).m2();
	U2mm=((-1.)j2gm.dot(mjH1m)jgbm+2.p2iMHmm)/(p2in-pg).m2();
	U2mp=((-1.)j2gp.dot(mjH1m)jgbp+2.p2iMHmp)/(p2in-pg).m2();
	U2pm=((-1.)j2gm.dot(mjH1p)jgbm+2.p2iMHpm)/(p2in-pg).m2();
	U2pp=((-1.)j2gp.dot(mjH1p)jgbp+2.p2iMHpp)/(p2in-pg).m2();

	const double cf=HEJ::C_F;
	double amm,amp,apm,app;

	amm=cf(2.vre(Lmm-U1mm,Lmm+U2mm))+2.cfcf/3.*vabs2(U1mm+U2mm);
	amp=cf(2.vre(Lmp-U1mp,Lmp+U2mp))+2.cfcf/3.*vabs2(U1mp+U2mp);
	apm=cf(2.vre(Lpm-U1pm,Lpm+U2pm))+2.cfcf/3.*vabs2(U1pm+U2pm);
	app=cf(2.vre(Lpp-U1pp,Lpp+U2pp))+2.cfcf/3.*vabs2(U1pp+U2pp);
	double ampsq=-(amm+amp+apm+app)/(q1.m2()*qH1.m2());

	// if ((vabs2(Lmm-U1mm+U2mm)+vabs2(Lmm)-vabs2(U1mm)-vabs2(U2mm))/(2*vre(Lmm-U1mm,Lmm+U2mm)) > 1.0000001)
	// std::cout << " Big Problem!! " << vabs2(Lmm-U1mm+U2mm)+vabs2(Lmm)-vabs2(U1mm)-vabs2(U2mm) << " " << 2*vre(Lmm-U1mm,Lmm+U2mm) << std::endl;
	// if ((vabs2(Lmm-U1mm+U2mm)+vabs2(Lmm)-vabs2(U1mm)-vabs2(U2mm))/(2*vre(Lmm-U1mm,Lmm+U2mm)) < 0.9999999)
	// std::cout << " Big Problem!! " << vabs2(Lmm-U1mm+U2mm)+vabs2(Lmm)-vabs2(U1mm)-vabs2(U2mm) << " " << 2*vre(Lmm-U1mm,Lmm+U2mm) << std::endl;

	// Now add the t-channels for the Higgs
	double th=qH2.m2()*q2.m2();
	ampsq/=th;
	ampsq/=16.;
	ampsq=4.4./(9.*9.); // Factor of (Cf/Ca) for each quark to match MH2qQ.
	//Higgs coupling is included in Hjets.C



	return ampsq;
	}

	double jM2unobgHQg (CLHEP::HepLorentzVector p1out, CLHEP::HepLorentzVector p1in, CLHEP::HepLorentzVector pg, CLHEP::HepLorentzVector p2out, CLHEP::HepLorentzVector p2in, CLHEP::HepLorentzVector qH1, CLHEP::HepLorentzVector qH2, double mt, bool incBot, double mb)
	{
	// std::cout << "####################\n";
	// std::cout << "# p1in : "<<p1in<< " "<<p1in.plus()<<" "<<p1in.minus()<<std::endl;
	// std::cout << "# p2in : "<<p2in<< " "<<p2in.plus()<<" "<<p2in.minus()<<std::endl;
	// std::cout << "# p1out : "<<p1out<< " "<<p1out.rapidity()<<std::endl;
	// std::cout << "# (qH1-qH2) : "<<(qH1-qH2)<< " "<<(qH1-qH2).rapidity()<<std::endl;
	// std::cout << "# pg : "<<pg<< " "<<pg.rapidity()<<std::endl;
	// std::cout << "# p2out : "<<p2out<< " "<<p2out.rapidity()<<std::endl;
	// std::cout << "####################\n";

	CLHEP::HepLorentzVector q1=p1in-p1out; // Top End
	CLHEP::HepLorentzVector q2=-(p2in-p2out-pg); // Extra bit pre-gluon
	CLHEP::HepLorentzVector q3=-(p2in-p2out); // Bottom End

	// std::cerr<<"Current: "<<q1.m2()<<" "<<q2.m2()<<std::endl;
	CCurrent mjH1m,mjH1p,mj2m,mj2p;
	mjH1p=jHtop(p1out,true,p1in,true,qH1,qH2,mt, incBot, mb);
	mjH1m=jHtop(p1out,false,p1in,false,qH1,qH2,mt, incBot, mb);
	mj2p=joi(p2out,true,p2in,true);
	mj2m=joi(p2out,false,p2in,false);

	// Dot products of these which occur again and again
	COM MHmp=mjH1m.dot(mj2p); // And now for the Higgs ones
	COM MHmm=mjH1m.dot(mj2m);
	COM MHpp=mjH1p.dot(mj2p);
	COM MHpm=mjH1p.dot(mj2m);

	// Currents with pg
	CCurrent jgbm,jgbp,j2gm,j2gp;
	j2gp=joo(p2out,true,pg,true);
	j2gm=joo(p2out,false,pg,false);
	jgbp=joi(pg,true,p2in,true);
	jgbm=joi(pg,false,p2in,false);

	CCurrent qsum(q2+q3);

	CCurrent Lmp,Lmm,Lpp,Lpm,U1mp,U1mm,U1pp,U1pm,U2mp,U2mm,U2pp,U2pm,p1o(p1out),p1i(p1in);
	CCurrent p2o(p2out);
	CCurrent p2i(p2in);

	CCurrent pplus((p1in+p1out)/2.);
	CCurrent pminus((p2in+p2out)/2.);

	// COM test=pminus.dot(p1in);

	Lmm=((-1.)qsum(MHmm) + (-2.mjH1m.dot(pg))mj2m+2.mj2m.dot(pg)mjH1m+(p1o/pg.dot(p1out) + p1i/pg.dot(p1in))(q2.m2()MHmm/2.))/q3.m2();
	Lmp=((-1.)qsum(MHmp) + (-2.mjH1m.dot(pg))mj2p+2.mj2p.dot(pg)mjH1m+(p1o/pg.dot(p1out) + p1i/pg.dot(p1in))(q2.m2()MHmp/2.))/q3.m2();
	Lpm=((-1.)qsum(MHpm) + (-2.mjH1p.dot(pg))mj2m+2.mj2m.dot(pg)mjH1p+(p1o/pg.dot(p1out) + p1i/pg.dot(p1in))(q2.m2()MHpm/2.))/q3.m2();
	Lpp=((-1.)qsum(MHpp) + (-2.mjH1p.dot(pg))mj2p+2.mj2p.dot(pg)mjH1p+(p1o/pg.dot(p1out) + p1i/pg.dot(p1in))(q2.m2()MHpp/2.))/q3.m2();
	U1mm=(jgbm.dot(mjH1m)j2gm+2.p2o*MHmm)/(p2out+pg).m2();
	U1mp=(jgbp.dot(mjH1m)j2gp+2.p2o*MHmp)/(p2out+pg).m2();
	U1pm=(jgbm.dot(mjH1p)j2gm+2.p2o*MHpm)/(p2out+pg).m2();
	U1pp=(jgbp.dot(mjH1p)j2gp+2.p2o*MHpp)/(p2out+pg).m2();
	U2mm=((-1.)j2gm.dot(mjH1m)jgbm+2.p2iMHmm)/(p2in-pg).m2();
	U2mp=((-1.)j2gp.dot(mjH1m)jgbp+2.p2iMHmp)/(p2in-pg).m2();
	U2pm=((-1.)j2gm.dot(mjH1p)jgbm+2.p2iMHpm)/(p2in-pg).m2();
	U2pp=((-1.)j2gp.dot(mjH1p)jgbp+2.p2iMHpp)/(p2in-pg).m2();

	const double cf=HEJ::C_F;
	double amm,amp,apm,app;

	amm=cf(2.vre(Lmm-U1mm,Lmm+U2mm))+2.cfcf/3.*vabs2(U1mm+U2mm);
	amp=cf(2.vre(Lmp-U1mp,Lmp+U2mp))+2.cfcf/3.*vabs2(U1mp+U2mp);
	apm=cf(2.vre(Lpm-U1pm,Lpm+U2pm))+2.cfcf/3.*vabs2(U1pm+U2pm);
	app=cf(2.vre(Lpp-U1pp,Lpp+U2pp))+2.cfcf/3.*vabs2(U1pp+U2pp);
	double ampsq=-(amm+amp+apm+app)/(q1.m2()*qH1.m2());

