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diff --git a/Shower/ShowerHandler.cc b/Shower/ShowerHandler.cc
--- a/Shower/ShowerHandler.cc
+++ b/Shower/ShowerHandler.cc
@@ -1,724 +1,724 @@
// -*- C++ -*-
//
// ShowerHandler.cc is a part of Herwig++ - A multi-purpose Monte Carlo event generator
// Copyright (C) 2002-2011 The Herwig Collaboration
//
// Herwig++ is licenced under version 2 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 ShowerHandler class.
//
#include "ShowerHandler.h"
#include "ThePEG/Interface/ClassDocumentation.h"
#include "ThePEG/Interface/Reference.h"
#include "ThePEG/Interface/Parameter.h"
#include "ThePEG/Interface/ParVector.h"
#include "ThePEG/Interface/Switch.h"
#include "ThePEG/PDF/PartonExtractor.h"
#include "ThePEG/PDF/PartonBinInstance.h"
#include "Herwig++/PDT/StandardMatchers.h"
#include "ThePEG/Cuts/Cuts.h"
#include "ThePEG/Handlers/StandardXComb.h"
#include "ThePEG/Utilities/Throw.h"
#include "Herwig++/Shower/Base/Evolver.h"
#include "Herwig++/Shower/Base/ShowerParticle.h"
#include "ThePEG/Persistency/PersistentOStream.h"
#include "ThePEG/Persistency/PersistentIStream.h"
#include "ThePEG/Repository/EventGenerator.h"
#include "Herwig++/Utilities/EnumParticles.h"
#include "Herwig++/PDF/MPIPDF.h"
#include "Herwig++/PDF/MinBiasPDF.h"
#include "ThePEG/Handlers/EventHandler.h"
#include "Herwig++/Shower/Base/ShowerTree.h"
#include "Herwig++/Shower/Base/HardTree.h"
#include "Herwig++/Shower/Base/KinematicsReconstructor.h"
#include "Herwig++/Shower/Base/PartnerFinder.h"
#include "Herwig++/PDF/HwRemDecayer.h"
#include <cassert>
using namespace Herwig;
ShowerHandler::~ShowerHandler() {}
ShowerHandler * ShowerHandler::currentHandler_ = 0;
void ShowerHandler::doinit() {
CascadeHandler::doinit();
// copy particles to decay before showering from input vector to the
// set used in the simulation
particlesDecayInShower_.insert(inputparticlesDecayInShower_.begin(),
inputparticlesDecayInShower_.end());
ShowerTree::_decayInShower = particlesDecayInShower_;
}
IBPtr ShowerHandler::clone() const {
return new_ptr(*this);
}
IBPtr ShowerHandler::fullclone() const {
return new_ptr(*this);
}
ShowerHandler::ShowerHandler() :
pdfFreezingScale_(2.5*GeV),
maxtry_(10),maxtryMPI_(10),maxtryDP_(10), subProcess_() {
inputparticlesDecayInShower_.push_back( 6 ); // top
inputparticlesDecayInShower_.push_back( 23 ); // Z0
inputparticlesDecayInShower_.push_back( 24 ); // W+/-
inputparticlesDecayInShower_.push_back( 25 ); // h0
}
void ShowerHandler::doinitrun(){
CascadeHandler::doinitrun();
//can't use isMPIOn here, because the EventHandler is not set at that stage
if(MPIHandler_){
MPIHandler_->initialize();
if(MPIHandler_->softInt())
remDec_->initSoftInteractions(MPIHandler_->Ptmin(), MPIHandler_->beta());
}
ShowerTree::_decayInShower = particlesDecayInShower_;
}
void ShowerHandler::dofinish(){
CascadeHandler::dofinish();
if(MPIHandler_) MPIHandler_->finalize();
}
void ShowerHandler::persistentOutput(PersistentOStream & os) const {
os << evolver_ << remDec_ << ounit(pdfFreezingScale_,GeV) << maxtry_
<< maxtryMPI_ << maxtryDP_ << inputparticlesDecayInShower_
- << particlesDecayInShower_ << MPIHandler_;
+ << particlesDecayInShower_ << MPIHandler_ << PDFA_ << PDFB_;
}
void ShowerHandler::persistentInput(PersistentIStream & is, int) {
is >> evolver_ >> remDec_ >> iunit(pdfFreezingScale_,GeV) >> maxtry_
>> maxtryMPI_ >> maxtryDP_ >> inputparticlesDecayInShower_
- >> particlesDecayInShower_ >> MPIHandler_;
+ >> particlesDecayInShower_ >> MPIHandler_ >> PDFA_ >> PDFB_;
}
ClassDescription<ShowerHandler> ShowerHandler::initShowerHandler;
// Definition of the static class description member.
