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	diff --git a/Hadronization/ClusterFissioner.cc b/Hadronization/ClusterFissioner.cc
	--- a/Hadronization/ClusterFissioner.cc
	+++ b/Hadronization/ClusterFissioner.cc
	@@ -1,1672 +1,1723 @@
	// -- C++ --
	//
	// ClusterFissioner.cc is a part of Herwig - A multi-purpose Monte Carlo event generator
	// Copyright (C) 2002-2019 The Herwig Collaboration
	//
	// Herwig is licenced under version 3 of the GPL, see COPYING for details.
	// Please respect the MCnet academic guidelines, see GUIDELINES for details.
	//
	//
	// Thisk is the implementation of the non-inlined, non-templated member
	// functions of the ClusterFissioner class.
	//

	#include "ClusterFissioner.h"
	#include <ThePEG/Interface/ClassDocumentation.h>
	#include <ThePEG/Interface/Reference.h>
	#include <ThePEG/Interface/Parameter.h>
	#include <ThePEG/Interface/Switch.h>
	#include <ThePEG/Persistency/PersistentOStream.h>
	#include <ThePEG/Persistency/PersistentIStream.h>
	#include <ThePEG/PDT/EnumParticles.h>
	#include "Herwig/Utilities/Kinematics.h"
	#include "Cluster.h"
	#include "ThePEG/Repository/UseRandom.h"
	#include "ThePEG/Repository/EventGenerator.h"
	#include <ThePEG/Utilities/DescribeClass.h>
	#include "ThePEG/Interface/ParMap.h"
	#include "Herwig/Utilities/AlphaS.h"

	using namespace Herwig;

	DescribeClass<ClusterFissioner,Interfaced>
	describeClusterFissioner("Herwig::ClusterFissioner","Herwig.so");

	ClusterFissioner::ClusterFissioner() :
	_clMaxLight(3.35*GeV),
	_clMaxDiquark(3.35*GeV),
	_clMaxExotic(3.35*GeV),
	_clPowLight(2.0),
	_clPowDiquark(2.0),
	_clPowExotic(2.0),
	_pSplitLight(1.0),
	_pSplitExotic(1.0),
	_phaseSpaceWeights(0),
	_dim(4),
	_fissionCluster(0),
	_kinematicThresholdChoice(0),
	_pwtDIquark(0.0),
	_diquarkClusterFission(0),
	_btClM(1.0*GeV),
	_iopRem(1),
	_kappa(1.0e15*GeV/meter),
	_enhanceSProb(0),
	_m0Fission(2.*GeV),
	_massMeasure(0),
	_probPowFactor(4.0),
	_probShift(0.0),
	_kinThresholdShift(1.0*sqr(GeV)),
	_strictDiquarkKinematics(0),
	_covariantBoost(false),
	_hadronizingStrangeDiquarks(2),
	_writeOut(0)
	{
	}
	ClusterFissioner::~ClusterFissioner(){
	}
	IBPtr ClusterFissioner::clone() const {
	return new_ptr(*this);
	}

	IBPtr ClusterFissioner::fullclone() const {
	return new_ptr(*this);
	}

	void ClusterFissioner::persistentOutput(PersistentOStream & os) const {
	os << ounit(_clMaxLight,GeV) << ounit(_clMaxHeavy,GeV) << ounit(_clMaxDiquark,GeV) << ounit(_clMaxExotic,GeV)
	<< _clPowLight << _clPowHeavy << _clPowDiquark << _clPowExotic
	<< _pSplitLight << _pSplitHeavy << _pSplitExotic
	<< _fissionCluster << _fissionPwt
	<< _pwtDIquark
	<< _diquarkClusterFission
	<< ounit(_btClM,GeV)
	<< _iopRem << ounit(_kappa, GeV/meter)
	<< _enhanceSProb << ounit(_m0Fission,GeV) << _massMeasure
	<< _dim << _phaseSpaceWeights
	<< _hadronSpectrum << _kinematicThresholdChoice
	<< _probPowFactor << _probShift << ounit(_kinThresholdShift,sqr(GeV))
	<< _strictDiquarkKinematics
	<< _covariantBoost
	<< _hadronizingStrangeDiquarks
	<< _writeOut
	;
	}

	void ClusterFissioner::persistentInput(PersistentIStream & is, int) {
	is >> iunit(_clMaxLight,GeV) >> iunit(_clMaxHeavy,GeV) >> iunit(_clMaxDiquark,GeV) >> iunit(_clMaxExotic,GeV)
	>> _clPowLight >> _clPowHeavy >> _clPowDiquark >> _clPowExotic
	>> _pSplitLight >> _pSplitHeavy >> _pSplitExotic
	>> _fissionCluster >> _fissionPwt
	>> _pwtDIquark
	>> _diquarkClusterFission
	>> iunit(_btClM,GeV)
	>> _iopRem >> iunit(_kappa, GeV/meter)
	>> _enhanceSProb >> iunit(_m0Fission,GeV) >> _massMeasure
	>> _dim >> _phaseSpaceWeights
	>> _hadronSpectrum >> _kinematicThresholdChoice
	>> _probPowFactor >> _probShift >> iunit(_kinThresholdShift,sqr(GeV))
	>> _strictDiquarkKinematics
	>> _covariantBoost
	>> _hadronizingStrangeDiquarks
	>> _writeOut
	;
	}

	void ClusterFissioner::doinit() {
	Interfaced::doinit();
	if (_writeOut){
	std::ofstream out("data_CluFis.dat", std::ios::out);
	out.close();
	}
	for ( const long& id : spectrum()->heavyHadronizingQuarks() ) {
	if ( _pSplitHeavy.find(id) == _pSplitHeavy.end() \|\|
	_clPowHeavy.find(id) == _clPowHeavy.end() \|\|
	_clMaxHeavy.find(id) == _clMaxHeavy.end() ){
	std::cout << "id = "<<id << std::endl;
	throw InitException() << "not all parameters have been set for heavy quark cluster fission";
	}
	}
	// for default Pwts not needed to initialize
	if (_fissionCluster==0) return;
	for ( const long& id : spectrum()->lightHadronizingQuarks() ) {
	if ( _fissionPwt.find(id) == _fissionPwt.end() )
	// check that all relevant weights are set
	throw InitException() << "fission weights for light quarks have not been set";
	}
	double pwtDquark=_fissionPwt.find(ParticleID::d)->second;
	double pwtUquark=_fissionPwt.find(ParticleID::u)->second;
	double pwtSquark=_fissionPwt.find(ParticleID::s)->second;
	// TODO better solution for this magic number alternative
	_fissionPwt[1103] = _pwtDIquark * pwtDquark * pwtDquark;
	_fissionPwt[2101] = 0.5 * _pwtDIquark * pwtUquark * pwtDquark;
	_fissionPwt[2203] = _pwtDIquark * pwtUquark * pwtUquark;
	if (_hadronizingStrangeDiquarks>0) {
	_fissionPwt[3101] = 0.5 * _pwtDIquark * pwtSquark * pwtDquark;
	_fissionPwt[3201] = 0.5 * _pwtDIquark * pwtSquark * pwtUquark;
	if (_hadronizingStrangeDiquarks==2) {
	_fissionPwt[3303] = _pwtDIquark* pwtSquark * pwtSquark;
	}
	}
	}

	void ClusterFissioner::Init() {

	static ClassDocumentation<ClusterFissioner> documentation
	("Class responsibles for chopping up the clusters");

	static Reference<ClusterFissioner,HadronSpectrum> interfaceHadronSpectrum
	("HadronSpectrum",
	"Set the Hadron spectrum for this cluster fissioner.",
	&ClusterFissioner::_hadronSpectrum, false, false, true, false);

	// ClMax for light, Bottom, Charm and exotic (e.g. Susy) quarks
	static Parameter<ClusterFissioner,Energy>
	interfaceClMaxLight ("ClMaxLight","cluster max mass for light quarks (unit [GeV])",
	&ClusterFissioner::_clMaxLight, GeV, 3.35GeV, ZERO, 100.0GeV,
	false,false,false);
	static Parameter<ClusterFissioner,Energy>
	interfaceClMaxDiquark ("ClMaxDiquark","cluster max mass for light hadronizing diquarks (unit [GeV])",
	&ClusterFissioner::_clMaxDiquark, GeV, 3.35GeV, ZERO, 100.0GeV,
	false,false,false);
	static ParMap<ClusterFissioner,Energy> interfaceClMaxHeavy
	("ClMaxHeavy",
	"ClMax for heavy quarks",
	&ClusterFissioner::_clMaxHeavy, GeV, -1, 3.35GeV, ZERO, 100.0GeV,
	false, false, Interface::upperlim);
	static Parameter<ClusterFissioner,Energy>
	interfaceClMaxExotic ("ClMaxExotic","cluster max mass for exotic quarks (unit [GeV])",
	&ClusterFissioner::_clMaxExotic, GeV, 3.35GeV, ZERO, 100.0GeV,
	false,false,false);

	// ClPow for light, Bottom, Charm and exotic (e.g. Susy) quarks
	static Parameter<ClusterFissioner,double>
	interfaceClPowLight ("ClPowLight","cluster mass exponent for light quarks",
	&ClusterFissioner::_clPowLight, 0, 2.0, 0.0, 10.0,false,false,false);
	static ParMap<ClusterFissioner,double> interfaceClPowHeavy
	("ClPowHeavy",
	"ClPow for heavy quarks",
	&ClusterFissioner::_clPowHeavy, -1, 1.0, 0.0, 10.0,
	false, false, Interface::upperlim);
	static Parameter<ClusterFissioner,double>
	interfaceClPowDiquark ("ClPowDiquark","cluster mass exponent for light hadronizing diquarks",
	&ClusterFissioner::_clPowDiquark, 0, 2.0, 0.0, 10.0,false,false,false);
	static Parameter<ClusterFissioner,double>
	interfaceClPowExotic ("ClPowExotic","cluster mass exponent for exotic quarks",
	&ClusterFissioner::_clPowExotic, 0, 2.0, 0.0, 10.0,false,false,false);

	// PSplit for light, Bottom, Charm and exotic (e.g. Susy) quarks
	static Parameter<ClusterFissioner,double>
	interfacePSplitLight ("PSplitLight","cluster mass splitting param for light quarks",
	&ClusterFissioner::_pSplitLight, 0, 1.0, 0.0, 10.0,false,false,false);
	static ParMap<ClusterFissioner,double> interfacePSplitHeavy
	("PSplitHeavy",
	"PSplit for heavy quarks",
	&ClusterFissioner::_pSplitHeavy, -1, 1.0, 0.0, 10.0,
	false, false, Interface::upperlim);
	static Parameter<ClusterFissioner,double>
	interfacePSplitExotic ("PSplitExotic","cluster mass splitting param for exotic quarks",
	&ClusterFissioner::_pSplitExotic, 0, 1.0, 0.0, 10.0,false,false,false);


	static Switch<ClusterFissioner,int> interfaceFission
	("Fission",
	"Option for different Fission options",
	&ClusterFissioner::_fissionCluster, 1, false, false);
	static SwitchOption interfaceFissionDefault
	(interfaceFission,
	"Default",
	"Normal cluster fission which depends on the hadron spectrum class.",
	0);
	static SwitchOption interfaceFissionNew
	(interfaceFission,
	"New",
	"Alternative cluster fission which does not depend on the hadron spectrum class",
	1);
	static SwitchOption interfaceFissionNewDiquarkSuppression
	(interfaceFission,
	"NewDiquarkSuppression",
	"Alternative cluster fission which does not depend on the hadron spectrum class"
	" and includes a suppression of AlphaS^2(Mc) for Diquark Production during "
	"Cluster Fission",
	-1);


	static Switch<ClusterFissioner,int> interfaceDiquarkClusterFission
	("DiquarkClusterFission",
	"Allow clusters to fission to 1 or 2 diquark Clusters or Turn off diquark fission completely",
	&ClusterFissioner::_diquarkClusterFission, 0, false, false);
	static SwitchOption interfaceDiquarkClusterFissionAll
	(interfaceDiquarkClusterFission,
	"All",
	"Allow diquark clusters and baryon clusters to fission to new diquark Clusters",
	2);
	static SwitchOption interfaceDiquarkClusterFissionOnlyBaryonClusters
	(interfaceDiquarkClusterFission,
	"OnlyBaryonClusters",
	"Allow only baryon clusters to fission to new diquark Clusters",
	1);
	static SwitchOption interfaceDiquarkClusterFissionNo
	(interfaceDiquarkClusterFission,
	"No",
	"Don't allow clusters to fission to new diquark Clusters",
	0);
	static SwitchOption interfaceDiquarkClusterFissionOff
	(interfaceDiquarkClusterFission,
	"Off",
	"Don't allow clusters fission to draw diquarks ",
	-1);

	static ParMap<ClusterFissioner,double> interfaceFissionPwt
	("FissionPwt",
	"The weights for quarks in the fission process.",
	&ClusterFissioner::_fissionPwt, -1, 1.0, 0.0, 10.0,
	false, false, Interface::upperlim);

	static Switch<ClusterFissioner,int> interfaceRemnantOption
	("RemnantOption",
	"Option for the treatment of remnant clusters",
	&ClusterFissioner::_iopRem, 1, false, false);
	static SwitchOption interfaceRemnantOptionSoft
	(interfaceRemnantOption,
	"Soft",
	"Both clusters produced in the fission of the beam cluster"
	" are treated as soft clusters.",
	0);
	static SwitchOption interfaceRemnantOptionHard
	(interfaceRemnantOption,
	"Hard",
	"Only the cluster containing the remnant is treated as a soft cluster.",
	1);
	static SwitchOption interfaceRemnantOptionVeryHard
	(interfaceRemnantOption,
	"VeryHard",
	"Even remnant clusters are treated as hard, i.e. all clusters the same",
	2);

	static Parameter<ClusterFissioner,Energy> interfaceBTCLM
	("SoftClusterFactor",
	"Parameter for the mass spectrum of remnant clusters",
	&ClusterFissioner::_btClM, GeV, 1.GeV, 0.1GeV, 10.0*GeV,
	false, false, Interface::limited);


	static Parameter<ClusterFissioner,Tension> interfaceStringTension
	("StringTension",
	"String tension used in vertex displacement calculation",
	&ClusterFissioner::_kappa, GeV/meter,
	1.0e15*GeV/meter, ZERO, ZERO,
	false, false, Interface::lowerlim);

	static Switch<ClusterFissioner,int> interfaceEnhanceSProb
	("EnhanceSProb",
	"Option for enhancing strangeness",
	&ClusterFissioner::_enhanceSProb, 0, false, false);
	static SwitchOption interfaceEnhanceSProbNo
	(interfaceEnhanceSProb,
	"No",
	"No strangeness enhancement.",
	0);
	static SwitchOption interfaceEnhanceSProbScaled
	(interfaceEnhanceSProb,
	"Scaled",
	"Scaled strangeness enhancement",
	1);
	static SwitchOption interfaceEnhanceSProbExponential
	(interfaceEnhanceSProb,
	"Exponential",
	"Exponential strangeness enhancement",
	2);
	+ static SwitchOption interfaceEnhanceSProbNoLightStrangeness
	+ (interfaceEnhanceSProb,
	+ "NoLightStrangeness",
	+ "Forbid Strangeness production for cluster masses below FissionMassScale",
	+ 3);