	// if ((vabs2(Lmm-U1mm+U2mm)+vabs2(Lmm)-vabs2(U1mm)-vabs2(U2mm))/(2*vre(Lmm-U1mm,Lmm+U2mm)) > 1.0000001)
	// std::cout << " Big Problem!! " << vabs2(Lmm-U1mm+U2mm)+vabs2(Lmm)-vabs2(U1mm)-vabs2(U2mm) << " " << 2*vre(Lmm-U1mm,Lmm+U2mm) << std::endl;
	// if ((vabs2(Lmm-U1mm+U2mm)+vabs2(Lmm)-vabs2(U1mm)-vabs2(U2mm))/(2*vre(Lmm-U1mm,Lmm+U2mm)) < 0.9999999)
	// std::cout << " Big Problem!! " << vabs2(Lmm-U1mm+U2mm)+vabs2(Lmm)-vabs2(U1mm)-vabs2(U2mm) << " " << 2*vre(Lmm-U1mm,Lmm+U2mm) << std::endl;

	// Now add the t-channels for the Higgs
	double th=qH2.m2()*q2.m2();
	ampsq/=th;
	ampsq/=16.;
	ampsq=4./9.4./9.; // Factor of (Cf/Ca) for each quark to match MH2qQ.
	// need twice to match the normalization
	//Higgs coupling is included in Hjets.C

	const double K = K_g(p1out, p1in);

	return ampsq*K/C_F;
	}



	double jM2unobgHQbarg (CLHEP::HepLorentzVector p1out, CLHEP::HepLorentzVector p1in, CLHEP::HepLorentzVector pg, CLHEP::HepLorentzVector p2out, CLHEP::HepLorentzVector p2in, CLHEP::HepLorentzVector qH1, CLHEP::HepLorentzVector qH2, double mt, bool incBot, double mb)
	{

	CLHEP::HepLorentzVector q1=p1in-p1out; // Top End
	CLHEP::HepLorentzVector q2=-(p2in-p2out-pg); // Extra bit pre-gluon
	CLHEP::HepLorentzVector q3=-(p2in-p2out); // Bottom End

	// std::cerr<<"Current: "<<q1.m2()<<" "<<q2.m2()<<std::endl;
	CCurrent mjH1m,mjH1p,mj2m,mj2p;
	mjH1p=jHtop(p1out,true,p1in,true,qH1,qH2,mt, incBot, mb);
	mjH1m=jHtop(p1out,false,p1in,false,qH1,qH2,mt, incBot, mb);
	mj2p=jio(p2in,true,p2out,true);
	mj2m=jio(p2in,false,p2out,false);

	// Dot products of these which occur again and again
	COM MHmp=mjH1m.dot(mj2p); // And now for the Higgs ones
	COM MHmm=mjH1m.dot(mj2m);
	COM MHpp=mjH1p.dot(mj2p);
	COM MHpm=mjH1p.dot(mj2m);


	// Currents with pg
	CCurrent jgbm,jgbp,j2gm,j2gp;
	j2gp=joo(pg,true,p2out,true);
	j2gm=joo(pg,false,p2out,false);
	jgbp=jio(p2in,true,pg,true);
	jgbm=jio(p2in,false,pg,false);

	CCurrent qsum(q2+q3);

	CCurrent Lmp,Lmm,Lpp,Lpm,U1mp,U1mm,U1pp,U1pm,U2mp,U2mm,U2pp,U2pm,p1o(p1out),p1i(p1in);
	CCurrent p2o(p2out);
	CCurrent p2i(p2in);

	CCurrent pplus((p1in+p1out)/2.);
	CCurrent pminus((p2in+p2out)/2.);

	// COM test=pminus.dot(p1in);


	Lmm=((-1.)qsum(MHmm) + (-2.mjH1m.dot(pg))mj2m+2.mj2m.dot(pg)mjH1m+(p1o/pg.dot(p1out) + p1i/pg.dot(p1in))(q2.m2()MHmm/2.))/q3.m2();
	Lmp=((-1.)qsum(MHmp) + (-2.mjH1m.dot(pg))mj2p+2.mj2p.dot(pg)mjH1m+(p1o/pg.dot(p1out) + p1i/pg.dot(p1in))(q2.m2()MHmp/2.))/q3.m2();
	Lpm=((-1.)qsum(MHpm) + (-2.mjH1p.dot(pg))mj2m+2.mj2m.dot(pg)mjH1p+(p1o/pg.dot(p1out) + p1i/pg.dot(p1in))(q2.m2()MHpm/2.))/q3.m2();
	Lpp=((-1.)qsum(MHpp) + (-2.mjH1p.dot(pg))mj2p+2.mj2p.dot(pg)mjH1p+(p1o/pg.dot(p1out) + p1i/pg.dot(p1in))(q2.m2()MHpp/2.))/q3.m2();
	U1mm=(jgbm.dot(mjH1m)j2gm+2.p2o*MHmm)/(p2out+pg).m2();
	U1mp=(jgbp.dot(mjH1m)j2gp+2.p2o*MHmp)/(p2out+pg).m2();
	U1pm=(jgbm.dot(mjH1p)j2gm+2.p2o*MHpm)/(p2out+pg).m2();
	U1pp=(jgbp.dot(mjH1p)j2gp+2.p2o*MHpp)/(p2out+pg).m2();
	U2mm=((-1.)j2gm.dot(mjH1m)jgbm+2.p2iMHmm)/(p2in-pg).m2();
	U2mp=((-1.)j2gp.dot(mjH1m)jgbp+2.p2iMHmp)/(p2in-pg).m2();
	U2pm=((-1.)j2gm.dot(mjH1p)jgbm+2.p2iMHpm)/(p2in-pg).m2();
	U2pp=((-1.)j2gp.dot(mjH1p)jgbp+2.p2iMHpp)/(p2in-pg).m2();

	const double cf=HEJ::C_F;
	double amm,amp,apm,app;

	amm=cf(2.vre(Lmm-U1mm,Lmm+U2mm))+2.cfcf/3.*vabs2(U1mm+U2mm);
	amp=cf(2.vre(Lmp-U1mp,Lmp+U2mp))+2.cfcf/3.*vabs2(U1mp+U2mp);
	apm=cf(2.vre(Lpm-U1pm,Lpm+U2pm))+2.cfcf/3.*vabs2(U1pm+U2pm);
	app=cf(2.vre(Lpp-U1pp,Lpp+U2pp))+2.cfcf/3.*vabs2(U1pp+U2pp);
	double ampsq=-(amm+amp+apm+app)/(q1.m2()*qH1.m2());