void ShowerHandler::Init() {
static ClassDocumentation<ShowerHandler> documentation
("Main driver class for the showering.",
"The Shower evolution was performed using an algorithm described in "
"\\cite{Marchesini:1983bm,Marchesini:1987cf,Gieseke:2003rz,Bahr:2008pv}.",
"%\\cite{Marchesini:1983bm}\n"
"\\bibitem{Marchesini:1983bm}\n"
" G.~Marchesini and B.~R.~Webber,\n"
" ``Simulation Of QCD Jets Including Soft Gluon Interference,''\n"
" Nucl.\\ Phys.\\ B {\\bf 238}, 1 (1984).\n"
" %%CITATION = NUPHA,B238,1;%%\n"
"%\\cite{Marchesini:1987cf}\n"
"\\bibitem{Marchesini:1987cf}\n"
" G.~Marchesini and B.~R.~Webber,\n"
" ``Monte Carlo Simulation of General Hard Processes with Coherent QCD\n"
" Radiation,''\n"
" Nucl.\\ Phys.\\ B {\\bf 310}, 461 (1988).\n"
" %%CITATION = NUPHA,B310,461;%%\n"
"%\\cite{Gieseke:2003rz}\n"
"\\bibitem{Gieseke:2003rz}\n"
" S.~Gieseke, P.~Stephens and B.~Webber,\n"
" ``New formalism for QCD parton showers,''\n"
" JHEP {\\bf 0312}, 045 (2003)\n"
" [arXiv:hep-ph/0310083].\n"
" %%CITATION = JHEPA,0312,045;%%\n"
);
static Reference<ShowerHandler,Evolver>
interfaceEvolver("Evolver",
"A reference to the Evolver object",
&Herwig::ShowerHandler::evolver_,
false, false, true, false);
static Reference<ShowerHandler,HwRemDecayer>
interfaceRemDecayer("RemDecayer",
"A reference to the Remnant Decayer object",
&Herwig::ShowerHandler::remDec_,
false, false, true, false);
static Parameter<ShowerHandler,Energy> interfacePDFFreezingScale
("PDFFreezingScale",
"The PDF freezing scale",
&ShowerHandler::pdfFreezingScale_, GeV, 2.5*GeV, 2.0*GeV, 10.0*GeV,
false, false, Interface::limited);
static Parameter<ShowerHandler,unsigned int> interfaceMaxTry
("MaxTry",
"The maximum number of attempts for the main showering loop",
&ShowerHandler::maxtry_, 10, 1, 100,
false, false, Interface::limited);
static Parameter<ShowerHandler,unsigned int> interfaceMaxTryMPI
("MaxTryMPI",
"The maximum number of regeneration attempts for an additional scattering",
&ShowerHandler::maxtryMPI_, 10, 0, 100,
false, false, Interface::limited);
static Parameter<ShowerHandler,unsigned int> interfaceMaxTryDP
("MaxTryDP",
"The maximum number of regeneration attempts for an additional hard scattering",
&ShowerHandler::maxtryDP_, 10, 0, 100,
false, false, Interface::limited);
static ParVector<ShowerHandler,long> interfaceDecayInShower
("DecayInShower",
"PDG codes of the particles to be decayed in the shower",
&ShowerHandler::inputparticlesDecayInShower_, -1, 0l, -10000000l, 10000000l,
false, false, Interface::limited);
static Reference<ShowerHandler,UEBase> interfaceMPIHandler
("MPIHandler",
"The object that administers all additional scatterings.",
&ShowerHandler::MPIHandler_, false, false, true, true);
static Reference<ShowerHandler,PDFBase> interfacePDFA
("PDFA",
"The PDF for beam particle A. Overrides the particle's own PDF setting.",
&ShowerHandler::PDFA_, false, false, true, true, false);
static Reference<ShowerHandler,PDFBase> interfacePDFB
("PDFB",
"The PDF for beam particle B. Overrides the particle's own PDF setting.",