	static Switch<ClusterFissioner,int> interfaceMassMeasure
	("MassMeasure",
	"Option to use different mass measures",
	&ClusterFissioner::_massMeasure,0,false,false);
	static SwitchOption interfaceMassMeasureMass
	(interfaceMassMeasure,
	"Mass",
	"Mass Measure",
	0);
	static SwitchOption interfaceMassMeasureLambda
	(interfaceMassMeasure,
	"Lambda",
	"Lambda Measure",
	1);

	static Parameter<ClusterFissioner,Energy> interfaceFissionMassScale
	("FissionMassScale",
	"Cluster fission mass scale",
	- &ClusterFissioner::_m0Fission, GeV, 2.0GeV, 0.1GeV, 50.*GeV,
	+ &ClusterFissioner::_m0Fission, GeV, 2.0GeV, 0.1GeV, 500.*GeV,
	false, false, Interface::limited);

	static Parameter<ClusterFissioner,double> interfaceProbPowFactor
	("ProbabilityPowerFactor",
	"Power factor in ClusterFissioner bell probablity function",
	&ClusterFissioner::_probPowFactor, 2.0, 0.001, 20.0,
	false, false, Interface::limited);

	static Parameter<ClusterFissioner,double> interfaceProbShift
	("ProbabilityShift",
	"Shifts from the center in ClausterFissioner bell probablity function",
	&ClusterFissioner::_probShift, 0.0, -10.0, 10.0,
	false, false, Interface::limited);

	static Parameter<ClusterFissioner,Energy2> interfaceKineticThresholdShift
	("KineticThresholdShift",
	"Shifts from the kinetic threshold in ClusterFissioner",
	&ClusterFissioner::_kinThresholdShift, sqr(GeV), 0.sqr(GeV), -10.0sqr(GeV), 10.0*sqr(GeV),
	false, false, Interface::limited);

	static Switch<ClusterFissioner,int> interfaceKinematicThreshold
	("KinematicThreshold",
	"Option for using static or dynamic kinematic thresholds in cluster splittings",
	&ClusterFissioner::_kinematicThresholdChoice, 0, false, false);
	static SwitchOption interfaceKinematicThresholdStatic
	(interfaceKinematicThreshold,
	"Static",
	"Set static kinematic thresholds for cluster splittings.",
	0);
	static SwitchOption interfaceKinematicThresholdDynamic
	(interfaceKinematicThreshold,
	"Dynamic",
	"Set dynamic kinematic thresholds for cluster splittings.",
	1);

	static Switch<ClusterFissioner,bool> interfaceCovariantBoost
	("CovariantBoost",
	"Use single Covariant Boost for Cluster Fission",
	&ClusterFissioner::_covariantBoost, false, false, false);
	static SwitchOption interfaceCovariantBoostYes
	(interfaceCovariantBoost,
	"Yes",
	"Use Covariant boost",
	true);
	static SwitchOption interfaceCovariantBoostNo
	(interfaceCovariantBoost,
	"No",
	"Do NOT use Covariant boost",
	false);


	static Switch<ClusterFissioner,int> interfaceStrictDiquarkKinematics
	("StrictDiquarkKinematics",
	"Option for selecting different selection criterions of diquarks for ClusterFission",
	&ClusterFissioner::_strictDiquarkKinematics, 0, false, false);
	static SwitchOption interfaceStrictDiquarkKinematicsLoose
	(interfaceStrictDiquarkKinematics,
	"Loose",
	"No kinematic threshold for diquark selection except for Mass bigger than 2 baryons",
	0);
	static SwitchOption interfaceStrictDiquarkKinematicsStrict
	(interfaceStrictDiquarkKinematics,
	"Strict",
	"Resulting clusters are at least as heavy as 2 lightest baryons",
	1);

	static Parameter<ClusterFissioner,double> interfacePwtDIquark
	("PwtDIquark",
	"specific probability for choosing a d diquark",
	&ClusterFissioner::_pwtDIquark, 0.0, 0.0, 10.0,
	false, false, Interface::limited);

	static Switch<ClusterFissioner,int> interfacePhaseSpaceWeights
	("PhaseSpaceWeights",
	"Include phase space weights.",
	&ClusterFissioner::_phaseSpaceWeights, 0, false, false);
	static SwitchOption interfacePhaseSpaceWeightsNo
	(interfacePhaseSpaceWeights,
	"No",
	"Do not include the effect of cluster phase space",
	0);
	static SwitchOption interfacePhaseSpaceWeightsYes
	(interfacePhaseSpaceWeights,
	"Yes",
	"Do include the effect of cluster fission phase space "
	"related to constituent masses."
	"Note: Need static Threshold choice",
	1);
	static SwitchOption interfacePhaseSpaceWeightsUseHadronMasses
	(interfacePhaseSpaceWeights,
	"UseHadronMasses",
	"Do include the effect of cluster fission phase space "
	"related to hadron masses."
	"Note: Need static Threshold choice",
	2);
	static SwitchOption interfacePhaseSpaceWeightsNoConstituentMasses
	(interfacePhaseSpaceWeights,
	"NoConstituentMasses",
	"Do not include the effect of cluster fission phase space "
	"related to constituent masses."
	"Note: Need static Threshold choice",
	3);

	static Parameter<ClusterFissioner,double>
	interfaceDim ("Dimension","Dimension in which phase space weights are calculated",
	&ClusterFissioner::_dim, 0, 4.0, 0.0, 10.0,false,false,false);

	// Allowing for strange diquarks in the ClusterFission
	static Switch<ClusterFissioner,unsigned int> interfaceHadronizingStrangeDiquarks
	("HadronizingStrangeDiquarks",
	"Option for adding strange diquarks to Cluster Fission (if Fission = New or Hybrid is enabled)",
	&ClusterFissioner::_hadronizingStrangeDiquarks, 0, false, false);
	static SwitchOption interfaceHadronizingStrangeDiquarksNo
	(interfaceHadronizingStrangeDiquarks,
	"No",
	"No strangeness containing diquarks during Cluster Fission",
	0);
	static SwitchOption interfaceHadronizingStrangeDiquarksOnlySingleStrange
	(interfaceHadronizingStrangeDiquarks,
	"OnlySingleStrange",
	"Only one strangeness containing diquarks during Cluster Fission i.e. su,sd",
	1);
	static SwitchOption interfaceHadronizingStrangeDiquarksAll
	(interfaceHadronizingStrangeDiquarks,
	"All",
	"All strangeness containing diquarks during Cluster Fission i.e. su,sd,ss",
	2);

	}

	tPVector ClusterFissioner::fission(ClusterVector & clusters, bool softUEisOn) {
	// return if no clusters
	if (clusters.empty()) return tPVector();

	/*****************
	* Loop over the (input) collection of cluster pointers, and store in
	* the vector splitClusters all the clusters that need to be split
	* (these are beam clusters, if soft underlying event is off, and
	* heavy non-beam clusters).
	********************/

	stack<ClusterPtr> splitClusters;
	for(ClusterVector::iterator it = clusters.begin() ;
	it != clusters.end() ; ++it) {
	/**************
	* Skip 3-component clusters that have been redefined (as 2-component
	* clusters) or not available clusters. The latter check is indeed
	* redundant now, but it is used for possible future extensions in which,
	* for some reasons, some of the clusters found by ClusterFinder are tagged
	* straight away as not available.
	**************/
	if((it)->isRedefined() \|\| !(it)->isAvailable()) continue;
	// if the cluster is a beam cluster add it to the vector of clusters
	// to be split or if it is heavy
	if((it)->isBeamCluster() \|\| isHeavy(it)) splitClusters.push(*it);
	}
	tPVector finalhadrons;
	cut(splitClusters, clusters, finalhadrons, softUEisOn);
	return finalhadrons;
	}

	void ClusterFissioner::cut(stack<ClusterPtr> & clusterStack,
	ClusterVector &clusters, tPVector & finalhadrons,
	bool softUEisOn) {
	/**************************************************
	* This method does the splitting of the cluster pointed by cluPtr
	* and "recursively" by all of its cluster children, if heavy. All of these
	* new children clusters are added (indeed the pointers to them) to the
	* collection of cluster pointers collecCluPtr. The method works as follows.
	* Initially the vector vecCluPtr contains just the input pointer to the
	* cluster to be split. Then it will be filled "recursively" by all
	* of the cluster's children that are heavy enough to require, in their turn,
	* to be split. In each loop, the last element of the vector vecCluPtr is
	* considered (only once because it is then removed from the vector).
	* This approach is conceptually recursive, but avoid the overhead of
	* a concrete recursive function. Furthermore it requires minimal changes
	* in the case that the fission of an heavy cluster could produce more
	* than two cluster children as assumed now.
	*
	* Draw the masses: for normal, non-beam clusters a power-like mass dist
	* is used, whereas for beam clusters a fast-decreasing exponential mass
	* dist is used instead (to avoid many iterative splitting which could
	* produce an unphysical large transverse energy from a supposed soft beam
	* remnant process).
	****************************************/
	// Here we recursively loop over clusters in the stack and cut them
	while (!clusterStack.empty()) {
	// take the last element of the vector
	ClusterPtr iCluster = clusterStack.top(); clusterStack.pop();
	// split it
	cutType ct = iCluster->numComponents() == 2 ?
	cutTwo(iCluster, finalhadrons, softUEisOn) :
	cutThree(iCluster, finalhadrons, softUEisOn);

	// There are cases when we don't want to split, even if it fails mass test
	if(!ct.first.first \|\| !ct.second.first) {
	// if an unsplit beam cluster leave if for the underlying event
	if(iCluster->isBeamCluster() && softUEisOn)
	iCluster->isAvailable(false);
	continue;
	}
	// check if clusters
	ClusterPtr one = dynamic_ptr_cast<ClusterPtr>(ct.first.first);
	ClusterPtr two = dynamic_ptr_cast<ClusterPtr>(ct.second.first);
	// is a beam cluster must be split into two clusters
	if(iCluster->isBeamCluster() && (!one\|\|!two) && softUEisOn) {
	iCluster->isAvailable(false);
	continue;
	}

	// There should always be a intermediate quark(s) from the splitting
	assert(ct.first.second && ct.second.second);
	/// \todo sort out motherless quark pairs here. Watch out for 'quark in final state' errors
	iCluster->addChild(ct.first.first);
	// iCluster->addChild(ct.first.second);
	// ct.first.second->addChild(ct.first.first);

	iCluster->addChild(ct.second.first);
	// iCluster->addChild(ct.second.second);
	// ct.second.second->addChild(ct.second.first);

	// Sometimes the clusters decay C -> H + C' or C -> H + H' rather then C -> C' + C''
	if(one) {
	clusters.push_back(one);
	if(one->isBeamCluster() && softUEisOn)
	one->isAvailable(false);
	if(isHeavy(one) && one->isAvailable())
	clusterStack.push(one);
	}
	if(two) {
	clusters.push_back(two);
	if(two->isBeamCluster() && softUEisOn)
	two->isAvailable(false);
	if(isHeavy(two) && two->isAvailable())
	clusterStack.push(two);
	}
	}
	}

	ClusterFissioner::cutType
	ClusterFissioner::cutTwo(ClusterPtr & cluster, tPVector & finalhadrons,
	bool softUEisOn) {
	// need to make sure only 2-cpt clusters get here
	assert(cluster->numComponents() == 2);
	tPPtr ptrQ1 = cluster->particle(0);
	tPPtr ptrQ2 = cluster->particle(1);
	Energy Mc = cluster->mass();
	assert(ptrQ1);
	assert(ptrQ2);

	// And check if those particles are from a beam remnant
	bool rem1 = cluster->isBeamRemnant(0);
	bool rem2 = cluster->isBeamRemnant(1);
	// workout which distribution to use
	bool soft1(false),soft2(false);
	switch (_iopRem) {
	case 0:
	soft1 = rem1 \|\| rem2;
	soft2 = rem2 \|\| rem1;
	break;
	case 1:
	soft1 = rem1;
	soft2 = rem2;
	break;
	}
	// Initialization for the exponential ("soft") mass distribution.
	static const int max_loop = 1000;
	int counter = 0;
	Energy Mc1 = ZERO, Mc2 = ZERO,m1=ZERO,m2=ZERO,m=ZERO;
	tcPDPtr toHadron1, toHadron2;
	PPtr newPtr1 = PPtr ();
	PPtr newPtr2 = PPtr ();
	bool succeeded = false;
	Lorentz5Momentum pClu1, pClu2, pQ1, pQone, pQtwo, pQ2;
	do
	{
	succeeded = false;
	++counter;
	// get a flavour for the qqbar pair
	drawNewFlavour(newPtr1,newPtr2,cluster);
	// check for right ordering
	assert (ptrQ2);
	assert (newPtr2);
	assert (ptrQ2->dataPtr());
	assert (newPtr2->dataPtr());
	if(cantMakeHadron(ptrQ1, newPtr1) \|\| cantMakeHadron(ptrQ2, newPtr2)) {
	swap(newPtr1, newPtr2);
	// check again
	if(cantMakeHadron(ptrQ1, newPtr1) \|\| cantMakeHadron(ptrQ2, newPtr2)) {
	throw Exception()
	<< "ClusterFissioner cannot split the cluster ("
	<< ptrQ1->PDGName() << ' ' << ptrQ2->PDGName()
	<< ") into hadrons.\n" << Exception::runerror;
	}
	}
	// Check that new clusters can produce particles and there is enough
	// phase space to choose the drawn flavour
	m1 = ptrQ1->data().constituentMass();
	m2 = ptrQ2->data().constituentMass();
	m = newPtr1->data().constituentMass();
	// Do not split in the case there is no phase space available
	if(Mc < m1+m + m2+m) continue;

	pQ1.setMass(m1);
	pQone.setMass(m);
	pQtwo.setMass(m);
	pQ2.setMass(m2);

	double weightMasses = drawNewMasses(Mc, soft1, soft2, pClu1, pClu2,
	ptrQ1, pQ1, newPtr1, pQone,
	newPtr2, pQtwo, ptrQ2, pQ2);
	if (weightMasses==0.0)
	continue;