	// if ((vabs2(Lmm-U1mm+U2mm)+vabs2(Lmm)-vabs2(U1mm)-vabs2(U2mm))/(2*vre(Lmm-U1mm,Lmm+U2mm)) > 1.0000001)
	// std::cout << " Big Problem!! " << vabs2(Lmm-U1mm+U2mm)+vabs2(Lmm)-vabs2(U1mm)-vabs2(U2mm) << " " << 2*vre(Lmm-U1mm,Lmm+U2mm) << std::endl;
	// if ((vabs2(Lmm-U1mm+U2mm)+vabs2(Lmm)-vabs2(U1mm)-vabs2(U2mm))/(2*vre(Lmm-U1mm,Lmm+U2mm)) < 0.9999999)
	// std::cout << " Big Problem!! " << vabs2(Lmm-U1mm+U2mm)+vabs2(Lmm)-vabs2(U1mm)-vabs2(U2mm) << " " << 2*vre(Lmm-U1mm,Lmm+U2mm) << std::endl;

	// Now add the t-channels for the Higgs
	double th=qH2.m2()*q2.m2();
	ampsq/=th;
	ampsq/=16.;
	ampsq=4./9.4./9.; // Factor of (Cf/Ca) for each quark to match MH2qQ.
	//Higgs coupling is included in Hjets.C

	const double K = K_g(p1out, p1in);

	return ampsq*K/C_F; //ca/cf = 9/4

	}

	// Begin finite mass stuff
	#ifdef HEJ_BUILD_WITH_QCDLOOP
	namespace {


	// All the stuff needed for the box functions in qg->qgH now...

	//COM E1(CLHEP::HepLorentzVector k1, CLHEP::HepLorentzVector k2, CLHEP::HepLorentzVector k3, CLHEP::HepLorentzVector k4, double mq)
	COM E1(CLHEP::HepLorentzVector k1, CLHEP::HepLorentzVector k2, CLHEP::HepLorentzVector kh, double mq)
	{
	//CLHEP::HepLorentzVector q2=k3+k4;
	CLHEP::HepLorentzVector q2=-(k1+k2+kh);
	double Delta, Sigma, S1, S2, s12, s34;
	S1 = 2.*k1.dot(q2);
	S2 = 2.*k2.dot(q2);
	s12 = 2.*k1.dot(k2);
	//s34 = 2.*k3.dot(k4);
	s34 = q2.m2();
	Delta = s12s34 - S1S2;
	Sigma = 4.s12s34 - pow(S1+S2,2);

	return looprwfactor(-s12D0DD(k2, k1, q2, mq)(1 - 8.mqmq/s12 + S2/(2.s12) +
	S2(s12 - 8.mqmq)(s34 + S1)/(2.s12Delta) +
	2.(s34 + S1)(s34 + S1)/Delta +
	S2pow((s34 + S1),3)/Delta/Delta) - ((s12 + S2)C0DD(k2,
	k1 + q2, mq) -
	s12C0DD(k1, k2, mq) + (S1 - S2)C0DD(k1 + k2, q2, mq) -
	S1*C0DD(k1, q2,
	mq))(S2(s12 - 4.mqmq)/(2.s12Delta) +
	2.*(s34 + S1)/Delta +
	S2*pow((s34 + S1),2)/Delta/Delta) + (C0DD(k1, q2, mq) -
	C0DD(k1 + k2, q2, mq))(1. - 4.mq*mq/s12) -
	C0DD(k1 + k2, q2, mq)2.s34/
	S1 - (B0DD(k1 + q2, mq) -
	B0DD(k1 + k2 + q2, mq))2.s34*(s34 +
	S1)/(S1*Delta) + (B0DD(q2, mq) -
	B0DD(k1 + k2 + q2, mq) +
	s12*C0DD(k1 + k2, q2,
	mq))(2.s34*(s34 +
	S1)(S1 - S2)/(DeltaSigma) +
	2.s34(s34 + S1)/(S1*Delta)) + (B0DD(k1 + k2, mq) -
	B0DD(k1 + k2 + q2,
	mq) - (s34 + S1 + S2)C0DD(k1 + k2, q2, mq))2.*(s34 +
	S1)(2.s12*s34 -
	S2(S1 + S2))/(DeltaSigma));
	}
	//COM F1(CLHEP::HepLorentzVector k1, CLHEP::HepLorentzVector k2, CLHEP::HepLorentzVector k3, CLHEP::HepLorentzVector k4, double mq)
	COM F1(CLHEP::HepLorentzVector k1, CLHEP::HepLorentzVector k2, CLHEP::HepLorentzVector kh, double mq)
	{
	//CLHEP::HepLorentzVector q2=k3+k4;
	CLHEP::HepLorentzVector q2 = -(k1+k2+kh);
	double Delta, Sigma, S1, S2, s12, s34;
	S1 = 2.*k1.dot(q2);
	S2 = 2.*k2.dot(q2);
	s12 = 2.*k1.dot(k2);
	//s34 = 2.*k3.dot(k4);
	s34 = q2.m2();
	Delta = s12s34 - S1S2;
	Sigma = 4.s12s34 - pow(S1+S2,2);

	return looprwfactor(-S2D0DD(k1, k2, q2,
	mq)(0.5 - (s12 - 8.mqmq)(s34 + S2)/(2.*Delta) -
	s12pow((s34 + S2),3)/Delta/Delta) + ((s12 + S1)C0DD(k1,
	k2 + q2, mq) -
	s12C0DD(k1, k2, mq) - (S1 - S2)C0DD(k1 + k2, q2, mq) -
	S2*C0DD(k2, q2,
	mq))(S2(s12 - 4.mqmq)/(2.s12Delta) +
	S2pow((s34 + S2),2)/Delta/Delta) - (C0DD(k1 + k2, q2, mq) - C0DD(k1, k2 + q2, mq))(1. - 4.mqmq/s12) -
	C0DD(k1, k2 + q2, mq) + (B0DD(k2 + q2, mq) -
	B0DD(k1 + k2 + q2,
	mq))2.pow((s34 + S2),2)/((s12 + S1)*Delta) - (B0DD(
	q2, mq) - B0DD(k1 + k2 + q2, mq) +
	s12C0DD(k1 + k2, q2, mq))2.s34(s34 +
	S2)(S2 - S1)/(DeltaSigma) + (B0DD(
	k1 + k2, mq) -
	B0DD(k1 + k2 + q2,
	mq) - (s34 + S1 + S2)C0DD(k1 + k2, q2, mq))2.*(s34 +
	S2)(2.s12*s34 -
	S2(S1 + S2))/(DeltaSigma));
	}
	//COM G1(CLHEP::HepLorentzVector k1, CLHEP::HepLorentzVector k2, CLHEP::HepLorentzVector k3, CLHEP::HepLorentzVector k4, double mq)
	COM G1(CLHEP::HepLorentzVector k1, CLHEP::HepLorentzVector k2, CLHEP::HepLorentzVector kh, double mq)
	{
	//CLHEP::HepLorentzVector q2=k3+k4;
	CLHEP::HepLorentzVector q2 = -(k1+k2+kh);
	double Delta, S1, S2, s12, s34;
	S1 = 2.*k1.dot(q2);
	S2 = 2.*k2.dot(q2);
	s12 = 2.*k1.dot(k2);
	//s34 = 2.*k3.dot(k4);
	s34 = q2.m2();
	Delta = s12s34 - S1S2;