&ShowerHandler::PDFB_, false, false, true, true, false);
}
void ShowerHandler::cascade() {
tcPDFPtr first = firstPDF().pdf();
tcPDFPtr second = secondPDF().pdf();
if ( PDFA_ ) first = PDFA_;
if ( PDFB_ ) second = PDFB_;
resetPDFs(make_pair(first,second));
// get the incoming partons
tPPair incomingPartons =
eventHandler()->currentCollision()->primarySubProcess()->incoming();
// and the parton bins
PBIPair incomingBins =
make_pair(lastExtractor()->partonBinInstance(incomingPartons.first),
lastExtractor()->partonBinInstance(incomingPartons.second));
// and the incoming hadrons
tPPair incomingHadrons =
eventHandler()->currentCollision()->incoming();
// check if incoming hadron == incoming parton
// and get the incoming hadron if exists or parton otherwise
incoming_ = make_pair(incomingBins.first ?
incomingBins.first ->particle() : incomingPartons.first,
incomingBins.second ?
incomingBins.second->particle() : incomingPartons.second);
// check the collision is of the beam particles
// and if not boost collision to the right frame
// i.e. the hadron-hadron CMF of the collision
bool btotal(false);
LorentzRotation rtotal;
if(incoming_.first != incomingHadrons.first ||
incoming_.second != incomingHadrons.second ) {
btotal = true;
boostCollision(false);
}
// set the current ShowerHandler
currentHandler_ = this;
// first shower the hard process
useMe();
try {
SubProPtr sub = eventHandler()->currentCollision()->primarySubProcess();
incomingPartons = cascade(sub,lastXCombPtr());
}
catch(ShowerTriesVeto &veto){
throw Exception() << "Failed to generate the shower after "
<< veto.tries
<< " attempts in Evolver::showerHardProcess()"
<< Exception::eventerror;
}
// if a non-hadron collision return (both incoming non-hadronic)
if( ( !incomingBins.first||
!isResolvedHadron(incomingBins.first ->particle()))&&
( !incomingBins.second||
!isResolvedHadron(incomingBins.second->particle()))) {
// boost back to lab if needed
if(btotal) boostCollision(true);
// unset the current ShowerHandler
currentHandler_ = 0;
return;
}
// get the remnants for hadronic collision
pair<tRemPPtr,tRemPPtr> remnants(getRemnants(incomingBins));
// set the starting scale of the forced splitting to the PDF freezing scale
remDec_->initialize(remnants, incoming_, *currentStep(), pdfFreezingScale());
// do the first forcedSplitting
try {
remDec_->doSplit(incomingPartons, make_pair(firstPDF() .pdf(),
secondPDF().pdf()), true);
}
catch (ExtraScatterVeto) {
throw Exception() << "Remnant extraction failed in "
<< "ShowerHandler::cascade() from primary interaction"
<< Exception::eventerror;
}
// if no MPI return
if( !isMPIOn() ) {
remDec_->finalize();
// boost back to lab if needed
if(btotal) boostCollision(true);
// unset the current ShowerHandler
currentHandler_ = 0;
return;
}
// generate the multiple scatters use modified pdf's now:
setMPIPDFs();
// additional "hard" processes
unsigned int tries(0);
// This is the loop over additional hard scatters (most of the time
// only one, but who knows...)