	// derive the masses of the children
	Mc1 = pClu1.mass();
	Mc2 = pClu2.mass();
	// static kinematic threshold
	if(_kinematicThresholdChoice == 0) {
	if (Mc1 < m1+m \|\| Mc2 < m+m2 \|\| Mc1+Mc2 > Mc) continue;
	if (_phaseSpaceWeights==2 &&
	( Mc1 < spectrum()->massLightestHadronPair(ptrQ1->dataPtr(),newPtr1->dataPtr())
	\|\| Mc2 < spectrum()->massLightestHadronPair(ptrQ2->dataPtr(),newPtr2->dataPtr()) ))
	continue;
	// dynamic kinematic threshold
	}
	else if(_kinematicThresholdChoice == 1) {
	bool C1 = ( sqr(Mc1) )/( sqr(m1) + sqr(m) + _kinThresholdShift ) < 1.0 ? true : false;
	bool C2 = ( sqr(Mc2) )/( sqr(m2) + sqr(m) + _kinThresholdShift ) < 1.0 ? true : false;
	bool C3 = ( sqr(Mc1) + sqr(Mc2) )/( sqr(Mc) ) > 1.0 ? true : false;

	if( C1 \|\| C2 \|\| C3 ) continue;
	}
	if ( _phaseSpaceWeights && phaseSpaceVeto(Mc,Mc1,Mc2,m,m1,m2, ptrQ1, ptrQ2, newPtr1, 0.0) ) {
	// reduce counter as it regards only the mass sampling
	counter--;
	continue;
	}

	/**************************
	* New (not present in Fortran Herwig):
	* check whether the fragment masses Mc1 and Mc2 are above the
	* threshold for the production of the lightest pair of hadrons with the
	* right flavours. If not, then set by hand the mass to the lightest
	* single hadron with the right flavours, in order to solve correctly
	* the kinematics, and (later in this method) create directly such hadron
	* and add it to the children hadrons of the cluster that undergoes the
	* fission (i.e. the one pointed by iCluPtr). Notice that in this special
	* case, the heavy cluster that undergoes the fission has one single
	* cluster child and one single hadron child. We prefer this approach,
	* rather than to create a light cluster, with the mass set equal to
	* the lightest hadron, and let then the class LightClusterDecayer to do
	* the job to decay it to that single hadron, for two reasons:
	* First, because the sum of the masses of the two constituents can be,
	* in this case, greater than the mass of that hadron, hence it would
	* be impossible to solve the kinematics for such two components, and
	* therefore we would have a cluster whose components are undefined.
	* Second, the algorithm is faster, because it avoids the reshuffling
	* procedure that would be necessary if we used LightClusterDecayer
	* to decay the light cluster to the lightest hadron.
	****************************/
	// override chosen masses if needed
	toHadron1 = _hadronSpectrum->chooseSingleHadron(ptrQ1->dataPtr(), newPtr1->dataPtr(),Mc1);
	if(toHadron1) { Mc1 = toHadron1->mass(); pClu1.setMass(Mc1); }
	toHadron2 = _hadronSpectrum->chooseSingleHadron(ptrQ2->dataPtr(), newPtr2->dataPtr(),Mc2);
	if(toHadron2) { Mc2 = toHadron2->mass(); pClu2.setMass(Mc2); }
	// if a beam cluster not allowed to decay to hadrons
	if(cluster->isBeamCluster() && (toHadron1\|\|toHadron2) && softUEisOn)
	continue;
	// Check if the decay kinematics is still possible: if not then
	// force the one-hadron decay for the other cluster as well.
	if(Mc1 + Mc2 > Mc) {
	if(!toHadron1) {
	toHadron1 = _hadronSpectrum->chooseSingleHadron(ptrQ1->dataPtr(), newPtr1->dataPtr(),Mc-Mc2);
	if(toHadron1) { Mc1 = toHadron1->mass(); pClu1.setMass(Mc1); }
	}
	else if(!toHadron2) {
	toHadron2 = _hadronSpectrum->chooseSingleHadron(ptrQ2->dataPtr(), newPtr2->dataPtr(),Mc-Mc1);
	if(toHadron2) { Mc2 = toHadron2->mass(); pClu2.setMass(Mc2); }
	}
	}
	succeeded = (Mc >= Mc1+Mc2);
	}
	while (!succeeded && counter < max_loop);

	if(counter >= max_loop) {
	static const PPtr null = PPtr();
	return cutType(PPair(null,null),PPair(null,null));
	}

	// Determined the (5-components) momenta (all in the LAB frame)
	Lorentz5Momentum pClu = cluster->momentum(); // known
	Lorentz5Momentum p0Q1 = ptrQ1->momentum(); // known (mom Q1 before fission)
	calculateKinematics(pClu,p0Q1,toHadron1,toHadron2,
	pClu1,pClu2,pQ1,pQone,pQtwo,pQ2);

	/******************
	* The previous methods have determined the kinematics and positions
	* of C -> C1 + C2.
	* In the case that one of the two product is light, that means either
	* decayOneHadronClu1 or decayOneHadronClu2 is true, then the momenta
	* of the components of that light product have not been determined,
	* and a (light) cluster will not be created: the heavy father cluster
	* decays, in this case, into a single (not-light) cluster and a
	* single hadron. In the other, "normal", cases the father cluster
	* decays into two clusters, each of which has well defined components.
	* Notice that, in the case of components which point to particles, the
	* momenta of the components is properly set to the new values, whereas
	* we do not change the momenta of the pointed particles, because we
	* want to keep all of the information (that is the new momentum of a
	* component after the splitting, which is contained in the _momentum
	* member of the Component class, and the (old) momentum of that component
	* before the splitting, which is contained in the momentum of the
	* pointed particle). Please not make confusion of this only apparent
	* inconsistency!
	********************/
	LorentzPoint posC,pos1,pos2;
	posC = cluster->vertex();
	calculatePositions(pClu, posC, pClu1, pClu2, pos1, pos2);
	cutType rval;
	if(toHadron1) {
	rval.first = produceHadron(toHadron1, newPtr1, pClu1, pos1);
	finalhadrons.push_back(rval.first.first);
	}
	else {
	rval.first = produceCluster(ptrQ1, newPtr1, pClu1, pos1, pQ1, pQone, rem1);
	}
	if(toHadron2) {
	rval.second = produceHadron(toHadron2, newPtr2, pClu2, pos2);
	finalhadrons.push_back(rval.second.first);
	}
	else {
	rval.second = produceCluster(ptrQ2, newPtr2, pClu2, pos2, pQ2, pQtwo, rem2);
	}
	return rval;
	}

	ClusterFissioner::cutType
	ClusterFissioner::cutThree(ClusterPtr & cluster, tPVector & finalhadrons,
	bool softUEisOn) {
	// need to make sure only 3-cpt clusters get here
	assert(cluster->numComponents() == 3);
	// extract quarks
	tPPtr ptrQ[3] = {cluster->particle(0),cluster->particle(1),cluster->particle(2)};
	assert( ptrQ[0] && ptrQ[1] && ptrQ[2] );
	// find maximum mass pair
	Energy mmax(ZERO);
	Lorentz5Momentum pDiQuark;
	int iq1(-1),iq2(-1);
	Lorentz5Momentum psum;
	for(int q1=0;q1<3;++q1) {
	psum+= ptrQ[q1]->momentum();
	for(int q2=q1+1;q2<3;++q2) {
	Lorentz5Momentum ptest = ptrQ[q1]->momentum()+ptrQ[q2]->momentum();
	ptest.rescaleMass();
	Energy mass = ptest.m();
	if(mass>mmax) {
	mmax = mass;
	pDiQuark = ptest;
	iq1 = q1;
	iq2 = q2;
	}
	}
	}
	// and the spectators
	int iother(-1);
	for(int ix=0;ix<3;++ix) if(ix!=iq1&&ix!=iq2) iother=ix;
	assert(iq1>=0&&iq2>=0&&iother>=0);

	// And check if those particles are from a beam remnant
	bool rem1 = cluster->isBeamRemnant(iq1);
	bool rem2 = cluster->isBeamRemnant(iq2);
	// workout which distribution to use
	bool soft1(false),soft2(false);
	switch (_iopRem) {
	case 0:
	soft1 = rem1 \|\| rem2;
	soft2 = rem2 \|\| rem1;
	break;
	case 1:
	soft1 = rem1;
	soft2 = rem2;
	break;
	}
	// Initialization for the exponential ("soft") mass distribution.
	static const int max_loop = 1000;
	int counter = 0;
	Energy Mc1 = ZERO, Mc2 = ZERO, m1=ZERO, m2=ZERO, m=ZERO;
	tcPDPtr toHadron;
	bool toDiQuark(false);
	PPtr newPtr1 = PPtr(),newPtr2 = PPtr();
	PDPtr diquark;
	bool succeeded = false;
	Lorentz5Momentum pClu1, pClu2, pQ1, pQone, pQtwo, pQ2;
	do {
	succeeded = false;
	++counter;

	// get a flavour for the qqbar pair
	drawNewFlavour(newPtr1,newPtr2,cluster);

	// randomly pick which will be (anti)diquark and which a mesonic cluster
	if(UseRandom::rndbool()) {
	swap(iq1,iq2);
	swap(rem1,rem2);
	}
	// check first order
	if(cantMakeHadron(ptrQ[iq1], newPtr1) \|\| !spectrum()->canMakeDiQuark(ptrQ[iq2], newPtr2)) {
	swap(newPtr1,newPtr2);
	}
	// check again
	if(cantMakeHadron(ptrQ[iq1], newPtr1) \|\| !spectrum()->canMakeDiQuark(ptrQ[iq2], newPtr2)) {
	throw Exception()
	<< "ClusterFissioner cannot split the cluster ("
	<< ptrQ[iq1]->PDGName() << ' ' << ptrQ[iq2]->PDGName()
	<< ") into a hadron and diquark.\n" << Exception::runerror;
	}
	// Check that new clusters can produce particles and there is enough
	// phase space to choose the drawn flavour
	m1 = ptrQ[iq1]->data().constituentMass();
	m2 = ptrQ[iq2]->data().constituentMass();
	m = newPtr1->data().constituentMass();
	// Do not split in the case there is no phase space available
	if(mmax < m1+m + m2+m) continue;

	pQ1.setMass(m1);
	pQone.setMass(m);
	pQtwo.setMass(m);
	pQ2.setMass(m2);

	double weightMasses = drawNewMasses(mmax, soft1, soft2, pClu1, pClu2,
	ptrQ[iq1], pQ1, newPtr1, pQone,
	newPtr2, pQtwo, ptrQ[iq1], pQ2);

	if (weightMasses == 0.0) continue;

	Mc1 = pClu1.mass();
	Mc2 = pClu2.mass();

	if(Mc1 < m1+m \|\| Mc2 < m+m2 \|\| Mc1+Mc2 > mmax) continue;

	if ( _phaseSpaceWeights && phaseSpaceVeto(mmax,Mc1,Mc2,m,m1,m2) ) {
	// reduce counter as it regards only the mass sampling
	counter--;
	continue;
	}

	// check if need to force meson clster to hadron
	toHadron = _hadronSpectrum->chooseSingleHadron(ptrQ[iq1]->dataPtr(), newPtr1->dataPtr(),Mc1);
	if(toHadron) { Mc1 = toHadron->mass(); pClu1.setMass(Mc1); }
	// check if need to force diquark cluster to be on-shell
	toDiQuark = false;
	diquark = spectrum()->makeDiquark(ptrQ[iq2]->dataPtr(), newPtr2->dataPtr());
	if(Mc2 < diquark->constituentMass()) {
	Mc2 = diquark->constituentMass(); pClu2.setMass(Mc2);
	toDiQuark = true;
	}
	// if a beam cluster not allowed to decay to hadrons
	if(cluster->isBeamCluster() && toHadron && softUEisOn)
	continue;
	// Check if the decay kinematics is still possible: if not then
	// force the one-hadron decay for the other cluster as well.
	if(Mc1 + Mc2 > mmax) {
	if(!toHadron) {
	toHadron = _hadronSpectrum->chooseSingleHadron(ptrQ[iq1]->dataPtr(), newPtr1->dataPtr(),mmax-Mc2);
	if(toHadron) { Mc1 = toHadron->mass(); pClu1.setMass(Mc1); }
	}
	else if(!toDiQuark) {
	Mc2 = _hadronSpectrum->massLightestHadron(ptrQ[iq2]->dataPtr(), newPtr2->dataPtr()); pClu2.setMass(Mc2);
	toDiQuark = true;
	}
	}
	succeeded = (mmax >= Mc1+Mc2);
	}
	while (!succeeded && counter < max_loop);
	// check no of tries
	if(counter >= max_loop) return cutType();

	// Determine the (5-components) momenta (all in the LAB frame)
	Lorentz5Momentum p0Q1 = ptrQ[iq1]->momentum();
	calculateKinematics(pDiQuark,p0Q1,toHadron,toDiQuark,
	pClu1,pClu2,pQ1,pQone,pQtwo,pQ2);
	// positions of the new clusters
	LorentzPoint pos1,pos2;
	Lorentz5Momentum pBaryon = pClu2+ptrQ[iother]->momentum();
	calculatePositions(cluster->momentum(), cluster->vertex(), pClu1, pBaryon, pos1, pos2);
	// first the mesonic cluster/meson
	cutType rval;
	if(toHadron) {
	rval.first = produceHadron(toHadron, newPtr1, pClu1, pos1);
	finalhadrons.push_back(rval.first.first);
	}
	else {
	rval.first = produceCluster(ptrQ[iq1], newPtr1, pClu1, pos1, pQ1, pQone, rem1);
	}
	if(toDiQuark) {
	rem2 \|= cluster->isBeamRemnant(iother);
	PPtr newDiQuark = diquark->produceParticle(pClu2);
	rval.second = produceCluster(newDiQuark, ptrQ[iother], pBaryon, pos2, pClu2,
	ptrQ[iother]->momentum(), rem2);
	}
	else {
	rval.second = produceCluster(ptrQ[iq2], newPtr2, pBaryon, pos2, pQ2, pQtwo, rem2,
	ptrQ[iother],cluster->isBeamRemnant(iother));
	}
	cluster->isAvailable(false);
	return rval;
	}

	ClusterFissioner::PPair
	ClusterFissioner::produceHadron(tcPDPtr hadron, tPPtr newPtr, const Lorentz5Momentum &a,
	const LorentzPoint &b) const {
	PPair rval;
	if(hadron->coloured()) {
	rval.first = (_hadronSpectrum->lightestHadron(hadron,newPtr->dataPtr()))->produceParticle();
	}
	else
	rval.first = hadron->produceParticle();
	rval.second = newPtr;
	rval.first->set5Momentum(a);
	rval.first->setVertex(b);
	return rval;
	}

	ClusterFissioner::PPair ClusterFissioner::produceCluster(tPPtr ptrQ, tPPtr newPtr,
	const Lorentz5Momentum & a,
	const LorentzPoint & b,
	const Lorentz5Momentum & c,
	const Lorentz5Momentum & d,
	bool isRem,
	tPPtr spect, bool remSpect) const {
	PPair rval;
	rval.second = newPtr;
	ClusterPtr cluster = !spect ? new_ptr(Cluster(ptrQ,rval.second)) : new_ptr(Cluster(ptrQ,rval.second,spect));
	rval.first = cluster;
	cluster->set5Momentum(a);
	cluster->setVertex(b);
	assert(cluster->particle(0)->id() == ptrQ->id());
	cluster->particle(0)->set5Momentum(c);
	cluster->particle(1)->set5Momentum(d);
	cluster->setBeamRemnant(0,isRem);
	if(remSpect) cluster->setBeamRemnant(2,remSpect);
	return rval;
	}