	return looprwfactor(S2D0DD(k1, q2, k2,
	mq)(Delta/s12/s12 - 4.mq*mq/s12) -
	S2((s12 + S1)C0DD(k1, k2 + q2, mq) -
	S1C0DD(k1, q2, mq))(1./
	s12/s12 - (s12 - 4.mqmq)/(2.s12Delta)) -
	S2((s12 + S2)C0DD(k1 + q2, k2, mq) -
	S2C0DD(k2, q2, mq))(1./
	s12/s12 + (s12 - 4.mqmq)/(2.s12Delta)) -
	C0DD(k1, q2, mq) - (C0DD(k1, k2 + q2, mq) -
	C0DD(k1, q2, mq))4.mq*mq/
	s12 + (B0DD(k1 + q2, mq) - B0DD(k1 + k2 + q2, mq))*2./
	s12 + (B0DD(k1 + q2, mq) -
	B0DD(q2, mq))2.s34/(s12*S1) + (B0DD(k2 + q2, mq) -
	B0DD(k1 + k2 + q2, mq))2.(s34 + S2)/(s12*(s12 + S1)));
	}
	//COM E4(CLHEP::HepLorentzVector k1, CLHEP::HepLorentzVector k2, CLHEP::HepLorentzVector k3, CLHEP::HepLorentzVector k4, double mq)
	COM E4(CLHEP::HepLorentzVector k1, CLHEP::HepLorentzVector k2, CLHEP::HepLorentzVector kh, double mq)
	{
	//CLHEP::HepLorentzVector q2=k3+k4;
	CLHEP::HepLorentzVector q2 = -(k1+k2+kh);
	double Delta, Sigma, S1, S2, s12, s34;
	S1 = 2.*k1.dot(q2);
	S2 = 2.*k2.dot(q2);
	s12 = 2.*k1.dot(k2);
	//s34 = 2.*k3.dot(k4);
	s34 = q2.m2();
	Delta = s12s34 - S1S2;
	Sigma = 4.s12s34 - pow(S1+S2,2);

	return looprwfactor* (-s12*D0DD(k2, k1, q2,
	mq)(0.5 - (S1 - 8.mqmq)(s34 + S1)/(2.*Delta) -
	s12pow((s34 + S1),3)/Delta/Delta) + ((s12 + S2)C0DD(k2,
	k1 + q2, mq) -
	s12C0DD(k1, k2, mq) + (S1 - S2)C0DD(k1 + k2, q2, mq) -
	S1C0DD(k1, q2, mq))((S1 - 4.mqmq)/(2.*Delta) +
	s12*pow((s34 + S1),2)/Delta/Delta) -
	C0DD(k1 + k2, q2, mq) + (B0DD(k1 + q2, mq) -
	B0DD(k1 + k2 + q2, mq))(2.s34/Delta +
	2.s12(s34 + S1)/((s12 + S2)*Delta)) - (B0DD(
	q2, mq) - B0DD(k1 + k2 + q2, mq) +
	s12*C0DD(k1 + k2, q2,
	mq))((2.s34(2.s12s34 - S2(S1 + S2) +
	s12*(S1 -
	S2)))/(Delta*Sigma)) + (B0DD(k1 + k2, mq) -
	B0DD(k1 + k2 + q2, mq) - (s34 + S1 + S2)C0DD(k1 + k2, q2, mq))((2.s12(2.s12s34 - S1*(S1 + S2) +
	s34(S2 - S1)))/(DeltaSigma)));
	}
	//COM F4(CLHEP::HepLorentzVector k1, CLHEP::HepLorentzVector k2, CLHEP::HepLorentzVector k3, CLHEP::HepLorentzVector k4, double mq)
	COM F4(CLHEP::HepLorentzVector k1, CLHEP::HepLorentzVector k2, CLHEP::HepLorentzVector kh, double mq)
	{
	//CLHEP::HepLorentzVector q2=k3+k4;
	CLHEP::HepLorentzVector q2 = -(k1+k2+kh);
	double Delta, Sigma, S1, S2, s12, s34;
	S1 = 2.*k1.dot(q2);
	S2 = 2.*k2.dot(q2);
	s12 = 2.*k1.dot(k2);
	//s34 = 2.*k3.dot(k4);
	s34 = q2.m2();
	Delta = s12s34 - S1S2;
	Sigma = 4.s12s34 - pow(S1+S2,2);

	return looprwfactor* (-s12*D0DD(k1, k2, q2,
	mq)(0.5 + (S1 - 8.mqmq)(s34 + S2)/(2.*Delta) +
	s12pow((s34 + S2),3)/Delta/Delta) - ((s12 + S1)C0DD(k1,
	k2 + q2, mq) -
	s12C0DD(k1, k2, mq) - (S1 - S2)C0DD(k1 + k2, q2, mq) -
	S2C0DD(k2, q2, mq))((S1 - 4.mqmq)/(2.*Delta) +
	s12*pow((s34 + S2),2)/Delta/Delta) -
	C0DD(k1 + k2, q2, mq) - (B0DD(k2 + q2, mq) -
	B0DD(k1 + k2 + q2, mq))2.(s34 +
	S2)/Delta + (B0DD(q2, mq) -
	B0DD(k1 + k2 + q2, mq) +
	s12C0DD(k1 + k2, q2, mq))2.s34(2.s12s34 -
	S1*(S1 + S2) +
	s12(S2 - S1))/(DeltaSigma) - (B0DD(k1 + k2, mq) -
	B0DD(k1 + k2 + q2, mq) - (s34 + S1 + S2)C0DD(k1 + k2, q2, mq))(2.s12(2.s12s34 - S2*(S1 + S2) +
	s34(S1 - S2))/(DeltaSigma)));
	}
	//COM G4(CLHEP::HepLorentzVector k1, CLHEP::HepLorentzVector k2, CLHEP::HepLorentzVector k3, CLHEP::HepLorentzVector k4, double mq)
	COM G4(CLHEP::HepLorentzVector k1, CLHEP::HepLorentzVector k2, CLHEP::HepLorentzVector kh, double mq)
	{
	//CLHEP::HepLorentzVector q2=k3+k4;
	CLHEP::HepLorentzVector q2 = -(k1+k2+kh);
	double Delta, S1, S2, s12, s34;
	S1 = 2.*k1.dot(q2);
	S2 = 2.*k2.dot(q2);
	s12 = 2.*k1.dot(k2);
	//s34 = 2.*k3.dot(k4);
	s34 = q2.m2();
	Delta = s12s34 - S1S2;

	return looprwfactor* (-D0DD(k1, q2, k2,
	mq)*(Delta/s12 + (s12 + S1)/2. -
	4.mqmq) + ((s12 + S1)*C0DD(k1, k2 + q2, mq) -
	S1C0DD(k1, q2, mq))(1./
	s12 - (S1 - 4.mqmq)/(2.Delta)) + ((s12 + S2)C0DD(
	k1 + q2, k2, mq) -
	S2C0DD(k2, q2, mq))(1./
	s12 + (S1 - 4.mqmq)/(2.*Delta)) + (B0DD(
	k1 + k2 + q2, mq) -
	B0DD(k1 + q2, mq))*2./(s12 + S2));
	}
	//COM E10(CLHEP::HepLorentzVector k1, CLHEP::HepLorentzVector k2, CLHEP::HepLorentzVector k3, CLHEP::HepLorentzVector k4, double mq)
	COM E10(CLHEP::HepLorentzVector k1, CLHEP::HepLorentzVector k2, CLHEP::HepLorentzVector kh, double mq)
	{
	//CLHEP::HepLorentzVector q2=k3+k4;
	CLHEP::HepLorentzVector q2 = -(k1+k2+kh);
	double Delta, Sigma, S1, S2, s12, s34;
	S1 = 2.*k1.dot(q2);
	S2 = 2.*k2.dot(q2);
	s12 = 2.*k1.dot(k2);
	//s34 = 2.*k3.dot(k4);
	s34 = q2.m2();
	Delta = s12s34 - S1S2;
	Sigma = 4.s12s34 - pow(S1+S2,2);