for(unsigned int i=1; i <= getMPIHandler()->additionalHardProcs(); i++){
//counter for regeneration
unsigned int multSecond = 0;
// generate the additional scatters
while( multSecond < getMPIHandler()->multiplicity(i) ) {
// generate the hard scatter
tStdXCombPtr lastXC = getMPIHandler()->generate(i);
SubProPtr sub = lastXC->construct();
// add to the Step
newStep()->addSubProcess(sub);
// increment the counters
tries++;
multSecond++;
if(tries == maxtryDP_)
throw Exception() << "Failed to establish the requested number "
<< "of additional hard processes. If this error "
<< "occurs often, your selection of additional "
<< "scatter is probably unphysical"
<< Exception::eventerror;
// Generate the shower. If not possible veto the event
try {
incomingPartons = cascade(sub,lastXC);
}
catch(ShowerTriesVeto &veto){
throw Exception() << "Failed to generate the shower of "
<< "a secondary hard process after "
<< veto.tries
<< " attempts in Evolver::showerHardProcess()"
<< Exception::eventerror;
}
try {
// do the forcedSplitting
remDec_->doSplit(incomingPartons, make_pair(firstPDF().pdf(),
secondPDF().pdf()), false);
}
catch(ExtraScatterVeto){
//remove all particles associated with the subprocess
newStep()->removeParticle(incomingPartons.first);
newStep()->removeParticle(incomingPartons.second);
//remove the subprocess from the list
newStep()->removeSubProcess(sub);
//regenerate the scattering
multSecond--;
continue;
}
// connect with the remnants but don't set Remnant colour,
// because that causes problems due to the multiple colour lines.
if ( !remnants.first ->extract(incomingPartons.first , false) ||
!remnants.second->extract(incomingPartons.second, false) )
throw Exception() << "Remnant extraction failed in "
<< "ShowerHandler::cascade() for additional scatter"
<< Exception::runerror;
}
}
// the underlying event processes
unsigned int ptveto(1), veto(0);
unsigned int max(getMPIHandler()->multiplicity());
for(unsigned int i=0; i<max; i++) {
// check how often this scattering has been regenerated
if(veto > maxtryMPI_) break;
//generate PSpoint
tStdXCombPtr lastXC = getMPIHandler()->generate();
SubProPtr sub = lastXC->construct();
//If Algorithm=1 additional scatters of the signal type
// with pt > ptmin have to be vetoed
//with probability 1/(m+1), where m is the number of occurances in this event
if( getMPIHandler()->Algorithm() == 1 ){
//get the pT
Energy pt = sub->outgoing().front()->momentum().perp();
if(pt > getMPIHandler()->PtForVeto() && UseRandom::rnd() < 1./(ptveto+1) ){
ptveto++;
i--;
continue;
}
}
// add to the SubProcess to the step
newStep()->addSubProcess(sub);
// Run the Shower. If not possible veto the scattering
try {
incomingPartons = cascade(sub,lastXC);
}
// discard this extra scattering, but try the next one
catch(ShowerTriesVeto) {
newStep()->removeSubProcess(sub);
//regenerate the scattering
veto++;
i--;
continue;
}
try{
//do the forcedSplitting
remDec_->doSplit(incomingPartons, make_pair(firstPDF().pdf(),
secondPDF().pdf()), false);
}
catch (ExtraScatterVeto) {
//remove all particles associated with the subprocess
newStep()->removeParticle(incomingPartons.first);
newStep()->removeParticle(incomingPartons.second);
//remove the subprocess from the list
newStep()->removeSubProcess(sub);
//regenerate the scattering
veto++;
i--;
continue;
}
//connect with the remnants but don't set Remnant colour,
//because that causes problems due to the multiple colour lines.