	/**
	* Calculate the phase space weight for M1M2(2 body PhaseSpace) ignore constituent masses
	*/
	double ClusterFissioner::weightFlatPhaseSpaceNoConstituentMasses(const Energy Mc, const Energy Mc1, const Energy Mc2) const {
	double M_temp = Mc/GeV;
	double M1_temp = Mc1/GeV;
	double M2_temp = Mc2/GeV;
	if (sqr(M_temp)<sqr(M1_temp+M2_temp)) {
	// This should be checked before
	throw Exception()
	<< "ERROR in ClusterFissioner::weightFlatPhaseSpaceNoConstituentMasses\n"
	<< "ClusterFissioner has not checked Masses properly\n"
	<< "Mc = " << M_temp << "\n"
	<< "Mc1 = " << M1_temp << "\n"
	<< "Mc2 = " << M2_temp << "\n"
	<< Exception::warning;
	return 0.0;
	}
	double lam = Kinematics::kaellen(M_temp, M1_temp, M2_temp);
	double ratio;
	// new weight with the Jacobi factor M1*M2 of the Mass integration
	double PSweight = M1_tempM2_temppow(sqrt(lam),_dim-3.);
	// overestimate only possible for dim>=3.0
	assert(_dim>=3.0);
	// new improved overestimate with the Jacobi factor M1*M2 of the Mass integration
	double overEstimate = pow(6.0sqrt(3.0), 3.0 - _dim)pow(M_temp, 2.*(_dim-2.));
	ratio = PSweight/overEstimate;
	if (!(ratio>=0) \|\| !(ratio<=1)) {
	throw Exception()
	<< "ERROR in ClusterFissioner::weightFlatPhaseSpaceNoConstituentMasses\n"
	<< "ratio = " <<ratio
	<<" M "<<M_temp
	<<" M1 "<<M1_temp
	<<" M2 "<<M2_temp <<"\t"<<_dim<<"\t" << lam
	<<"\t"<< overEstimate<<"\n\n"
	<< Exception::runerror;
	}
	return ratio;
	}
	/**
	* Calculate the phase space weight for M1M2(2 body PhaseSpace)^3
	*/
	double ClusterFissioner::weightPhaseSpaceConstituentMasses(const Energy Mc, const Energy Mc1, const Energy Mc2,
	const Energy m, const Energy m1, const Energy m2, const double power) const {
	double M_temp = Mc/GeV;
	double M1_temp = Mc1/GeV;
	double M2_temp = Mc2/GeV;
	double m_temp = m/GeV;
	double m1_temp = m1/GeV;
	double m2_temp = m2/GeV;
	if (sqr(M_temp)<sqr(M1_temp+M2_temp)
	\|\| sqr(M1_temp)<sqr(m1_temp+m_temp)
	\|\| sqr(M2_temp)<sqr(m2_temp+m_temp)
	) {
	// This should be checked before
	throw Exception()
	<< "ERROR in ClusterFissioner::weightPhaseSpaceConstituentMasses\n"
	<< "ClusterFissioner has not checked Masses properly\n"
	<< "Mc = " << M_temp << "\n"
	<< "Mc1 = " << M1_temp << "\n"
	<< "Mc2 = " << M2_temp << "\n"
	<< "m1 = " << m1_temp << "\n"
	<< "m2 = " << m2_temp << "\n"
	<< "m = " << m_temp << "\n"
	<< Exception::warning;
	return 0.0;
	}
	double lam1 = Kinematics::kaellen(M1_temp, m1_temp, m_temp);
	double lam2 = Kinematics::kaellen(M2_temp, m2_temp, m_temp);
	double lam3 = Kinematics::kaellen(M_temp, M1_temp, M2_temp);
	double ratio;
	// new weight with the Jacobi factor M1*M2 of the Mass integration
	double PSweight = pow(lam1lam2lam3,(_dim-3.)/2.0)pow(M1_tempM2_temp,3.-_dim);
	// overestimate only possible for dim>=3.0
	assert(_dim>=3.0);
	// new improved overestimate with the Jacobi factor M1*M2 of the Mass integration
	double overEstimate = pow(6.0sqrt(3.0), 3.0 - _dim)pow(M_temp, 4.*_dim-12.);
	ratio = PSweight/overEstimate;
	if (!(ratio>=0)) std::cout << "ratio = " <<ratio<<" M "<<M_temp<<" M1 "<<M1_temp<<" M2 "<<M2_temp<<" m1 "<<m1_temp<<" m2 "<<m2_temp<<" m "<<m_temp<<"\t"<<_dim<<"\t" << lam1<<"\t"<< lam2<<"\t" << lam3 <<"\t"<< overEstimate<<"\n\n";
	if (!(ratio>=0) \|\| !(ratio<=1)) {
	throw Exception()
	<< "ERROR in ClusterFissioner::weightPhaseSpaceConstituentMasses\n"
	<< "ratio = " <<ratio
	<<" M "<<M_temp
	<<" M1 "<<M1_temp
	<<" M2 "<<M2_temp
	<<" m1 "<<m1_temp
	<<" m2 "<<m2_temp
	<<" m "<<m_temp <<"\t"<<_dim
	<<"\t" << lam1<<"\t"<< lam2<<"\t" << lam3
	<<"\t"<< overEstimate<<"\n\n"
	<< Exception::runerror;
	}
	// multiply by overestimate of power of matrix element to modulate the phase space with (M1*M2)^power
	if (power) {
	double powerLawOver = power<0 ? pow(Mc1Mc2/((m1+m)(m2+m)),power):pow(Mc1Mc2/((Mc-(m1+m))(Mc-(m2+m))),power);
	ratio*=powerLawOver;
	}
	return ratio;
	}
	/**
	* Calculate the phase space weight for M1M2(2 body PhaseSpace)^3
	* using Hadron Masses
	*/
	double ClusterFissioner::weightFlatPhaseSpaceHadronMasses(const Energy Mc, const Energy Mc1, const Energy Mc2, tcPPtr pQ, tcPPtr pQ1, tcPPtr pQ2) const {
	auto LHP1 = spectrum()->lightestHadronPair(pQ1->dataPtr(),pQ->dataPtr());
	auto LHP2 = spectrum()->lightestHadronPair(pQ2->dataPtr(),pQ->dataPtr());
	if (sqr(Mc1)<sqr(LHP1.first->mass()+LHP1.second->mass()))
	return true;
	if (sqr(Mc2)<sqr(LHP2.first->mass()+LHP2.second->mass()))
	return true;
	double lam1 = sqrt(Kinematics::kaellen(Mc1/GeV, LHP1.first->mass()/GeV, LHP1.second->mass()/GeV));
	double lam2 = sqrt(Kinematics::kaellen(Mc2/GeV, LHP2.first->mass()/GeV, LHP2.second->mass()/GeV));
	double lam3 = sqrt(Kinematics::kaellen(Mc/GeV, Mc1/GeV, Mc2/GeV));
	double ratio;
	// new weight with the Jacobi factor M1*M2 of the Mass integration
	double PSweight = pow(lam1lam2lam3,_dim-3.)pow(Mc1Mc2/GeV2,3.-_dim);
	// overestimate only possible for dim>=3.0
	assert(_dim>=3.0);
	// new improved overestimate with the Jacobi factor M1*M2 of the Mass integration
	double overEstimate = pow(6.0sqrt(3.0), 3.0 - _dim)pow(Mc/GeV, 4.*_dim-12.);
	ratio = PSweight/overEstimate;
	if (!(ratio>=0) \|\| !(ratio<=1)) {
	throw Exception()
	<< "ERROR in ClusterFissioner::weightFlatPhaseSpaceHadronMasses\n"
	<< "ratio = " <<ratio
	<<" M "<<Mc/GeV
	<<" M1 "<<Mc1/GeV
	<<" M2 "<<Mc2/GeV <<"\t"<<_dim<<"\t" << lam1<<"\t" << lam2 <<"\t" << lam3
	<<"\t"<< overEstimate<<"\n\n"
	<< Exception::runerror;
	}
	return ratio;
	}

	/**
	* Veto for the phase space weight
	* returns true if proposed Masses are rejected
	* else returns false
	*/
	bool ClusterFissioner::phaseSpaceVeto(const Energy Mc, const Energy Mc1, const Energy Mc2,
	const Energy m, const Energy m1, const Energy m2, tcPPtr pQ1, tcPPtr pQ2, tcPPtr pQ, const double power) const {
	switch (_phaseSpaceWeights)
	{
	case 1:
	return phaseSpaceVetoConstituentMasses(Mc, Mc1, Mc2, m, m1, m2, power);
	case 2:
	return phaseSpaceVetoHadronPairs(Mc, Mc1, Mc2, pQ, pQ1, pQ2);
	case 3:
	return phaseSpaceVetoNoConstituentMasses(Mc, Mc1, Mc2);
	default:
	assert(false);
	}
	}

	/**
	* Veto for the phase space weight
	* returns true if proposed Masses are rejected
	* else returns false
	*/
	bool ClusterFissioner::phaseSpaceVetoConstituentMasses(const Energy Mc, const Energy Mc1, const Energy Mc2,
	const Energy m, const Energy m1, const Energy m2, const double power) const {
	return (UseRandom::rnd()>weightPhaseSpaceConstituentMasses(Mc, Mc1, Mc2, m, m1, m2, power));
	}
	bool ClusterFissioner::phaseSpaceVetoNoConstituentMasses(const Energy Mc, const Energy Mc1, const Energy Mc2) const {
	return (UseRandom::rnd()>weightFlatPhaseSpaceNoConstituentMasses(Mc, Mc1, Mc2));
	}

	bool ClusterFissioner::phaseSpaceVetoHadronPairs(const Energy Mc, const Energy Mc1, const Energy Mc2, tcPPtr pQ, tcPPtr pQ1, tcPPtr pQ2) const {
	return (UseRandom::rnd()>weightFlatPhaseSpaceHadronMasses(Mc, Mc1, Mc2, pQ, pQ1, pQ2));
	}

	/**
	* Calculate the masses and possibly kinematics of the cluster
	* fission at hand; if calculateKineamtics is perfomring non-trivial
	* steps kinematics claulcated here will be overriden. Currentl;y resorts to the default
	*/
	double ClusterFissioner::drawNewMasses(const Energy Mc, const bool soft1, const bool soft2,
	Lorentz5Momentum& pClu1, Lorentz5Momentum& pClu2,
	tcPPtr ptrQ1, const Lorentz5Momentum& pQ1,
	tcPPtr, const Lorentz5Momentum& pQone,
	tcPPtr, const Lorentz5Momentum& pQtwo,
	tcPPtr ptrQ2, const Lorentz5Momentum& pQ2) const {
	// power for splitting
	double exp1 = !spectrum()->isExotic(ptrQ1->dataPtr()) ? _pSplitLight : _pSplitExotic;
	double exp2 = !spectrum()->isExotic(ptrQ2->dataPtr()) ? _pSplitLight : _pSplitExotic;
	for ( const long& id : spectrum()->heavyHadronizingQuarks() ) {
	assert(_pSplitHeavy.find(id) != _pSplitHeavy.end());
	if ( spectrum()->hasHeavy(id,ptrQ1->dataPtr()) ) exp1 = _pSplitHeavy.find(id)->second;
	if ( spectrum()->hasHeavy(id,ptrQ2->dataPtr()) ) exp2 = _pSplitHeavy.find(id)->second;
	}

	Energy M1 = drawChildMass(Mc,pQ1.mass(),pQ2.mass(),pQone.mass(),exp1,soft1);
	Energy M2 = drawChildMass(Mc,pQ2.mass(),pQ1.mass(),pQtwo.mass(),exp2,soft2);

	pClu1.setMass(M1);
	pClu2.setMass(M2);

	return 1.0; // succeeds
	}


	void ClusterFissioner::drawNewFlavourDiquarks(PPtr& newPtrPos,PPtr& newPtrNeg,
	const ClusterPtr & clu) const {

	// Flavour is assumed to be only u, d, s, with weights
	// (which are not normalized probabilities) given
	// by the same weights as used in HadronsSelector for
	// the decay of clusters into two hadrons.

	unsigned hasDiquarks=0;
	assert(clu->numComponents()==2);
	tcPDPtr pD1=clu->particle(0)->dataPtr();
	tcPDPtr pD2=clu->particle(1)->dataPtr();
	bool isDiq1=DiquarkMatcher::Check(pD1->id());
	if (isDiq1) hasDiquarks++;
	bool isDiq2=DiquarkMatcher::Check(pD2->id());
	if (isDiq2) hasDiquarks++;
	assert(hasDiquarks<=2);
	Energy Mc=(clu->momentum().mass());
	Energy minMass;
	double weight;
	Selector<long> choice;
	// adding quark-antiquark pairs to the selection list
	for ( const long& id : spectrum()->lightHadronizingQuarks() ) {
	minMass=spectrum()->massLightestHadronPair(pD1,pD2);
	if (_fissionCluster==0) choice.insert(_hadronSpectrum->pwtQuark(id),id);
	else if (abs(_fissionCluster)==1) choice.insert(_fissionPwt.find(id)->second,id);
	else assert(false);
	}
	// adding diquark-antidiquark pairs to the selection list
	switch (hasDiquarks)
	{
	case 0:
	for ( const long& id : spectrum()->lightHadronizingDiquarks() ) {
	if (_strictDiquarkKinematics) {
	tPDPtr cand = getParticleData(id);
	Energy mH1=spectrum()->massLightestHadron(pD2,cand);
	Energy mH2=spectrum()->massLightestHadron(cand,pD1);
	minMass = mH1 + mH2;
	}
	else {
	minMass = spectrum()->massLightestBaryonPair(pD1,pD2);
	}
	if (Mc < minMass) continue;
	if (_fissionCluster==0) weight = _hadronSpectrum->pwtQuark(id);
	else if (abs(_fissionCluster)==1) weight = _fissionPwt.find(id)->second;
	else assert(false);
	if (_fissionCluster==-1)
	weight=sqr(Herwig::Math::alphaS(Mc, 0.25GeV,3, 2));
	choice.insert(weight,id);
	}
	break;
	case 1:
	if (_diquarkClusterFission<1) break;
	for ( const long& id : spectrum()->lightHadronizingDiquarks() ) {
	tPDPtr diq = getParticleData(id);
	if (isDiq1)
	minMass = spectrum()->massLightestHadron(pD2,diq)
	+ spectrum()->massLightestBaryonPair(diq,pD1);
	else
	minMass = spectrum()->massLightestHadron(pD1,diq)
	+ spectrum()->massLightestBaryonPair(diq,pD2);
	if (Mc < minMass) continue;
	if (_fissionCluster==0) weight = _hadronSpectrum->pwtQuark(id);
	else if (abs(_fissionCluster)==1) weight = _fissionPwt.find(id)->second;
	else assert(false);
	if (_fissionCluster==-1)
	weight=sqr(Herwig::Math::alphaS(Mc, 0.25GeV,3, 2));
	choice.insert(weight,id);
	}
	break;
	case 2:
	if (_diquarkClusterFission<2) break;
	for ( const long& id : spectrum()->lightHadronizingDiquarks() ) {
	tPDPtr diq = getParticleData(id);
	if (Mc < spectrum()->massLightestBaryonPair(pD1,pD2)) {
	throw Exception() << "Found Diquark Cluster:\n" << *clu << "\nwith MassCluster = "
	<< Mc/GeV <<" GeV MassLightestBaryonPair = "
	<< spectrum()->massLightestBaryonPair(pD1,pD2)/GeV
	<< " GeV cannot decay" << Exception::eventerror;
	}
	minMass = spectrum()->massLightestBaryonPair(pD1,diq)
	+ spectrum()->massLightestBaryonPair(diq,pD2);
	if (Mc < minMass) continue;
	if (_fissionCluster==0) weight = _hadronSpectrum->pwtQuark(id);
	else if (abs(_fissionCluster)==1) weight = _fissionPwt.find(id)->second;
	else assert(false);
	if (_fissionCluster==-1)
	weight=sqr(Herwig::Math::alphaS(Mc, 0.25GeV,3, 2));
	choice.insert(weight,id);
	}
	break;
	default:
	assert(false);
	}
	assert(choice.size()>0);
	long idNew = choice.select(UseRandom::rnd());
	newPtrPos = getParticle(idNew);
	newPtrNeg = getParticle(-idNew);
	assert(newPtrPos);
	assert(newPtrNeg);
	assert(newPtrPos->dataPtr());
	assert(newPtrNeg->dataPtr());