	return looprwfactor(-s12D0DD(k2, k1, q2, mq)*((s34 + S1)/Delta +
	12.mqmqS1(s34 + S1)/Delta/Delta -
	4.s12S1pow((s34 + S1),3)/Delta/Delta/Delta) - ((s12 + S2)C0DD(k2, k1 + q2, mq) -
	s12C0DD(k1, k2, mq) + (S1 - S2)C0DD(k1 + k2, q2, mq) -
	S1C0DD(k1, q2, mq))(1./Delta +
	4.mqmq*S1/Delta/Delta -
	4.s12S1*pow((s34 + S1),2)/Delta/Delta/Delta) +
	C0DD(k1 + k2, q2, mq)(4.s12s34(S1 - S2)/(Delta*Sigma) -
	4.*(s12 -
	2.mqmq)(2.s12*s34 -
	S1(S1 + S2))/(DeltaSigma)) + (B0DD(k1 + q2, mq) -
	B0DD(k1 + k2 + q2, mq))(4.(s34 + S1)/((s12 + S2)*Delta) +
	8.S1(s34 + S1)/Delta/Delta) + (B0DD(q2, mq) -
	B0DD(k1 + k2 + q2, mq) +
	s12C0DD(k1 + k2, q2, mq))(12.s34(2.*s12 + S1 +
	S2)(2.s12*s34 -
	S1(S1 + S2))/(DeltaSigma*Sigma) -
	4.s34(4.s12 + 3.S1 +
	S2)/(Delta*Sigma) +
	8.s12s34(s34(s12 + S2) -
	S1*(s34 +
	S1))/(DeltaDeltaSigma)) + (B0DD(k1 + k2, mq) -
	B0DD(k1 + k2 + q2, mq) - (s34 + S1 + S2)*C0DD(k1 + k2, q2,
	mq))(12.s12(2.s34 + S1 +
	S2)(2.s12*s34 -
	S1(S1 + S2))/(DeltaSigma*Sigma) +
	8.s12S1(s34(s12 + S2) -
	S1*(s34 +
	S1))/(DeltaDeltaSigma))) + (COM(0.,1.)/(4.M_PIM_PI))((2.s12*s34 -
	S1(S1 + S2))/(DeltaSigma));
	}

	//COM F10(CLHEP::HepLorentzVector k1, CLHEP::HepLorentzVector k2, CLHEP::HepLorentzVector k3, CLHEP::HepLorentzVector k4, double mq)
	COM F10(CLHEP::HepLorentzVector k1, CLHEP::HepLorentzVector k2, CLHEP::HepLorentzVector kh, double mq)
	{
	//CLHEP::HepLorentzVector q2=k3+k4;
	CLHEP::HepLorentzVector q2 = -(k1+k2+kh);
	double Delta, Sigma, S1, S2, s12, s34;
	S1 = 2.*k1.dot(q2);
	S2 = 2.*k2.dot(q2);
	s12 = 2.*k1.dot(k2);
	//s34 = 2.*k3.dot(k4);
	s34 = q2.m2();
	Delta = s12s34 - S1S2;
	Sigma = 4.s12s34 - pow(S1+S2,2);

	return looprwfactor* (s12*D0DD(k1, k2, q2,
	mq)((s34 + S2)/Delta - 4.mq*mq/Delta +
	12.mqmqs34(s12 + S1)/Delta/Delta -
	4.s12pow((s34 + S2),2)/Delta/Delta -
	4.s12S1pow((s34 + S2),3)/Delta/Delta/Delta) + ((s12 + S1)C0DD(k1, k2 + q2, mq) -
	s12C0DD(k1, k2, mq) - (S1 - S2)C0DD(k1 + k2, q2, mq) -
	S2C0DD(k2, q2, mq))(1./Delta +
	4.mqmq*S1/Delta/Delta -
	4.s12(s34 + S2)/Delta/Delta -
	4.s12S1*pow((s34 + S2),2)/Delta/Delta/Delta) -
	C0DD(k1 + k2, q2, mq)(4.s12s34/(S2Delta) +
	4.s12s34(S2 - S1)/(DeltaSigma) +
	4.*(s12 -
	2.mqmq)(2.s12*s34 -
	S1(S1 + S2))/(DeltaSigma)) - (B0DD(
	k2 + q2, mq) -
	B0DD(k1 + k2 + q2, mq))(4.s34/(S2*Delta) +
	8.s34(s12 + S1)/Delta/Delta) - (B0DD(q2, mq) -
	B0DD(k1 + k2 + q2, mq) +
	s12*C0DD(k1 + k2, q2,
	mq))(-12s34(2s12 + S1 +
	S2)(2.s12*s34 -
	S1(S1 + S2))/(DeltaSigma*Sigma) -
	4.s12s34s34/(S2Delta*Delta) +
	4.s34S1/(Delta*Sigma) -
	4.s34(s12s34(2.*s12 + S2) -
	S1S1(2.*s12 +
	S1))/(DeltaDeltaSigma)) - (B0DD(k1 + k2, mq) -
	B0DD(k1 + k2 + q2, mq) - (s34 + S1 + S2)C0DD(k1 + k2, q2, mq))(-12.s12(2.*s34 + S1 +
	S2)(2.s12*s34 -
	S1(S1 + S2))/(DeltaSigma*Sigma) +
	8.s12(2.s34 + S1)/(DeltaSigma) -
	8.s12s34(2.s12s34 - S1(S1 + S2) +
	s12*(S2 -
	S1))/(DeltaDeltaSigma))) + (COM(0.,1.)/(4.M_PIM_PI))((2.s12*s34 -
	S1(S1 + S2))/(DeltaSigma));

	}

	//COM G10(CLHEP::HepLorentzVector k1, CLHEP::HepLorentzVector k2, CLHEP::HepLorentzVector k3, CLHEP::HepLorentzVector k4, double mq)
	COM G10(CLHEP::HepLorentzVector k1, CLHEP::HepLorentzVector k2, CLHEP::HepLorentzVector kh, double mq)
	{
	//CLHEP::HepLorentzVector q2=k3+k4;
	CLHEP::HepLorentzVector q2 = -(k1+k2+kh);
	double Delta, S1, S2, s12, s34;
	S1 = 2.*k1.dot(q2);
	S2 = 2.*k2.dot(q2);
	s12 = 2.*k1.dot(k2);
	//s34 = 2.*k3.dot(k4);
	s34 = q2.m2();
	Delta = s12s34 - S1S2;

	return looprwfactor* (-D0DD(k1, q2, k2, mq)*(1. +
	4.S1mqmq/Delta) + ((s12 + S1)C0DD(k1,
	k2 + q2, mq) -
	S1C0DD(k1, q2, mq))(1./Delta +
	4.S1mqmq/Delta/Delta) - ((s12 + S2)C0DD(k1 + q2,
	k2, mq) - S2C0DD(k2, q2, mq))(1./Delta +
	4.S1mq*mq/Delta/Delta) + (B0DD(k1 + k2 + q2, mq) -
	B0DD(k1 + q2, mq))4.(s34 +
	S1)/(Delta*(s12 + S2)) + (B0DD(q2, mq) -
	B0DD(k2 + q2, mq))4.s34/(Delta*S2));
	}