if ( !remnants.first ->extract(incomingPartons.first , false) ||
!remnants.second->extract(incomingPartons.second, false) )
throw Exception() << "Remnant extraction failed in "
<< "ShowerHandler::cascade() for MPI hard scattering"
<< Exception::runerror;
//reset veto counter
veto = 0;
}
// finalize the remnants
remDec_->finalize(getMPIHandler()->colourDisrupt(),
getMPIHandler()->softMultiplicity());
// boost back to lab if needed
if(btotal) boostCollision(true);
// unset the current ShowerHandler
currentHandler_ = 0;
}
void ShowerHandler::fillEventRecord() {
// create a new step
StepPtr pstep = newStep();
assert(!done_.empty());
assert(done_[0]->isHard());
// insert the steps
for(unsigned int ix=0;ix<done_.size();++ix) {
done_[ix]->fillEventRecord(pstep,
evolver_->isISRadiationON(),
evolver_->isFSRadiationON());
}
}
void ShowerHandler::findShoweringParticles() {
// clear the storage
hard_=ShowerTreePtr();
decay_.clear();
done_.clear();
// temporary storage of the particles
set<PPtr> hardParticles;
// outgoing particles from the hard process
PVector outgoing = currentSubProcess()->outgoing();
set<PPtr> outgoingset(outgoing.begin(),outgoing.end());
// loop over the tagged particles
tPVector thetagged;
if( firstInteraction() ){
thetagged = tagged();
}
else{
thetagged.insert(thetagged.end(),
outgoing.begin(),outgoing.end());
}
bool isHard=false;
for (tParticleVector::const_iterator
taggedP = thetagged.begin();
taggedP != thetagged.end(); ++taggedP) {
// if a remnant don't consider
if(eventHandler()->currentCollision()->isRemnant(*taggedP))
continue;
// find the parent and whether its a colourless s-channel resonance
bool isDecayProd=false;
tPPtr parent;
if(!(*taggedP)->parents().empty()) {
parent = (*taggedP)->parents()[0];
// check if from s channel decaying colourless particle
isDecayProd = decayProduct(parent);
}
// add to list of outgoing hard particles if needed
isHard |=(outgoingset.find(*taggedP) != outgoingset.end());
if(isDecayProd) hardParticles.insert(findParent(parent,isHard,outgoingset));
else hardParticles.insert(*taggedP);
}
// there must be something to shower
if(hardParticles.empty())
throw Exception() << "No particles to shower in "
<< "ShowerHandler::fillShoweringParticles"
<< Exception::eventerror;
if(!isHard)
throw Exception() << "Starting on decay not yet implemented in "
<< "ShowerHandler::findShoweringParticles()"
<< Exception::runerror;
// create the hard process ShowerTree
ParticleVector out(hardParticles.begin(),hardParticles.end());
hard_=new_ptr(ShowerTree(currentSubProcess()->incoming(),out, decay_));
hard_->setParents();
}
tPPair ShowerHandler::cascade(tSubProPtr sub,
XCPtr xcomb) {
// get the current step
current_ = currentStep();
// get the current subprocess
subProcess_ = sub;
// start of the try block for the whole showering process
unsigned int countFailures=0;
while (countFailures<maxtry_) {
try {
// find the particles in the hard process and the decayed particles to shower
findShoweringParticles();
// if no hard process
if(!hard_) throw Exception() << "Shower starting with a decay"
<< "is not implemented"
<< Exception::runerror;
// perform the shower for the hard process
evolver_->showerHardProcess(hard_,xcomb);
done_.push_back(hard_);
hard_->updateAfterShower(decay_);
// if no decaying particles to shower break out of the loop
if(decay_.empty()) break;
// shower the decay products
while(!decay_.empty()) {
// find particle whose production process has been showered
ShowerDecayMap::iterator dit = decay_.begin();
while(!dit->second->parent()->hasShowered() && dit!=decay_.end()) ++dit;
assert(dit!=decay_.end());
// get the particle
ShowerTreePtr decayingTree = dit->second;
// remove it from the multimap
decay_.erase(dit);
// make sure the particle has been decayed
decayingTree->decay(decay_);
// now shower the decay
evolver_->showerDecay(decayingTree);
done_.push_back(decayingTree);
decayingTree->updateAfterShower(decay_);
}
// suceeded break out of the loop
break;
}
catch (KinematicsReconstructionVeto) {
++countFailures;
}
}
// if loop exited because of too many tries, throw event away
if (countFailures >= maxtry_) {
hard_=ShowerTreePtr();
decay_.clear();
done_.clear();
throw Exception() << "Too many tries for main while loop "
<< "in ShowerHandler::cascade()."