	}

	void ClusterFissioner::drawNewFlavourQuarks(PPtr& newPtrPos,PPtr& newPtrNeg) const {

	// Flavour is assumed to be only u, d, s, with weights
	// (which are not normalized probabilities) given
	// by the same weights as used in HadronsSelector for
	// the decay of clusters into two hadrons.


	Selector<long> choice;
	switch(abs(_fissionCluster)){
	case 0:
	for ( const long& id : spectrum()->lightHadronizingQuarks() )
	choice.insert(_hadronSpectrum->pwtQuark(id),id);
	break;
	case 1:
	for ( const long& id : spectrum()->lightHadronizingQuarks() )
	choice.insert(_fissionPwt.find(id)->second,id);
	break;
	default :
	assert(false);
	}
	long idNew = choice.select(UseRandom::rnd());
	newPtrPos = getParticle(idNew);
	newPtrNeg = getParticle(-idNew);
	assert (newPtrPos);
	assert(newPtrNeg);
	assert (newPtrPos->dataPtr());
	assert(newPtrNeg->dataPtr());

	}

	void ClusterFissioner::drawNewFlavourEnhanced(PPtr& newPtrPos,PPtr& newPtrNeg,
	- Energy2 mass2) const {
	+ const ClusterPtr & clu) const {

	- if ( spectrum()->gluonId() != ParticleID::g )
	- throw Exception() << "strange enhancement only working with Standard Model hadronization"
	- << Exception::runerror;
	-
	- // Flavour is assumed to be only u, d, s, with weights
	- // (which are not normalized probabilities) given
	- // by the same weights as used in HadronsSelector for
	- // the decay of clusters into two hadrons.
	+ if ( spectrum()->gluonId() != ParticleID::g )
	+ throw Exception() << "strange enhancement only working with Standard Model hadronization"
	+ << Exception::runerror;

	- double prob_d = 0.;
	- double prob_u = 0.;
	- double prob_s = 0.;
	- double scale = abs(double(sqr(_m0Fission)/mass2));
	- // Choose which splitting weights you wish to use
	-switch(abs(_fissionCluster)){
	- // 0: ClusterFissioner and ClusterDecayer use the same weights
	- case 0:
	- prob_d = _hadronSpectrum->pwtQuark(ParticleID::d);
	- prob_u = _hadronSpectrum->pwtQuark(ParticleID::u);
	- /* Strangeness enhancement:
	- Case 1: probability scaling
	- Case 2: Exponential scaling
	- */
	- if (_enhanceSProb == 1)
	- prob_s = (_maxScale < scale) ? 0. : pow(_hadronSpectrum->pwtQuark(ParticleID::s),scale);
	- else if (_enhanceSProb == 2)
	- prob_s = (_maxScale < scale) ? 0. : exp(-scale);
	- break;
	- /* 1: ClusterFissioner uses its own unique set of weights,
	- i.e. decoupled from ClusterDecayer */
	- case 1:
	- prob_d = _fissionPwt.find(ParticleID::d)->second;
	- prob_u = _fissionPwt.find(ParticleID::u)->second;
	- if (_enhanceSProb == 1)
	- prob_s = (_maxScale < scale) ? 0. : pow(_fissionPwt.find(ParticleID::s)->second,scale);
	- else if (_enhanceSProb == 2)
	- prob_s = (_maxScale < scale) ? 0. : exp(-scale);
	- break;
	- default:
	- assert(false);
	- }
	+ Energy2 mass2 = clustermass(clu);
	+ // Flavour is assumed to be only u, d, s, with weights
	+ // (which are not normalized probabilities) given
	+ // by the same weights as used in HadronsSelector for
	+ // the decay of clusters into two hadrons.

	- int choice = UseRandom::rnd3(prob_u, prob_d, prob_s);
	- long idNew = 0;
	- switch (choice) {
	- case 0: idNew = ThePEG::ParticleID::u; break;
	- case 1: idNew = ThePEG::ParticleID::d; break;
	- case 2: idNew = ThePEG::ParticleID::s; break;
	- }
	- newPtrPos = getParticle(idNew);
	- newPtrNeg = getParticle(-idNew);
	- assert (newPtrPos);
	- assert(newPtrNeg);
	- assert (newPtrPos->dataPtr());
	- assert(newPtrNeg->dataPtr());
	+ double prob_d = 0.;
	+ double prob_u = 0.;
	+ double prob_s = 0.;
	+ double pwts;
	+ double scale = abs(double(sqr(_m0Fission)/mass2));
	+ // Choose which splitting weights you wish to use
	+ switch(abs(_fissionCluster)){
	+ // 0: ClusterFissioner and ClusterDecayer use the same weights
	+ case 0:
	+ {
	+ prob_u = _hadronSpectrum->pwtQuark(ParticleID::u);
	+ prob_d = _hadronSpectrum->pwtQuark(ParticleID::d);
	+ pwts = _hadronSpectrum->pwtQuark(ParticleID::s);
	+ break;
	+ }
	+ /* Strangeness enhancement:
	+ Case 1: probability scaling
	+ Case 2: Exponential scaling
	+ Case 3: NoLightStrangeness
	+ */
	+ // if (_enhanceSProb == 1)
	+ // prob_s = (_maxScale < scale) ? 0. : pow(_hadronSpectrum->pwtQuark(ParticleID::s),scale);
	+ // else if (_enhanceSProb == 2)
	+ // prob_s = (_maxScale < scale) ? 0. : exp(-scale);
	+ // break;
	+ /* 1: ClusterFissioner uses its own unique set of weights,
	+ i.e. decoupled from ClusterDecayer */
	+ case 1:
	+ {
	+ prob_u = _fissionPwt.find(ParticleID::u)->second;
	+ prob_d = _fissionPwt.find(ParticleID::d)->second;
	+ pwts = _fissionPwt.find(ParticleID::s)->second;
	+ // if (_enhanceSProb == 1)
	+ // prob_s = (_maxScale < scale) ? 0. : pow(_fissionPwt.find(ParticleID::s)->second,scale);
	+ // else if (_enhanceSProb == 2)
	+ // prob_s = (_maxScale < scale) ? 0. : exp(-scale);
	+ // break;
	+ break;
	+ }
	+ default:
	+ assert(false);
	+ }
	+
	+ switch (_enhanceSProb)
	+ {
	+ case 1:
	+ {
	+ // Scaling strangeness enhancement
	+ prob_s = (_maxScale < scale) ? 0. : pow(pwts, scale);
	+ break;
	+ }
	+ case 2:
	+ {
	+ // Exponential strangeness enhancement
	+ prob_s = (_maxScale < scale) ? 0. : exp(-scale);
	+ break;
	+ }
	+ case 3:
	+ {
	+ // Strongly ordered strangeness: only if one of the constituents
	+ // are of higher mass than the strange quark allow for the strange
	+ // quark production
	+
	+ // _m0Fission is here the forbidden strangeness hard threshold
	+ if (sqrt(mass2) > _m0Fission) {
	+ prob_s = pwts;
	+ break;
	+ }
	+ assert(clu->numComponents()==2);
	+ unsigned int flav1 = abs(clu->particle(0)->dataPtr()->id());
	+ unsigned int flav2 = abs(clu->particle(1)->dataPtr()->id());
	+ // Light && u,d clusters are forbidden from producing strangeness
	+ prob_s = (flav1>=3 \|\| flav2>=3) ? pwts:0.0;
	+ break;
	+ }
	+ default:
	+ assert(false);
	+ }
	+ int choice = UseRandom::rnd3(prob_u, prob_d, prob_s);
	+ long idNew = 0;
	+ switch (choice) {
	+ case 0: idNew = ThePEG::ParticleID::u; break;
	+ case 1: idNew = ThePEG::ParticleID::d; break;
	+ case 2: idNew = ThePEG::ParticleID::s; break;
	+ }
	+ newPtrPos = getParticle(idNew);
	+ newPtrNeg = getParticle(-idNew);
	+ assert (newPtrPos);
	+ assert(newPtrNeg);
	+ assert (newPtrPos->dataPtr());
	+ assert(newPtrNeg->dataPtr());

	}

	Energy2 ClusterFissioner::clustermass(const ClusterPtr & cluster) const {
	Lorentz5Momentum pIn = cluster->momentum();
	Energy2 endpointmass2 = sqr(cluster->particle(0)->mass() +
	cluster->particle(1)->mass());
	Energy2 singletm2 = pIn.m2();
	// Return either the cluster mass, or the lambda measure
	return (_massMeasure == 0) ? singletm2 : singletm2 - endpointmass2;
	}

	Energy ClusterFissioner::drawChildMass(const Energy M, const Energy m1,
	const Energy m2, const Energy m,
	const double expt, const bool soft) const {

	/***************************
	* This method, given in input the cluster mass Mclu of an heavy cluster C,
	* made of consituents of masses m1 and m2, draws the masses Mclu1 and Mclu2
	* of, respectively, the children cluster C1, made of constituent masses m1
	* and m, and cluster C2, of mass Mclu2 and made of constituent masses m2
	* and m. The mass is extracted from one of the two following mass
	* distributions:
	* --- power-like ("normal" distribution)
	* d(Prob) / d(M^exponent) = const
	* where the exponent can be different from the two children C1 (exp1)
	* and C2 (exponent2).
	* --- exponential ("soft" distribution)
	* d(Prob) / d(M^2) = exp(-b*M)
	* where b = 2.0 / average.
	* Such distributions are limited below by the masses of
	* the constituents quarks, and above from the mass of decaying cluster C.
	* The choice of which of the two mass distributions to use for each of the
	* two cluster children is dictated by iRemnant (see below).
	* If the number of attempts to extract a pair of mass values that are
	* kinematically acceptable is above some fixed number (max_loop, see below)
	* the method gives up and returns false; otherwise, when it succeeds, it
	* returns true.
	*
	* These distributions have been modified from HERWIG:
	* Before these were:
	* Mclu1 = m1 + (Mclu - m1 - m2)*pow( rnd(), 1.0/exponent1 );
	* The new one coded here is a more efficient version, same density
	* but taking into account 'in phase space from' beforehand
	***************************/
	// hard cluster
	if(!soft) {
	return pow(UseRandom::rnd(pow((M-m1-m2-m)*UnitRemoval::InvE, expt),
	pow(m*UnitRemoval::InvE, expt)), 1./expt
	)*UnitRemoval::E + m1;
	}
	// Otherwise it uses a soft mass distribution
	else {
	static const InvEnergy b = 2.0 / _btClM;
	Energy max = M-m1-m2-2.0*m;
	double rmin = b*max;
	rmin = ( rmin < 50 ) ? exp(-rmin) : 0.;
	double r1;
	do {
	r1 = UseRandom::rnd(rmin, 1.0) * UseRandom::rnd(rmin, 1.0);
	}
	while (r1 < rmin);
	return m1 + m - log(r1)/b;
	}
	}

	void ClusterFissioner::calculateKinematics(const Lorentz5Momentum & pClu,
	const Lorentz5Momentum & p0Q1,
	const bool toHadron1,
	const bool toHadron2,
	Lorentz5Momentum & pClu1,
	Lorentz5Momentum & pClu2,
	Lorentz5Momentum & pQ1,
	Lorentz5Momentum & pQbar,
	Lorentz5Momentum & pQ,
	Lorentz5Momentum & pQ2bar) const {

	/******************
	* This method solves the kinematics of the two body cluster decay:
	* C (Q1 Q2bar) ---> C1 (Q1 Qbar) + C2 (Q Q2bar)
	* In input we receive the momentum of C, pClu, and the momentum
	* of the quark Q1 (constituent of C), p0Q1, both in the LAB frame.
	* Furthermore, two boolean variables inform whether the two fission
	* products (C1, C2) decay immediately into a single hadron (in which
	* case the cluster itself is identify with that hadron) and we do
	* not have to solve the kinematics of the components (Q1,Qbar) for
	* C1 and (Q,Q2bar) for C2.
	* The output is given by the following momenta (all 5-components,
	* and all in the LAB frame):
	* pClu1 , pClu2 respectively of C1 , C2
	* pQ1 , pQbar respectively of Q1 , Qbar in C1
	* pQ , pQ2bar respectively of Q , Q2 in C2
	* The assumption, suggested from the string model, is that, in C frame,
	* C1 and its constituents Q1 and Qbar are collinear, and collinear to
	* the direction of Q1 in C (that is before cluster decay); similarly,
	* (always in the C frame) C2 and its constituents Q and Q2bar are
	* collinear (and therefore anti-collinear with C1,Q1,Qbar).
	* The solution is then obtained by using Lorentz boosts, as follows.
	* The kinematics of C1 and C2 is solved in their parent C frame,
	* and then boosted back in the LAB. The kinematics of Q1 and Qbar
	* is solved in their parent C1 frame and then boosted back in the LAB;
	* similarly, the kinematics of Q and Q2bar is solved in their parent
	* C2 frame and then boosted back in the LAB. In each of the three
	* "two-body decay"-like cases, we use the fact that the direction
	* of the motion of the decay products is known in the rest frame of
	* their parent. This is obvious for the first case in which the
	* parent rest frame is C; but it is also true in the other two cases
	* where the rest frames are C1 and C2. This is because C1 and C2
	* are boosted w.r.t. C in the same direction where their components,
	* respectively (Q1,Qbar) and (Q,Q2bar) move in C1 and C2 rest frame
	* respectively.
	* Of course, although the notation used assumed that C = (Q1 Q2bar)
	* where Q1 is a quark and Q2bar an antiquark, indeed everything remain
	* unchanged also in all following cases:
	* Q1 quark, Q2bar antiquark; --> Q quark;
	* Q1 antiquark , Q2bar quark; --> Q antiquark;
	* Q1 quark, Q2bar diquark; --> Q quark
	* Q1 antiquark, Q2bar anti-diquark; --> Q antiquark
	* Q1 diquark, Q2bar quark --> Q antiquark
	* Q1 anti-diquark, Q2bar antiquark; --> Q quark
	**************************/