	//COM H1(CLHEP::HepLorentzVector k1, CLHEP::HepLorentzVector k2, CLHEP::HepLorentzVector k3, CLHEP::HepLorentzVector k4, double mq)
	COM H1(CLHEP::HepLorentzVector k1, CLHEP::HepLorentzVector k2, CLHEP::HepLorentzVector kh, double mq)
	{
	//return E1(k1,k2,k3,k4,mq)+F1(k1,k2,k3,k4,mq)+G1(k1,k2,k3,k4,mq);
	return E1(k1,k2,kh,mq)+F1(k1,k2,kh,mq)+G1(k1,k2,kh,mq);
	}
	//COM H4(CLHEP::HepLorentzVector k1, CLHEP::HepLorentzVector k2, CLHEP::HepLorentzVector k3, CLHEP::HepLorentzVector k4, double mq)
	COM H4(CLHEP::HepLorentzVector k1, CLHEP::HepLorentzVector k2, CLHEP::HepLorentzVector kh, double mq)
	{
	//return E4(k1,k2,k3,k4,mq)+F4(k1,k2,k3,k4,mq)+G4(k1,k2,k3,k4,mq);
	return E4(k1,k2,kh,mq)+F4(k1,k2,kh,mq)+G4(k1,k2,kh,mq);
	}
	//COM H10(CLHEP::HepLorentzVector k1, CLHEP::HepLorentzVector k2, CLHEP::HepLorentzVector k3, CLHEP::HepLorentzVector k4, double mq)
	COM H10(CLHEP::HepLorentzVector k1, CLHEP::HepLorentzVector k2, CLHEP::HepLorentzVector kh, double mq)
	{
	//return E10(k1,k2,k3,k4,mq)+F10(k1,k2,k3,k4,mq)+G10(k1,k2,k3,k4,mq);
	return E10(k1,k2,kh,mq)+F10(k1,k2,kh,mq)+G10(k1,k2,kh,mq);
	}
	//COM H2(CLHEP::HepLorentzVector k1, CLHEP::HepLorentzVector k2, CLHEP::HepLorentzVector k3, CLHEP::HepLorentzVector k4, double mq)
	COM H2(CLHEP::HepLorentzVector k1, CLHEP::HepLorentzVector k2, CLHEP::HepLorentzVector kh, double mq)
	{
	//return -1.*H1(k2,k1,k3,k4,mq);
	return -1.*H1(k2,k1,kh,mq);
	}
	//COM H5(CLHEP::HepLorentzVector k1, CLHEP::HepLorentzVector k2, CLHEP::HepLorentzVector k3, CLHEP::HepLorentzVector k4, double mq)
	COM H5(CLHEP::HepLorentzVector k1, CLHEP::HepLorentzVector k2, CLHEP::HepLorentzVector kh, double mq)
	{
	//return -1.*H4(k2,k1,k3,k4,mq);
	return -1.*H4(k2,k1,kh,mq);
	}
	//COM H12(CLHEP::HepLorentzVector k1, CLHEP::HepLorentzVector k2, CLHEP::HepLorentzVector k3, CLHEP::HepLorentzVector k4, double mq)
	COM H12(CLHEP::HepLorentzVector k1, CLHEP::HepLorentzVector k2, CLHEP::HepLorentzVector kh, double mq)
	{
	//return -1.*H10(k2,k1,k3,k4,mq);
	return -1.*H10(k2,k1,kh,mq);
	}

	// FL and FT functions
	COM FL(CLHEP::HepLorentzVector q1, CLHEP::HepLorentzVector q2, double mq)
	{
	CLHEP::HepLorentzVector Q = q1 + q2;
	double detQ2 = q1.m2()q2.m2() - q1.dot(q2)q1.dot(q2);
	return -1./(2.detQ2)((2.-
	3.q1.m2()q2.dot(Q)/detQ2)*(B0DD(q1, mq) -
	B0DD(Q, mq)) + (2. -
	3.q2.m2()q1.dot(Q)/detQ2)*(B0DD(q2, mq) -
	B0DD(Q, mq)) - (4.mqmq + q1.m2() + q2.m2() +
	Q.m2() - 3.q1.m2()q2.m2()Q.m2()/detQ2)C0DD(
	q1, q2, mq) - 2.);
	}
	COM FT(CLHEP::HepLorentzVector q1, CLHEP::HepLorentzVector q2, double mq)
	{
	CLHEP::HepLorentzVector Q = q1 + q2;
	double detQ2 = q1.m2()q2.m2() - q1.dot(q2)q1.dot(q2);
	return -1./(2.detQ2)(Q.m2()(B0DD(q1, mq) + B0DD(q2, mq) - 2.B0DD(Q, mq) -
	2.q1.dot(q2)C0DD(q1, q2, mq)) + (q1.m2() -
	q2.m2()) *(B0DD(q1, mq) - B0DD(q2, mq))) -
	q1.dot(q2)*FL(q1, q2, mq);
	}

	CLHEP::HepLorentzVector ParityFlip(CLHEP::HepLorentzVector p)
	{
	CLHEP::HepLorentzVector flippedVector;
	flippedVector.setE(p.e());
	flippedVector.setX(-p.x());
	flippedVector.setY(-p.y());
	flippedVector.setZ(-p.z());
	return flippedVector;
	}
	/// @brief HC amp for qg->qgH with finite top (i.e. j^{++}_H)
	void g_gH_HC(CLHEP::HepLorentzVector pa, CLHEP::HepLorentzVector p1,
	CLHEP::HepLorentzVector pH, double mq, current &retAns)
	{
	current cura1,pacur,p1cur,pHcur,conjeps1,conjepsH1,epsa,epsHa,epsHapart1,
	epsHapart2,conjepsH1part1,conjepsH1part2;
	COM ang1a,sqa1;

	const double F = 4.mqmq/HEJ::vev;
	// Easier to have the whole thing as current object so I can use cdot functionality.
	// Means I need to write pa,p1 as current objects
	to_current(pa, pacur);
	to_current(p1,p1cur);
	to_current(pH,pHcur);
	bool gluonforward = true;
	if(pa.z() < 0)
	gluonforward = false;
	//HEJ gauge
	jio(pa,false,p1,false,cura1);

	if(gluonforward){
	// sqrt(2pa_-/p1_-)*p1_perp/abs(p1_perp)
	ang1a = sqrt(pa.plus()p1.minus())(p1.x()+COM(0.,1.)*p1.y())/p1.perp();
	// sqrt(2pa_-/p1_-)p1_perp/abs(p1_perp)
	sqa1 = sqrt(pa.plus()p1.minus())(p1.x()-COM(0.,1.)*p1.y())/p1.perp();
	} else {
	ang1a = sqrt(pa.minus()*p1.plus());
	sqa1 = sqrt(pa.minus()*p1.plus());
	}


	const double prop = (pa-p1-pH).m2();

	cmult(-1./sqrt(2)/ang1a,cura1,conjeps1);
	cmult(1./sqrt(2)/sqa1,cura1,epsa);

	const COM Fta = FT(-pa,pa-pH,mq)/(pa-pH).m2();
	const COM Ft1 = FT(-p1-pH,p1,mq)/(p1+pH).m2();

	const COM h4 = H4(p1,-pa,pH,mq);
	const COM h5 = H5(p1,-pa,pH,mq);
	const COM h10 = H10(p1,-pa,pH,mq);
	const COM h12 = H12(p1,-pa,pH,mq);


	cmult(Fta*pa.dot(pH), epsa, epsHapart1);
	cmult(-1.Ftacdot(pHcur,epsa), pacur, epsHapart2);
	cmult(Ft1*cdot(pHcur,conjeps1), p1cur, conjepsH1part1);
	cmult(-Ft1*p1.dot(pH), conjeps1, conjepsH1part2);
	cadd(epsHapart1, epsHapart2, epsHa);
	cadd(conjepsH1part1, conjepsH1part2, conjepsH1);
	const COM aH1 = cdot(pHcur, cura1);

	current T1,T2,T3,T4,T5,T6,T7,T8,T9,T10;

	if(gluonforward){
	cmult(sqrt(2.)sqrt(p1.plus()/pa.plus())prop/sqa1, conjepsH1, T1);
	cmult(-sqrt(2.)sqrt(pa.plus()/p1.plus())prop/ang1a, epsHa, T2);
	}
	else{
	cmult(-sqrt(2.)*sqrt(p1.minus()/pa.minus())
	((p1.x()-COM(0.,1.)p1.y())/p1.perp())*prop/sqa1, conjepsH1, T1);
	cmult(sqrt(2.)*sqrt(pa.minus()/p1.minus())
	((p1.x()-COM(0.,1.)p1.y())/p1.perp())*prop/ang1a, epsHa, T2);
	}