<< Exception::eventerror;
}
//enter the particles in the event record
fillEventRecord();
// clear storage
hard_=ShowerTreePtr();
decay_.clear();
done_.clear();
// non hadronic case return
if (!isResolvedHadron(incoming_.first ) &&
!isResolvedHadron(incoming_.second) )
return incoming_;
// remake the remnants (needs to be after the colours are sorted
// out in the insertion into the event record)
if ( firstInteraction() ) return remakeRemnant(sub->incoming());
//Return the new pair of incoming partons. remakeRemnant is not
//necessary here, because the secondary interactions are not yet
//connected to the remnants.
return make_pair(findFirstParton(sub->incoming().first ),
findFirstParton(sub->incoming().second));
}
PPtr ShowerHandler::findParent(PPtr original, bool & isHard,
set<PPtr> outgoingset) const {
PPtr parent=original;
isHard |=(outgoingset.find(original) != outgoingset.end());
if(!original->parents().empty()) {
PPtr orig=original->parents()[0];
if(current_->find(orig)&&decayProduct(orig)) {
parent=findParent(orig,isHard,outgoingset);
}
}
return parent;
}
ShowerHandler::RemPair
ShowerHandler::getRemnants(PBIPair incomingBins) {
RemPair remnants;
// first beam particle
if(incomingBins.first&&!incomingBins.first->remnants().empty()) {
remnants.first =
dynamic_ptr_cast<tRemPPtr>(incomingBins.first->remnants()[0] );
if(remnants.first) {
ParticleVector children=remnants.first->children();
for(unsigned int ix=0;ix<children.size();++ix) {
if(children[ix]->dataPtr()==remnants.first->dataPtr())
remnants.first = dynamic_ptr_cast<RemPPtr>(children[ix]);
}
//remove existing colour lines from the remnants
if(remnants.first->colourLine())
remnants.first->colourLine()->removeColoured(remnants.first);
if(remnants.first->antiColourLine())
remnants.first->antiColourLine()->removeAntiColoured(remnants.first);
}
}
// seconnd beam particle
if(incomingBins.second&&!incomingBins. second->remnants().empty()) {
remnants.second =
dynamic_ptr_cast<tRemPPtr>(incomingBins.second->remnants()[0] );
if(remnants.second) {
ParticleVector children=remnants.second->children();
for(unsigned int ix=0;ix<children.size();++ix) {
if(children[ix]->dataPtr()==remnants.second->dataPtr())
remnants.second = dynamic_ptr_cast<RemPPtr>(children[ix]);
}
//remove existing colour lines from the remnants
if(remnants.second->colourLine())
remnants.second->colourLine()->removeColoured(remnants.second);
if(remnants.second->antiColourLine())
remnants.second->antiColourLine()->removeAntiColoured(remnants.second);
}
}
assert(remnants.first || remnants.second);
return remnants;
}
tPPair ShowerHandler::remakeRemnant(tPPair oldp){
// get the parton extractor
PartonExtractor & pex = *lastExtractor();
// get the new partons
tPPair newp = make_pair(findFirstParton(oldp.first ),
findFirstParton(oldp.second));
// if the same do nothing
if(newp == oldp) return oldp;
// Creates the new remnants and returns the new PartonBinInstances
PBIPair newbins = pex.newRemnants(oldp, newp, newStep());
newStep()->addIntermediate(newp.first);
newStep()->addIntermediate(newp.second);
// return the new partons
return newp;
}
PPtr ShowerHandler::findFirstParton(tPPtr seed) const{
if(seed->parents().empty()) return seed;
tPPtr parent = seed->parents()[0];
//if no parent there this is a loose end which will
//be connected to the remnant soon.