	// Calculate the unit three-vector, in the C frame, along which
	// all of the constituents and children clusters move.
	Lorentz5Momentum u(p0Q1);
	u.boost( -pClu.boostVector() ); // boost from LAB to C
	// the unit three-vector is then u.vect().unit()

	// Calculate the momenta of C1 and C2 in the (parent) C frame first,
	// where the direction of C1 is u.vect().unit(), and then boost back in the
	// LAB frame.

	if (pClu.m() < pClu1.mass() + pClu2.mass() ) {
	throw Exception() << "Impossible Kinematics in ClusterFissioner::calculateKinematics() (A)"
	<< Exception::eventerror;
	}
	Kinematics::twoBodyDecay(pClu, pClu1.mass(), pClu2.mass(),
	u.vect().unit(), pClu1, pClu2);

	// In the case that cluster1 does not decay immediately into a single hadron,
	// calculate the momenta of Q1 (as constituent of C1) and Qbar in the
	// (parent) C1 frame first, where the direction of Q1 is u.vect().unit(),
	// and then boost back in the LAB frame.
	if(!toHadron1) {
	if (pClu1.m() < pQ1.mass() + pQbar.mass() ) {
	throw Exception() << "Impossible Kinematics in ClusterFissioner::calculateKinematics() (B)"
	<< Exception::eventerror;
	}
	Kinematics::twoBodyDecay(pClu1, pQ1.mass(), pQbar.mass(),
	u.vect().unit(), pQ1, pQbar);
	}

	// In the case that cluster2 does not decay immediately into a single hadron,
	// Calculate the momenta of Q and Q2bar (as constituent of C2) in the
	// (parent) C2 frame first, where the direction of Q is u.vect().unit(),
	// and then boost back in the LAB frame.
	if(!toHadron2) {
	if (pClu2.m() < pQ.mass() + pQ2bar.mass() ) {
	throw Exception() << "Impossible Kinematics in ClusterFissioner::calculateKinematics() (C)"
	<< Exception::eventerror;
	}
	Kinematics::twoBodyDecay(pClu2, pQ.mass(), pQ2bar.mass(),
	u.vect().unit(), pQ, pQ2bar);
	}
	}

	void ClusterFissioner::calculatePositions(const Lorentz5Momentum & pClu,
	const LorentzPoint & positionClu,
	const Lorentz5Momentum & pClu1,
	const Lorentz5Momentum & pClu2,
	LorentzPoint & positionClu1,
	LorentzPoint & positionClu2) const {
	// Determine positions of cluster children.
	// See Marc Smith's thesis, page 127, formulas (4.122) and (4.123).
	Energy Mclu = pClu.m();
	Energy Mclu1 = pClu1.m();
	Energy Mclu2 = pClu2.m();

	// Calculate the unit three-vector, in the C frame, along which
	// children clusters move.
	Lorentz5Momentum u(pClu1);
	u.boost( -pClu.boostVector() ); // boost from LAB to C frame

	// the unit three-vector is then u.vect().unit()

	Energy pstarChild = Kinematics::pstarTwoBodyDecay(Mclu,Mclu1,Mclu2);

	// First, determine the relative positions of the children clusters
	// in the parent cluster reference frame.

	Energy2 mag2 = u.vect().mag2();
	InvEnergy fact = mag2>ZERO ? 1./sqrt(mag2) : 1./GeV;

	Length x1 = ( 0.25Mclu + 0.5( pstarChild + (sqr(Mclu2) - sqr(Mclu1))/(2.0*Mclu)))/_kappa;
	Length t1 = Mclu/_kappa - x1;
	LorentzDistance distanceClu1( x1 * fact * u.vect(), t1 );

	Length x2 = (-0.25Mclu + 0.5(-pstarChild + (sqr(Mclu2) - sqr(Mclu1))/(2.0*Mclu)))/_kappa;
	Length t2 = Mclu/_kappa + x2;
	LorentzDistance distanceClu2( x2 * fact * u.vect(), t2 );

	// Then, transform such relative positions from the parent cluster
	// reference frame to the Lab frame.
	distanceClu1.boost( pClu.boostVector() );
	distanceClu2.boost( pClu.boostVector() );

	// Finally, determine the absolute positions in the Lab frame.
	positionClu1 = positionClu + distanceClu1;
	positionClu2 = positionClu + distanceClu2;

	}

	bool ClusterFissioner::ProbabilityFunction(double scale, double threshold) {
	double cut = UseRandom::rnd(0.0,1.0);
	return 1./(1.+pow(abs((threshold-_probShift)/scale),_probPowFactor)) > cut ? true : false;
	}
	bool ClusterFissioner::ProbabilityFunctionPower(double Mass, double threshold) {
	double cut = UseRandom::rnd(0.0,1.0);
	if ((Mass-threshold)<=0)
	return false;
	return 1.0/(1.0 + _probPowFactor*pow(1.0/(Mass-threshold),_clPowLight)) > cut ? true : false;
	}


	bool ClusterFissioner::isHeavy(tcClusterPtr clu) {
	// particle data for constituents
	tcPDPtr cptr[3]={tcPDPtr(),tcPDPtr(),tcPDPtr()};
	bool hasDiquark=0;
	for(size_t ix=0;ix<min(clu->numComponents(),3);++ix) {
	cptr[ix]=clu->particle(ix)->dataPtr();
	// Assuming diquark masses are ordered with larger id corresponding to larger masses
	if (DiquarkMatcher::Check(*(cptr[ix]))) {
	hasDiquark=true;
	break;
	}
	}
	// different parameters for exotic, bottom and charm clusters
	double clpow = !spectrum()->isExotic(cptr[0],cptr[1],cptr[1]) ? _clPowLight : _clPowExotic;
	Energy clmax = !spectrum()->isExotic(cptr[0],cptr[1],cptr[1]) ? _clMaxLight : _clMaxExotic;
	// if no heavy quark is found in the cluster, but diquarks are present use
	// different ClMax and ClPow
	if ( hasDiquark) {
	clpow = _clPowDiquark;
	clmax = _clMaxDiquark;
	}

	for ( const long& id : spectrum()->heavyHadronizingQuarks() ) {
	if ( spectrum()->hasHeavy(id,cptr[0],cptr[1],cptr[1])) {
	clpow = _clPowHeavy[id];
	clmax = _clMaxHeavy[id];
	}
	}
	// required test for SUSY clusters, since aboveCutoff alone
	// cannot guarantee (Mc > m1 + m2 + 2*m) in cut()
	static const Energy minmass
	= getParticleData(ParticleID::d)->constituentMass();
	bool aboveCutoff = false, canSplitMinimally = false;
	// static kinematic threshold
	if(_kinematicThresholdChoice == 0) {
	aboveCutoff = (
	pow(clu->mass()*UnitRemoval::InvE , clpow)
	>
	pow(clmax*UnitRemoval::InvE, clpow)
	+ pow(clu->sumConstituentMasses()*UnitRemoval::InvE, clpow)
	);

	canSplitMinimally = clu->mass() > clu->sumConstituentMasses() + 2.0 * minmass;
	}
	// dynamic kinematic threshold
	else if(_kinematicThresholdChoice == 1) {
	//some smooth probablity function to create a dynamic thershold
	double scale = pow(clu->mass()/GeV , clpow);
	double threshold = pow(clmax/GeV, clpow)
	+ pow(clu->sumConstituentMasses()/GeV, clpow);
	aboveCutoff = ProbabilityFunction(scale,threshold);

	scale = clu->mass()/GeV;
	threshold = clu->sumConstituentMasses()/GeV + 2.0 * minmass/GeV;

	canSplitMinimally = ProbabilityFunction(scale,threshold);
	}
	// probablistic kinematic threshold
	else if(_kinematicThresholdChoice == 2) {
	// Consistent power law for CF probability
	double Mass = clu->mass()/GeV;
	double threshold = clu->sumConstituentMasses()/GeV + 2.0 * minmass/GeV;
	aboveCutoff = ProbabilityFunctionPower(Mass,threshold + clmax/GeV);

	canSplitMinimally = Mass - threshold>ZERO;
	}

	return aboveCutoff && canSplitMinimally;
	}
	diff --git a/Hadronization/ClusterFissioner.h b/Hadronization/ClusterFissioner.h
	--- a/Hadronization/ClusterFissioner.h
	+++ b/Hadronization/ClusterFissioner.h
	@@ -1,617 +1,617 @@
	// -- C++ --
	//
	// ClusterFissioner.h is a part of Herwig - A multi-purpose Monte Carlo event generator
	// Copyright (C) 2002-2019 The Herwig Collaboration
	//
	// Herwig is licenced under version 3 of the GPL, see COPYING for details.
	// Please respect the MCnet academic guidelines, see GUIDELINES for details.
	//
	#ifndef HERWIG_ClusterFissioner_H
	#define HERWIG_ClusterFissioner_H

	#include <ThePEG/Interface/Interfaced.h>
	#include "CluHadConfig.h"
	#include "ClusterFissioner.fh"
	#include "HadronSpectrum.h"

	namespace Herwig {
	using namespace ThePEG;

	//class Cluster; // forward declaration

	/** \ingroup Hadronization
	* \class ClusterFissioner
	* \brief This class handles clusters which are too heavy.
	* \author Philip Stephens
	* \author Alberto Ribon
	* \author Stefan Gieseke
	*
	* This class does the job of chopping up either heavy clusters or beam
	* clusters in two lighter ones. The procedure is repeated recursively until
	* all of the cluster children have masses below some threshold values.
	*
	* For the beam remnant clusters, at the moment what is done is the following.
	* In the case that the soft underlying event is switched on, the
	* beam remnant clusters are tagged as not available,
	* therefore they will not be treated at all during the hadronization.
	* In the case instead that the soft underlying event is switched off,
	* then the beam remnant clusters are treated exactly as "normal" clusters,
	* with the only exception of the mass spectrum used to generate the
	* cluster children masses. For non-beam clusters, the masses of the cluster
	* children are draw from a power-like mass distribution; for beam clusters,
	* according to the value of the flag _IOpRem, either both
	* children masses are draw from a fast-decreasing exponential mass
	* distribution (case _IOpRem == 0, or, indendently by
	* _IOpRem, in the special case that the beam cluster contains two
	* beam remnants), or one mass from the exponential distribution (corresponding
	* of the cluster child with the beam remnant) and the other with the usual
	* power-like distribution (case _IOpRem == 1, which is the
	* default one, as in Herwig 6.3).
	*
	* The reason behind the use of a fast-decreasing exponential distribution
	* is that to avoid a large transverse energy from the many sequential
	* fissions that would otherwise occur due to the typical large cluster
	* mass of beam clusters. Using instead an exponential distribution
	* the masses of the two cluster children will be very small (order of
	* GeV).
	*
	* The rationale behind the implementation of the splitting of clusters
	* has been to preserve all of the information about such splitting
	* process. More explicitly a ThePEG::Step class is passed in and the
	* new clusters are added to the step as the decay products of the
	* heavy cluster. This approach has the twofold
	* advantage to provide all of the information that could be needed
	* (expecially in future developments), without any information loss,
	* and furthermore it allows a better debugging.
	*
	* @see \ref ClusterFissionerInterfaces "The interfaces"
	* defined for ClusterFissioner.
	*/
	class ClusterFissioner: public Interfaced {

	public:

	/** @name Standard constructors and destructors. */
	//@{
	/**
	* Default constructor.
	*/
	ClusterFissioner();
	/**
	* Default destructor.
	*/
	virtual ~ClusterFissioner();

	//@}

	/** Splits the clusters which are too heavy.
	*
	* Split either heavy clusters or beam clusters recursively until all
	* children have mass below some threshold. Heavy clusters are those that
	* satisfy the condition
	* \f[ M^P > C^P + S^P \f]
	* where \f$ M \f$ is the clusters mass, \f$ P \f$ is the parameter
	* ClPow, \f$ C \f$ is the parameter ClMax and \f$ S \f$ is the
	* sum of the clusters constituent partons.
	* For beam clusters, they are split only if the soft underlying event
	* is switched off, otherwise these clusters will be tagged as unavailable
	* and they will not be treated by the hadronization altogether.
	* In the case beam clusters will be split, the procedure is exactly
	* the same as for normal non-beam clusters, with the only exception
	* of the mass spectrum from which to draw the masses of the two
	* cluster children (see method drawChildrenMasses for details).
	*/
	virtual tPVector fission(ClusterVector & clusters, bool softUEisOn);

	/**
	* Return the hadron spectrum
	*/
	virtual Ptr<HadronSpectrum>::tptr spectrum() const {
	return _hadronSpectrum;
	}

	public:

	/** @name Functions used by the persistent I/O system. */
	//@{
	/**
	* Function used to write out object persistently.
	* @param os the persistent output stream written to.
	*/
	void persistentOutput(PersistentOStream & os) const;

	/**
	* Function used to read in object persistently.
	* @param is the persistent input stream read from.
	* @param version the version number of the object when written.
	*/
	void persistentInput(PersistentIStream & is, int version);
	//@}

	/**
	* Standard Init function used to initialize the interfaces.
	*/
	static void Init();

	protected:

	/** @name Clone Methods. */
	//@{
	/**
	* Make a simple clone of this object.
	* @return a pointer to the new object.
	*/
	virtual IBPtr clone() const;

	/** Make a clone of this object, possibly modifying the cloned object
	* to make it sane.
	* @return a pointer to the new object.
	*/
	virtual IBPtr fullclone() const;
	//@}

	private:

	/**
	* Private and non-existent assignment operator.
	*/
	ClusterFissioner & operator=(const ClusterFissioner &) = delete;