	cmult(sqrt(2.)/ang1a*aH1, epsHa, T3);
	cmult(sqrt(2.)/sqa1*aH1, conjepsH1, T4);

	cmult(-sqrt(2.)Ftapa.dot(p1)*aH1/sqa1, conjeps1, T5);
	cmult(-sqrt(2.)Ft1pa.dot(p1)*aH1/ang1a, epsa, T6);

	cmult(-aH1/sqrt(2.)/sqa1h48.COM(0.,1.)M_PI*M_PI, conjeps1, T7);
	cmult(aH1/sqrt(2.)/ang1ah58.COM(0.,1.)M_PI*M_PI, epsa, T8);
	cmult(aH1aH1/2./ang1a/sqa1h108.COM(0.,1.)M_PIM_PI, pacur, T9);
	cmult(-aH1aH1/2./ang1a/sqa1h128.COM(0.,1.)M_PIM_PI, p1cur, T10);

	current ans;
	for(int i=0;i<4;i++)
	{
	ans[i] = T1[i]+T2[i]+T3[i]+T4[i]+T5[i]+T6[i]+T7[i]+T8[i]+T9[i]+T10[i];
	}

	retAns[0] = F/prop*ans[0];
	retAns[1] = F/prop*ans[1];
	retAns[2] = F/prop*ans[2];
	retAns[3] = F/prop*ans[3];
	}

	/// @brief HNC amp for qg->qgH with finite top (i.e. j^{+-}_H)
	void g_gH_HNC(CLHEP::HepLorentzVector pa, CLHEP::HepLorentzVector p1, CLHEP::HepLorentzVector pH, double mq, current &retAns)
	{
	const double F = 4.mqmq/HEJ::vev;
	COM ang1a,sqa1;
	current conjepsH1,epsHa,p1cur,pacur,pHcur,conjeps1,epsa,paplusp1cur,
	p1minuspacur,cur1a,cura1,epsHapart1,epsHapart2,conjepsH1part1,
	conjepsH1part2;
	// Find here if pa, meaning the gluon, is forward or backward
	bool gluonforward = true;
	if(pa.z() < 0)
	gluonforward = false;

	jio(pa,true,p1,true,cura1);
	joi(p1,true,pa,true,cur1a);

	to_current(pa,pacur);
	to_current(p1,p1cur);
	to_current(pH,pHcur);
	to_current(pa+p1,paplusp1cur);
	to_current(p1-pa,p1minuspacur);
	const COM aH1 = cdot(pHcur,cura1);
	const COM oneHa = std::conj(aH1); // = cdot(pHcur,cur1a)

	if(gluonforward){
	// sqrt(2pa_-/p1_-)*p1_perp/abs(p1_perp)
	ang1a = sqrt(pa.plus()p1.minus())(p1.x()+COM(0.,1.)*p1.y())/p1.perp();
	// sqrt(2pa_-/p1_-)p1_perp/abs(p1_perp)
	sqa1 = sqrt(pa.plus()p1.minus())(p1.x()-COM(0.,1.)*p1.y())/p1.perp();
	}
	else {
	ang1a = sqrt(pa.minus()*p1.plus());
	sqa1 = sqrt(pa.minus()*p1.plus());
	}

	const double prop = (pa-p1-pH).m2();

	cmult(1./sqrt(2)/sqa1, cur1a, epsa);
	cmult(-1./sqrt(2)/sqa1, cura1, conjeps1);
	const COM phase = cdot(conjeps1, epsa);
	const COM Fta = FT(-pa,pa-pH,mq)/(pa-pH).m2();
	const COM Ft1 = FT(-p1-pH,p1,mq)/(p1+pH).m2();
	const COM Falpha = FT(p1-pa,pa-p1-pH,mq);
	const COM Fbeta = FL(p1-pa,pa-p1-pH,mq);

	const COM h1 = H1(p1,-pa, pH, mq);
	const COM h2 = H2(p1,-pa, pH, mq);
	const COM h4 = H4(p1,-pa, pH, mq);
	const COM h5 = H5(p1,-pa, pH, mq);
	const COM h10 = H10(p1,-pa, pH, mq);
	const COM h12 = H12(p1,-pa, pH, mq);

	cmult(Fta*pa.dot(pH), epsa, epsHapart1);
	cmult(-1.Ftacdot(pHcur,epsa), pacur, epsHapart2);
	cmult(Ft1*cdot(pHcur,conjeps1), p1cur, conjepsH1part1);
	cmult(-Ft1*p1.dot(pH), conjeps1, conjepsH1part2);
	cadd(epsHapart1, epsHapart2, epsHa);
	cadd(conjepsH1part1, conjepsH1part2, conjepsH1);

	current T1,T2,T3,T4,T5a,T5b,T6,T7,T8a,T8b,T9,T10,T11a,
	T11b,T12a,T12b,T13;

	if(gluonforward){
	cmult(sqrt(2.)sqrt(p1.plus()/pa.plus())prop/sqa1, conjepsH1, T1);
	cmult(-sqrt(2.)sqrt(pa.plus()/p1.plus())prop/sqa1, epsHa, T2);
	}
	else{
	cmult(-sqrt(2.)sqrt(p1.minus()/pa.minus())((p1.x()-COM(0.,1.)*p1.y())/p1.perp())
	*prop/sqa1, conjepsH1, T1);
	cmult(sqrt(2.)sqrt(pa.minus()/p1.minus())((p1.x()+COM(0.,1.)*p1.y())/p1.perp())
	*prop/sqa1, epsHa, T2);
	}

	const COM boxdiagFact = 8.COM(0.,1.)M_PI*M_PI;

	cmult(aH1*sqrt(2.)/sqa1, epsHa, T3);
	cmult(oneHa*sqrt(2.)/sqa1, conjepsH1, T4);
	cmult(-2.phaseFta*pa.dot(pH), p1cur, T5a);
	cmult(2.phaseFt1*p1.dot(pH), pacur, T5b);
	cmult(-sqrt(2.)Ftap1.dot(pa)*oneHa/sqa1, conjeps1, T6);
	cmult(-sqrt(2.)Ft1pa.dot(p1)*aH1/sqa1, epsa, T7);

	cmult(-boxdiagFactphaseh2, pacur, T8a);
	cmult(boxdiagFactphaseh1, p1cur, T8b);
	cmult(boxdiagFactaH1/sqrt(2.)/sqa1h5, epsa, T9);
	cmult(-boxdiagFactoneHa/sqrt(2.)/sqa1h4, conjeps1, T10);
	cmult(boxdiagFactaH1oneHa/2./sqa1/sqa1*h10, pacur, T11a);
	cmult(-boxdiagFactaH1oneHa/2./sqa1/sqa1*h12, p1cur, T11b);

	cmult(-phase/(pa-p1).m2()Falpha(p1-pa).dot(pa-p1-pH), paplusp1cur, T12a);
	cmult(phase/(pa-p1).m2()Falpha(pa+p1).dot(pa-p1-pH), p1minuspacur, T12b);
	cmult(-phaseFbeta(pa-p1-pH).m2(), paplusp1cur, T13);

	current ans;
	for(int i=0;i<4;i++)
	{
	ans[i] = T1[i]+T2[i]+T3[i]+T4[i]+T5a[i]+T5b[i]+T6[i]+T7[i]+T8a[i]+T8b[i]+T9[i]+T10[i]+T11a[i]+T11b[i]+T12a[i]+T12b[i]+T13[i];
	}

	retAns[0] = F/prop*ans[0];
	retAns[1] = F/prop*ans[1];
	retAns[2] = F/prop*ans[2];
	retAns[3] = F/prop*ans[3];
	}