	/**
	* This method directs the splitting of the heavy clusters
	*
	* This method does the splitting of the clusters and all of its cluster
	* children, if heavy. All of these new children clusters are added to the
	* collection of clusters. The method works as follows.
	* Initially the vector contains just the stack of input pointers to the
	* clusters to be split. Then it will be filled recursively by all
	* of the cluster's children that are heavy enough to require
	* to be split. In each loop, the last element of the vector is
	* considered (only once because it is then removed from the vector).
	*
	* \todo is the following still true?
	* For normal, non-beam clusters, a power-like mass distribution
	* is used, whereas for beam clusters a fast-decreasing exponential mass
	* distribution is used instead. This avoids many iterative splitting which
	* could produce an unphysical large transverse energy from a supposed
	* soft beam remnant process.
	*/
	void cut(stack<ClusterPtr> &,
	ClusterVector&, tPVector & finalhadrons, bool softUEisOn);

	public:

	/**
	* Definition for easy passing of two particles.
	*/
	typedef pair<PPtr,PPtr> PPair;

	/**
	* Definition for use in the cut function.
	*/
	typedef pair<PPair,PPair> cutType;

	/**
	* Splits the input cluster.
	*
	* Split the input cluster (which can be either an heavy non-beam
	* cluster or a beam cluster). The result is two pairs of particles. The
	* first element of each pair is new cluster/hadron, while the second
	* element of each pair is the particle drawn from the vacuum to create
	* the new cluster/hadron.
	* Notice that this method treats also beam clusters by using a different
	* mass spectrum used to generate the cluster child masses (see method
	* drawChildMass).
	*/
	//@{
	/**
	* Split two-component cluster
	*/
	virtual cutType cutTwo(ClusterPtr &, tPVector & finalhadrons, bool softUEisOn);

	/**
	* Split three-component cluster
	*/
	virtual cutType cutThree(ClusterPtr &, tPVector & finalhadrons, bool softUEisOn);
	//@}
	public:

	/**
	* Produces a hadron and returns the flavour drawn from the vacuum.
	*
	* This routine produces a new hadron. It
	* also sets the momentum and vertex to the values given.
	*/
	PPair produceHadron(tcPDPtr hadron, tPPtr newPtr, const Lorentz5Momentum &a,
	const LorentzPoint &b) const;
	protected:

	/**
	* Produces a cluster from the flavours passed in.
	*
	* This routine produces a new cluster with the flavours given by ptrQ and newPtr.
	* The new 5 momentum is a and the parent momentum are c and d. C is for the
	* ptrQ and d is for the new particle newPtr. rem specifies whether the existing
	* particle is a beam remnant or not.
	*/
	PPair produceCluster(tPPtr ptrQ, tPPtr newPtr, const Lorentz5Momentum &a,
	const LorentzPoint &b, const Lorentz5Momentum &c,
	const Lorentz5Momentum &d, const bool rem,
	tPPtr spect=tPPtr(), bool remSpect=false) const;

	/**
	* Returns the new quark-antiquark pair
	* needed for fission of a heavy cluster. Equal probabilities
	* are assumed for producing u, d, or s pairs.
	*/
	void drawNewFlavourQuarks(PPtr& newPtrPos,PPtr& newPtrNeg) const;

	/**
	* Returns the new quark-antiquark pair or diquark -
	* antidiquark pair needed for fission of a heavy cluster.
	*/
	void drawNewFlavourDiquarks(PPtr& newPtrPos,PPtr& newPtrNeg,
	const ClusterPtr & clu) const;

	/**
	* Returns the new quark-antiquark pair
	* needed for fission of a heavy cluster. Equal probabilities
	* are assumed for producing u, d, or s pairs.
	* Extra argument is used when performing strangeness enhancement
	*/
	- void drawNewFlavourEnhanced(PPtr& newPtrPos,PPtr& newPtrNeg, Energy2 mass2) const;
	+ void drawNewFlavourEnhanced(PPtr& newPtrPos,PPtr& newPtrNeg, const ClusterPtr & clu) const;


	/**
	* Produces the mass of a child cluster.
	*
	* Draw the masses \f$M'\f$ of the the cluster child produced
	* by the fission of an heavy cluster (of mass M). m1, m2 are the masses
	* of the constituents of the cluster; m is the mass of the quark extract
	* from the vacuum (together with its antiparticle). The algorithm produces
	* the mass of the cluster formed with consituent m1.
	* Two mass distributions can be used for the child cluster mass:
	* -# power-like mass distribution ("normal" mass) with power exp
	* \f[ M' = {\rm rnd}((M-m_1-m_2-m)^P, m^p)^{1/P} + m_1 \f]
	* where \f$ P \f$ is a parameter of the model and \f$ \rm{rnd} \f$ is
	* the function:
	* \f[ \rm{rnd}(a,b) = (1-r)a + r b \f]
	* and here \f$ r \f$ is a random number [0,1].
	* -# fast-decreasing exponential mass distribution ("soft" mass) with
	* rmin. rmin is given by
	* \f[ r_{\rm min} = \exp(-b (M - m_1 - m_2 - 2 m)) \f]
	* where \f$ b \f$ is a parameter of the model. The generated mass is
	* given by
	* \f[ M' = m_1 + m - \frac{\log\left(
	* {\rm rnd}(r_{\rm min}, 1-r_{\rm min})\right)}{b} \f].
	*
	* The choice of which mass distribution should be used for each of the two
	* cluster children is dictated by the parameter soft.
	*/
	Energy drawChildMass(const Energy M, const Energy m1, const Energy m2,
	const Energy m, const double exp, const bool soft) const;

	/**
	* Determine the positions of the two children clusters.
	*
	* This routine generates the momentum of the decay products. It also
	* generates the momentum in the lab frame of the partons drawn out of
	* the vacuum.
	*/
	void calculatePositions(const Lorentz5Momentum &pClu,
	const LorentzPoint & positionClu,
	const Lorentz5Momentum & pClu1,
	const Lorentz5Momentum & pClu2,
	LorentzPoint & positionClu1,
	LorentzPoint & positionClu2 ) const;

	protected:

	/**
	* Dimension used to calculate phase space weights
	*/
	double dim() const {return _dim;}

	/**
	* Access to soft-cluster parameter
	*/
	Energy btClM() const {return _btClM;}

	/**
	* Function that returns either the cluster mass or the lambda measure
	*/
	Energy2 clustermass(const ClusterPtr & cluster) const;

	/**
	* Draw a new flavour for the given cluster; currently defaults to
	* the default model
	*/
	virtual void drawNewFlavour(PPtr& newPtr1, PPtr& newPtr2, const ClusterPtr & cluster) const {
	if (_enhanceSProb == 0){
	if (_diquarkClusterFission>=0) drawNewFlavourDiquarks(newPtr1,newPtr2,cluster);
	else drawNewFlavourQuarks(newPtr1,newPtr2);
	}
	else {
	- drawNewFlavourEnhanced(newPtr1,newPtr2,clustermass(cluster));
	+ drawNewFlavourEnhanced(newPtr1,newPtr2,cluster);
	}
	}

	/**
	* Calculate the masses and possibly kinematics of the cluster
	* fission at hand; if claculateKineamtics is perfomring non-trivial
	* steps kinematics claulcated here will be overriden. Currentl;y resorts to the default
	* @return the potentially non-trivial distribution weight=f(M1,M2)
	* On Failure we return 0
	*/
	virtual double drawNewMasses(const Energy Mc, const bool soft1, const bool soft2,
	Lorentz5Momentum& pClu1, Lorentz5Momentum& pClu2,
	tcPPtr ptrQ1, const Lorentz5Momentum& pQ1,
	tcPPtr, const Lorentz5Momentum& pQone,
	tcPPtr, const Lorentz5Momentum& pQtwo,
	tcPPtr ptrQ2, const Lorentz5Momentum& pQ2) const;

	/**
	* Calculate the final kinematics of a heavy cluster decay C->C1 +
	* C2, if not already performed by drawNewMasses
	*/
	virtual void calculateKinematics(const Lorentz5Momentum & pClu,
	const Lorentz5Momentum & p0Q1,
	const bool toHadron1,
	const bool toHadron2,
	Lorentz5Momentum & pClu1,
	Lorentz5Momentum & pClu2,
	Lorentz5Momentum & pQ1,
	Lorentz5Momentum & pQbar,
	Lorentz5Momentum & pQ,
	Lorentz5Momentum & pQ2bar) const;

	protected:

	/** @name Access members for child classes. */
	//@{
	/**
	* Access to the hadron selector
	*/
	HadronSpectrumPtr hadronSpectrum() const {return _hadronSpectrum;}
	/**
	* Access for fission Pwts
	*/
	const map<long,double> fissionPwt() const { return _fissionPwt;}

	//@}

	protected:

	/** @name Standard Interfaced functions. */
	//@{
	/**
	* Initialize this object after the setup phase before saving an
	* EventGenerator to disk.
	* @throws InitException if object could not be initialized properly.
	*/
	virtual void doinit();

	/**
	* Flat PhaseSpace weight for ClusterFission
	*/
	double weightFlatPhaseSpace(const Energy Mc, const Energy Mc1, const Energy Mc2,
	const Energy m, const Energy m1, const Energy m2,
	tcPPtr pQ, tcPPtr pQ1, tcPPtr pQ2) const {
	switch (_phaseSpaceWeights)
	{
	case 1:
	return weightPhaseSpaceConstituentMasses(Mc, Mc1, Mc2, m, m1, m2, 0.0);
	case 2:
	return weightFlatPhaseSpaceHadronMasses(Mc, Mc1, Mc2, pQ, pQ1, pQ2);
	case 3:
	return weightFlatPhaseSpaceNoConstituentMasses(Mc, Mc1, Mc2);
	default:
	assert(false);
	}
	};
	/**
	* PhaseSpace weight for ClusterFission using constituent masses
	*/
	double weightPhaseSpaceConstituentMasses(const Energy Mc, const Energy Mc1, const Energy Mc2,
	const Energy m, const Energy m1, const Energy m2, const double power=0.0) const;
	/**
	* Flat PhaseSpace weight for ClusterFission using lightest hadron masses
	*/
	double weightFlatPhaseSpaceHadronMasses(const Energy Mc, const Energy Mc1, const Energy Mc2,
	tcPPtr pQ, tcPPtr pQ1, tcPPtr pQ2) const;
	double weightFlatPhaseSpaceNoConstituentMasses(const Energy Mc, const Energy Mc1, const Energy Mc2) const;


	/**
	* Calculate a veto for the phase space weight
	*/
	bool phaseSpaceVeto(const Energy Mc, const Energy Mc1, const Energy Mc2,
	const Energy m, const Energy m1, const Energy m2, tcPPtr pQ1=tcPPtr(), tcPPtr pQ2=tcPPtr(), tcPPtr pQ=tcPPtr(), const double power = 0.0) const;
	bool phaseSpaceVetoConstituentMasses(const Energy Mc, const Energy Mc1, const Energy Mc2,
	const Energy m, const Energy m1, const Energy m2, const double power = 0.0) const;
	bool phaseSpaceVetoNoConstituentMasses(const Energy Mc, const Energy Mc1, const Energy Mc2) const;

	bool phaseSpaceVetoHadronPairs(const Energy Mc, const Energy Mc1, const Energy Mc2,
	tcPPtr pQ1, tcPPtr pQ2, tcPPtr pQconst) const;


	//@}

	protected:

	/**
	* Smooth probability for dynamic threshold cuts:
	* @scale the current scale, e.g. the mass of the cluster,
	* @threshold the physical threshold,
	*/
	bool ProbabilityFunction(double scale, double threshold);
	bool ProbabilityFunctionPower(double Mass, double threshold);

	/**
	* Check if a cluster is heavy enough to split again
	*/
	bool isHeavy(tcClusterPtr );

	/**
	* Check if a cluster is heavy enough to be at least kinematically able to split
	*/
	bool canSplitMinimally(tcClusterPtr, Energy);

	/**
	* Check if can't make a hadron from the partons
	*/
	inline bool cantMakeHadron(tcPPtr p1, tcPPtr p2) {
	return ! spectrum()->canBeHadron(p1->dataPtr(), p2->dataPtr());
	}
	/**
	* A pointer to a Herwig::HadronSpectrum object for generating hadrons.
	*/
	HadronSpectrumPtr _hadronSpectrum;

	/**
	* @name The Cluster max mass,dependant on which quarks are involved, used to determine when
	* fission will occur.
	*/
	//@{
	Energy _clMaxLight;
	Energy _clMaxDiquark;
	map<long,Energy> _clMaxHeavy;
	Energy _clMaxExotic;
	//@}
	/**
	* @name The power used to determine when cluster fission will occur.
	*/
	//@{
	double _clPowLight;
	double _clPowDiquark;
	map<long,double> _clPowHeavy;
	double _clPowExotic;
	//@}
	/**
	* @name The power, dependant on whic quarks are involved, used in the cluster mass generation.
	*/
	//@{
	double _pSplitLight;
	map<long,double> _pSplitHeavy;
	double _pSplitExotic;

	/**
	* Weights for alternative cluster fission
	*/
	map<long,double> _fissionPwt;

	/**
	* Include phase space weights
	*/
	int _phaseSpaceWeights;

	/**
	* Dimensionality of phase space weight
	*/
	double _dim;

	/**
	* Flag used to determine between normal cluster fission and alternative cluster fission
	*/
	int _fissionCluster;

	/**
	* Flag to choose static or dynamic kinematic thresholds in cluster splittings
	*/
	int _kinematicThresholdChoice;

	/**
	* Pwt weight for drawing diquark
	*/
	double _pwtDIquark;

	/**
	* allow clusters to fission to 1 (or 2) diquark clusters or not
	*/
	int _diquarkClusterFission;

	//@}
	/**
	* Parameter used (2/b) for the beam cluster mass generation.
	* Currently hard coded value.
	*/
	Energy _btClM;

	/**
	* Flag used to determine what distributions to use for the cluster masses.
	*/
	int _iopRem;

	/**
	* The string constant
	*/
	Tension _kappa;

	/**
	* Flag that switches between no strangeness enhancement, scaling enhancement,
	* and exponential enhancement (in numerical order)
	*/
	int _enhanceSProb;

	/**
	* Parameter that governs the strangeness enhancement scaling
	*/
	Energy _m0Fission;

	/**
	* Flag that switches between mass measures used in strangeness enhancement:
	* cluster mass, or the lambda measure - ( m_{clu}^2 - (m_q + m_{qbar})^2 )
	*/
	int _massMeasure;

	/**
	* Constant variable which stops the scale from being to large, and not worth
	* calculating
	*/
	const double _maxScale = 20.;

	/**
	* Power factor in ClausterFissioner bell probablity function
	*/
	double _probPowFactor;

	/**
	* Shifts from the center in ClausterFissioner bell probablity function
	*/
	double _probShift;

	/**
	* Shifts from the kinetic threshold in ClausterFissioner
	*/
	Energy2 _kinThresholdShift;

	/**
	* Flag for strict diquark selection according to kinematics
	*/
	int _strictDiquarkKinematics;

	/**
	* Use Covariant boost in MatrixElementClusterFissioner
	*/
	bool _covariantBoost;

	/**
	* Power for MassPreSampler = PowerLaw
	*/
	double _powerLawPower;

	/*
	* flag for allowing strange Diquarks to be produced during
	* Cluster Fission
	* */
	unsigned int _hadronizingStrangeDiquarks;

	private:
	/*
	* DEBUG output */
	int _writeOut;
	};

	}

	#endif /* HERWIG_ClusterFissioner_H */
	diff --git a/Hadronization/HwppSelector.cc b/Hadronization/HwppSelector.cc
	--- a/Hadronization/HwppSelector.cc
	+++ b/Hadronization/HwppSelector.cc
	@@ -1,313 +1,350 @@
	// -- C++ --
	//
	// HwppSelector.cc is a part of Herwig - A multi-purpose Monte Carlo event generator
	// Copyright (C) 2002-2019 The Herwig Collaboration
	//
	// Herwig is licenced under version 3 of the GPL, see COPYING for details.
	// Please respect the MCnet academic guidelines, see GUIDELINES for details.
	//
	//
	// This is the implementation of the non-inlined, non-templated member
	// functions of the HwppSelector class.
	//

	#include "HwppSelector.h"
	#include "ThePEG/Interface/ClassDocumentation.h"
	#include "ThePEG/Interface/Switch.h"
	#include "ThePEG/Interface/Parameter.h"
	#include "ThePEG/Persistency/PersistentOStream.h"
	#include "ThePEG/Persistency/PersistentIStream.h"
	#include "Herwig/Utilities/Kinematics.h"
	#include "ThePEG/Utilities/Selector.h"
	#include "ThePEG/Repository/UseRandom.h"
	#include <cassert>
	#include <ThePEG/Utilities/DescribeClass.h>

	#include "Herwig/Utilities/AlphaS.h"
	using namespace Herwig;

	DescribeClass<HwppSelector,StandardModelHadronSpectrum>
	describeHwppSelector("Herwig::HwppSelector","Herwig.so");

	IBPtr HwppSelector::clone() const {
	return new_ptr(*this);
	}

	IBPtr HwppSelector::fullclone() const {
	return new_ptr(*this);
	}

	void HwppSelector::doinit() {
	// the default partons allowed
	// the quarks
	for ( int ix=1; ix<=5; ++ix ) {
	_partons.push_back(getParticleData(ix));
	}
	// the diquarks
	for(unsigned int ix=1;ix<=5;++ix) {
	for(unsigned int iy=1; iy<=ix;++iy) {
	if(ix==iy)
	_partons.push_back(getParticleData(makeDiquarkID(ix,iy,long(3))));
	else
	_partons.push_back(getParticleData(makeDiquarkID(ix,iy,long(1))));
	}
	}
	// weights for the different quarks etc
	for(unsigned int ix=0; ix<partons().size(); ++ix) {
	_pwt[partons()[ix]->id()]=0.;
	}
	_pwt[1] = _pwtDquark;
	_pwt[2] = _pwtUquark;
	_pwt[3] = _pwtSquark;
	_pwt[4] = _pwtCquark;
	_pwt[5] = _pwtBquark;
	_pwt[1103] = _pwtDIquark * _pwtDquark * _pwtDquark;
	_pwt[2101] = 0.5 * _pwtDIquark * _pwtUquark * _pwtDquark;
	_pwt[2203] = _pwtDIquark * _pwtUquark * _pwtUquark;
	_pwt[3101] = 0.5 * _pwtDIquark * _pwtSquark * _pwtDquark;
	_pwt[3201] = 0.5 * _pwtDIquark * _pwtSquark * _pwtUquark;
	_pwt[3303] = _pwtDIquark * _pwtSquark * _pwtSquark;
	StandardModelHadronSpectrum::doinit();
	// lightest members (baryons)
	for(const PDPtr & p1 : partons()) {
	if(DiquarkMatcher::Check(p1->id())) continue;
	for(const PDPtr & p2 : partons()) {
	if(DiquarkMatcher::Check(p2->id())) continue;
	lightestBaryons_[make_pair(p1->id(),p2->id())] = lightestBaryonPair(p1,p2);
	}
	}
	}

	void HwppSelector::persistentOutput(PersistentOStream & os) const {
	os << _pwtDIquark
	<< _mode << _enhanceSProb << ounit(_m0Decay,GeV) << _massMeasure
	<< _scHadronWtFactor << _sbHadronWtFactor << lightestBaryons_;
	}

	void HwppSelector::persistentInput(PersistentIStream & is, int) {
	is >> _pwtDIquark
	>> _mode >> _enhanceSProb >> iunit(_m0Decay,GeV) >> _massMeasure
	>> _scHadronWtFactor >> _sbHadronWtFactor >> lightestBaryons_;
	}

	void HwppSelector::Init() {

	static ClassDocumentation<HwppSelector> documentation
	("The HwppSelector class implements the Herwig algorithm for selecting"
	" the hadrons",
	"The hadronization used the selection algorithm described in \\cite{Kupco:1998fx}.",
	"%\\cite{Kupco:1998fx}\n"
	"\\bibitem{Kupco:1998fx}\n"
	" A.~Kupco,\n"
	" ``Cluster hadronization in HERWIG 5.9,''\n"
	" arXiv:hep-ph/9906412.\n"
	" %%CITATION = HEP-PH/9906412;%%\n"
	);

	static Parameter<HwppSelector,double>
	interfacePwtDIquark("PwtDIquark","Weight for choosing a DIquark",
	&HwppSelector::_pwtDIquark, 0, 1.0, 0.0, 100.0,
	false,false,false);

	static Switch<HwppSelector,unsigned int> interfaceMode
	("Mode",
	"Which algorithm to use",
	&HwppSelector::_mode, 1, false, false);

	static SwitchOption interfaceModeKupco
	(interfaceMode,
	"Kupco",
	"Use the Kupco approach",
	0);

	static SwitchOption interfaceModeHwpp
	(interfaceMode,
	"Hwpp",
	"Use the Herwig approach",
	1);

	static SwitchOption interfaceModeBaryonic
	(interfaceMode,
	"Baryonic",
	"Use alphaS^2 suppression for Baryon production.",
	2);

	static SwitchOption interfaceModeBaryonicLimit
	(interfaceMode,
	"BaryonicLimit",
	"Use alphaS^2 suppression for Baryon production.",
	3);



	static Switch<HwppSelector,int> interfaceEnhanceSProb
	("EnhanceSProb",
	"Option for enhancing strangeness",
	&HwppSelector::_enhanceSProb, 0, false, false);

	static SwitchOption interfaceEnhanceSProbNo
	(interfaceEnhanceSProb,
	"No",
	"No strangeness enhancement.",
	0);

	static SwitchOption interfaceEnhanceSProbScaled
	(interfaceEnhanceSProb,
	"Scaled",
	"Scaled strangeness enhancement",
	1);

	static SwitchOption interfaceEnhanceSProbExponential
	(interfaceEnhanceSProb,
	"Exponential",
	"Exponential strangeness enhancement",
	2);

	+ static SwitchOption interfaceEnhanceSProbNoLightStrangeness
	+ (interfaceEnhanceSProb,
	+ "NoLightStrangeness",
	+ "Forbid strangeness production for u,d cluster masses < DecayMassScale",
	+ 3);
	+
	+
	static Switch<HwppSelector,int> interfaceMassMeasure
	("MassMeasure",
	"Option to use different mass measures",
	&HwppSelector::_massMeasure,0,false,false);

	static SwitchOption interfaceMassMeasureMass
	(interfaceMassMeasure,
	"Mass",
	"Mass Measure",
	0);

	static SwitchOption interfaceMassMeasureLambda
	(interfaceMassMeasure,
	"Lambda",
	"Lambda Measure",
	1);

	static Parameter<HwppSelector,double> interfacescHadronWtFactor
	("scHadronWtFactor",
	- "Wight factor for strenge-charm heavy hadrns",
	+ "Weight factor for strange-charm heavy hadrons",
	&HwppSelector::_scHadronWtFactor, 1., 0., 10.,
	false, false, Interface::limited);

	static Parameter<HwppSelector,double> interfacesbHadronWtFactor
	("sbHadronWtFactor",
	- "Wight factor for strenge-bottom heavy hadrns",
	+ "Weight factor for strange-bottom heavy hadrons",
	&HwppSelector::_sbHadronWtFactor, 1., 0., 10.,
	false, false, Interface::limited);

	static Parameter<HwppSelector,Energy> interfaceDecayMassScale
	("DecayMassScale",
	"Cluster decay mass scale",
	- &HwppSelector::_m0Decay, GeV, 1.0GeV, 0.1GeV, 50.*GeV,
	+ &HwppSelector::_m0Decay, GeV, 1.0GeV, 0.1GeV, 500.*GeV,
	false, false, Interface::limited);

	}

	double HwppSelector::baryonWeight(long id) const {
	const int pspin = id % 10;
	if(pspin == 2) {
	// Singlet (Lambda-like) baryon
	if( (id/100)%10 < (id/10 )%10 ) return sqr(_sngWt);
	}
	// Decuplet baryon
	else if (pspin == 4) return sqr(_decWt);
	return 1.;
	}

	std::tuple<bool,bool,bool> HwppSelector::selectBaryon(const Energy cluMass, tcPDPtr par1, tcPDPtr par2) const {
	useMe();
	std::tuple<bool,bool,bool> output(true,true,true);
	switch (_mode)
	{
	case 0:
	return output;
	case 1:
	{
	if(UseRandom::rnd() > 1./(1.+_pwtDIquark) && cluMass > massLightestBaryonPair(par1,par2)) {
	std::get<0>(output) = false;
	}
	else {
	std::get<1>(output) = false;
	std::get<2>(output) = false;
	}
	break;
	}
	case 2:
	{
	double wB=_pwtDIquarksqr(Herwig::Math::alphaS(cluMass, 0.25GeV,3, 2));
	if (wB>1.0) wB=1.0;
	if(UseRandom::rnd() < wB && cluMass > massLightestBaryonPair(par1,par2)) {
	std::get<0>(output) = false;
	}
	else {
	std::get<1>(output) = false;
	std::get<2>(output) = false;
	}
	break;
	}
	case 3:
	{
	double wB=_pwtDIquarksqr(Herwig::Math::alphaS(cluMass, 0.25GeV,3, 2));
	wB = wB/(1.0+wB);
	if (wB>1.0) wB=1.0;
	if(UseRandom::rnd() < wB && cluMass > massLightestBaryonPair(par1,par2)) {
	std::get<0>(output) = false;
	}
	else {
	std::get<1>(output) = false;
	std::get<2>(output) = false;
	}
	break;
	}
	default:
	assert(false);

	}
	return output;
	}

	double HwppSelector::strangeWeight(const Energy cluMass, tcPDPtr par1, tcPDPtr par2) const {
	- // Decoupling the weight of heavy strenge hadrons
	- if(_enhanceSProb == 0 && abs(par1->id()) == 4) {
	- return pwt(3)*_scHadronWtFactor;
	- }
	- else if(_enhanceSProb == 0 && abs(par1->id()) == 5) {
	- return pwt(3)*_sbHadronWtFactor;
	- }
	- // Scaling strangeness enhancement
	- else if(_enhanceSProb == 1) {
	- double scale = double(sqr(_m0Decay/cluMass));
	- return (_maxScale < scale) ? 0. : pow(pwt(3),scale);
	- }
	- // Exponential strangeness enhancement
	- else if(_enhanceSProb == 2) {
	- Energy2 mass2;
	- Energy endpointmass = par1->mass() + par2->mass();
	- // Choose to use either the cluster mass
	- // or to use the lambda measure
	- mass2 = (_massMeasure == 0) ? sqr(cluMass) :
	- sqr(cluMass) - sqr(endpointmass);
	- double scale = double(sqr(_m0Decay)/mass2);
	- return (_maxScale < scale) ? 0. : exp(-scale);
	- }
	- return pwt(3);
	+ switch (_enhanceSProb)
	+ {
	+ case 0:
	+ {
	+ // Decoupling the weight of heavy strenge hadrons
	+ if(abs(par1->id()) == 4) {
	+ return pwt(3)*_scHadronWtFactor;
	+ }
	+ else if(abs(par1->id()) == 5) {
	+ return pwt(3)*_sbHadronWtFactor;
	+ }
	+ else {
	+ return pwt(3);
	+ }
	+ break;
	+ }
	+ case 1:
	+ {
	+ // Scaling strangeness enhancement
	+ double scale = double(sqr(_m0Decay/cluMass));
	+ return (_maxScale < scale) ? 0. : pow(pwt(3),scale);
	+ break;
	+ }
	+ case 2:
	+ {
	+ // Exponential strangeness enhancement
	+ Energy2 mass2;
	+ Energy endpointmass = par1->mass() + par2->mass();
	+ // Choose to use either the cluster mass
	+ // or to use the lambda measure
	+ mass2 = (_massMeasure == 0) ? sqr(cluMass) :
	+ sqr(cluMass) - sqr(endpointmass);
	+ double scale = double(sqr(_m0Decay)/mass2);
	+ return (_maxScale < scale) ? 0. : exp(-scale);
	+ break;
	+ }
	+ case 3:
	+ {
	+ // Strongly ordered strangeness: only if one of the constituents
	+ // are of higher mass than the strange quark allow for the strange
	+ // quark production
	+
	+ // _m0Decay is here the forbidden strangeness hard threshold
	+ if (cluMass > _m0Decay)
	+ return pwt(3);
	+ // Light && u,d clusters are forbidden from producing strangeness
	+ return (abs(par1->id())>=3 \|\| abs(par2->id())>=3) ? pwt(3):0.0;
	+ break;
	+ }
	+ default:
	+ assert(false);
	+ }
	+ assert(false);
	+ return 0;
	}

	tcPDPair HwppSelector::lightestBaryonPair(tcPDPtr ptr1, tcPDPtr ptr2) const {
	// Make sure that we don't have any diquarks as input, return arbitrarily
	// large value if we do
	Energy currentSum = Constants::MaxEnergy;
	tcPDPair output;
	for(unsigned int ix=0; ix<partons().size(); ++ix) {
	if(!DiquarkMatcher::Check(partons()[ix]->id())) continue;
	HadronTable::const_iterator
	tit1=table().find(make_pair(abs(ptr1->id()),partons()[ix]->id())),
	tit2=table().find(make_pair(partons()[ix]->id(),abs(ptr2->id())));
	if( tit1==table().end() \|\| tit2==table().end()) continue;
	if(tit1->second.empty()\|\|tit2->second.empty()) continue;
	Energy s = tit1->second.begin()->mass + tit2->second.begin()->mass;
	if(currentSum > s) {
	currentSum = s;
	output.first = tit1->second.begin()->ptrData;
	output.second = tit2->second.begin()->ptrData;
	}
	}
	return output;
	}

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