	} // namespace anonymous
	// JDC - new amplitude with Higgs emitted close to gluon with full mt effects. Keep usual HEJ-style function call
	double MH2gq_outsideH(CLHEP::HepLorentzVector p1out, CLHEP::HepLorentzVector p1in, CLHEP::HepLorentzVector p2out, CLHEP::HepLorentzVector p2in, CLHEP::HepLorentzVector pH, double mq, bool includeBottom, double mq2)
	{

	current cur2bplus,cur2bminus, cur2bplusFlip, cur2bminusFlip;
	current retAns,retAnsb;
	joi(p2out,true,p2in,true,cur2bplus);
	joi(p2out,false,p2in,false,cur2bminus);
	joi(ParityFlip(p2out),true,ParityFlip(p2in),true,cur2bplusFlip);
	joi(ParityFlip(p2out),false,ParityFlip(p2in),false,cur2bminusFlip);

	COM app1,app2,apm1,apm2;
	COM app3, app4, apm3, apm4;

	if(!includeBottom)
	{
	g_gH_HC(p1in,p1out,pH,mq,retAns);
	app1=cdot(retAns,cur2bplus);
	app2=cdot(retAns,cur2bminus);

	g_gH_HC(ParityFlip(p1in),ParityFlip(p1out),ParityFlip(pH),mq,retAns);
	app3=cdot(retAns,cur2bplusFlip);
	app4=cdot(retAns,cur2bminusFlip);

	// And non-conserving bits
	g_gH_HNC(p1in,p1out,pH,mq,retAns);
	apm1=cdot(retAns,cur2bplus);
	apm2=cdot(retAns,cur2bminus);

	g_gH_HNC(ParityFlip(p1in),ParityFlip(p1out),ParityFlip(pH),mq,retAns);
	apm3=cdot(retAns,cur2bplusFlip);
	apm4=cdot(retAns,cur2bminusFlip);
	} else {
	g_gH_HC(p1in,p1out,pH,mq,retAns);
	g_gH_HC(p1in,p1out,pH,mq2,retAnsb);
	app1=cdot(retAns,cur2bplus) + cdot(retAnsb,cur2bplus);
	app2=cdot(retAns,cur2bminus) + cdot(retAnsb,cur2bminus);

	g_gH_HC(ParityFlip(p1in),ParityFlip(p1out),ParityFlip(pH),mq,retAns);
	g_gH_HC(ParityFlip(p1in),ParityFlip(p1out),ParityFlip(pH),mq2,retAnsb);
	app3=cdot(retAns,cur2bplusFlip) + cdot(retAnsb,cur2bplusFlip);
	app4=cdot(retAns,cur2bminusFlip) + cdot(retAnsb,cur2bminusFlip);

	// And non-conserving bits
	g_gH_HNC(p1in,p1out,pH,mq,retAns);
	g_gH_HNC(p1in,p1out,pH,mq2,retAnsb);
	apm1=cdot(retAns,cur2bplus) + cdot(retAnsb,cur2bplus);
	apm2=cdot(retAns,cur2bminus) + cdot(retAnsb,cur2bminus);

	g_gH_HNC(ParityFlip(p1in),ParityFlip(p1out),ParityFlip(pH),mq,retAns);
	g_gH_HNC(ParityFlip(p1in),ParityFlip(p1out),ParityFlip(pH),mq2,retAnsb);
	apm3=cdot(retAns,cur2bplusFlip) + cdot(retAnsb,cur2bplusFlip);
	apm4=cdot(retAns,cur2bminusFlip) + cdot(retAnsb,cur2bminusFlip);
	}

	return abs2(app1) + abs2(app2) + abs2(app3) + abs2(app4) + abs2(apm1)
	+ abs2(apm2) + abs2(apm3) + abs2(apm4);
	}
	#endif // HEJ_BUILD_WITH_QCDLOOP

	double C2gHgm(CLHEP::HepLorentzVector p2, CLHEP::HepLorentzVector p1, CLHEP::HepLorentzVector pH)
	{
	static double A=1./(3.M_PIHEJ::vev);
	// Implements Eq. (4.22) in hep-ph/0301013 with modifications to incoming plus momenta
	double s12,p1p,p2p;
	COM p1perp,p3perp,phperp;
	// Determine first whether this is the case p1p\sim php>>p3p og the opposite
	s12=p1.invariantMass2(-p2);
	if (p2.pz()>0.) { // case considered in hep-ph/0301013
	p1p=p1.plus();
	p2p=p2.plus();
	} else { // opposite case
	p1p=p1.minus();
	p2p=p2.minus();
	}
	p1perp=p1.px()+COM(0,1)*p1.py();
	phperp=pH.px()+COM(0,1)*pH.py();
	p3perp=-(p1perp+phperp);

	COM temp=COM(0,1)A/(2.s12)(p2p/p1pconj(p1perp)p3perp+p1p/p2pp1perp*conj(p3perp));
	temp=temp*conj(temp);
	return temp.real();
	}

	double C2gHgp(CLHEP::HepLorentzVector p2, CLHEP::HepLorentzVector p1, CLHEP::HepLorentzVector pH)
	{
	static double A=1./(3.M_PIHEJ::vev);
	// Implements Eq. (4.23) in hep-ph/0301013
	double s12,php,p1p,phm;
	COM p1perp,p3perp,phperp;
	// Determine first whether this is the case p1p\sim php>>p3p or the opposite
	s12=p1.invariantMass2(-p2);
	if (p2.pz()>0.) { // case considered in hep-ph/0301013
	php=pH.plus();
	phm=pH.minus();
	p1p=p1.plus();
	} else { // opposite case
	php=pH.minus();
	phm=pH.plus();
	p1p=p1.minus();
	}
	p1perp=p1.px()+COM(0,1)*p1.py();
	phperp=pH.px()+COM(0,1)*pH.py();
	p3perp=-(p1perp+phperp);

	COM temp=-COM(0,1)A/(2.s12)( conj(p1perpp3perp)*pow(php/p1p,2)/(1.+php/p1p)
	+s12(pow(conj(phperp),2)/(pow(abs(phperp),2)+p1pphm)
	-pow(conj(p3perp)
	+(1.+php/p1p)conj(p1perp),2)/((1.+php/p1p)(pH.m2()+2.*p1.dot(pH)))) );
	temp=temp*conj(temp);
	return temp.real();
	}

	double C2qHqm(CLHEP::HepLorentzVector p2, CLHEP::HepLorentzVector p1, CLHEP::HepLorentzVector pH)
	{
	static double A=1./(3.M_PIHEJ::vev);
	// Implements Eq. (4.22) in hep-ph/0301013
	double s12,p2p,p1p;
	COM p1perp,p3perp,phperp;
	// Determine first whether this is the case p1p\sim php>>p3p or the opposite
	s12=p1.invariantMass2(-p2);
	if (p2.pz()>0.) { // case considered in hep-ph/0301013
	p2p=p2.plus();
	p1p=p1.plus();
	} else { // opposite case
	p2p=p2.minus();
	p1p=p1.minus();
	}
	p1perp=p1.px()+COM(0,1)*p1.py();
	phperp=pH.px()+COM(0,1)*pH.py();
	p3perp=-(p1perp+phperp);

	COM temp=A/(2.s12)( sqrt(p2p/p1p)p3perpconj(p1perp)
	+sqrt(p1p/p2p)p1perpconj(p3perp) );
	temp=temp*conj(temp);
	return temp.real();
	}

File Metadata

Mime Type: text/x-diff
Expires: Mon, Jan 20, 8:40 PM (22 h, 41 m)
Storage Engine: blob
Storage Format: Raw Data
Storage Handle: 4242314
Default Alt Text: (272 KB)

No OneTemporaryActions

View Options

File Metadata

Event Timeline

No OneTemporary
Actions