if(!parent || parent == incoming_.first ||
parent == incoming_.second ) return seed;
else return findFirstParton(parent);
}
bool ShowerHandler::decayProduct(tPPtr particle) const {
// must be time-like and not incoming
if(particle->momentum().m2()<=ZERO||
particle == currentSubProcess()->incoming().first||
particle == currentSubProcess()->incoming().second) return false;
// if only 1 outgoing and this is it
if(currentSubProcess()->outgoing().size()==1 &&
currentSubProcess()->outgoing()[0]==particle) return true;
// must not be the s-channel intermediate otherwise
if(find(currentSubProcess()->incoming().first->children().begin(),
currentSubProcess()->incoming().first->children().end(),particle)!=
currentSubProcess()->incoming().first->children().end()&&
find(currentSubProcess()->incoming().second->children().begin(),
currentSubProcess()->incoming().second->children().end(),particle)!=
currentSubProcess()->incoming().second->children().end()&&
currentSubProcess()->incoming().first ->children().size()==1&&
currentSubProcess()->incoming().second->children().size()==1)
return false;
// if non-coloured this is enough
if(!particle->dataPtr()->coloured()) return true;
// if coloured must be unstable
if(particle->dataPtr()->stable()) return false;
// must not have same particle type as a child
int id = particle->id();
for(unsigned int ix=0;ix<particle->children().size();++ix)
if(particle->children()[ix]->id()==id) return false;
// otherwise its a decaying particle
return true;
}
namespace {
void addChildren(tPPtr in,set<tPPtr> & particles) {
particles.insert(in);
for(unsigned int ix=0;ix<in->children().size();++ix)
addChildren(in->children()[ix],particles);
}
}
void ShowerHandler::boostCollision(bool boost) {
// calculate boost from lab to rest
if(!boost) {
Lorentz5Momentum ptotal=incoming_.first ->momentum()+incoming_.second->momentum();
boost_ = LorentzRotation(-ptotal.boostVector());
Axis axis((boost_*incoming_.first ->momentum()).vect().unit());
if(axis.perp2()>0.) {
double sinth(sqrt(sqr(axis.x())+sqr(axis.y())));
boost_.rotate(acos(-axis.z()),Axis(-axis.y()/sinth,axis.x()/sinth,0.));
}
}
// first call performs the boost and second inverse
// get the particles to be boosted
set<tPPtr> particles;
addChildren(incoming_.first,particles);
addChildren(incoming_.second,particles);
// apply the boost
for(set<tPPtr>::const_iterator cit=particles.begin();
cit!=particles.end();++cit) {
(*cit)->transform(boost_);
}
if(!boost) boost_.invert();
}
void ShowerHandler::setMPIPDFs() {
if ( !mpipdfs_.first ) {
// first have to check for MinBiasPDF
tcMinBiasPDFPtr first = dynamic_ptr_cast<tcMinBiasPDFPtr>(firstPDF().pdf());
if(first)
mpipdfs_.first = new_ptr(MPIPDF(first->originalPDF()));
else
mpipdfs_.first = new_ptr(MPIPDF(firstPDF().pdf()));
}
if ( !mpipdfs_.second ) {
tcMinBiasPDFPtr second = dynamic_ptr_cast<tcMinBiasPDFPtr>(secondPDF().pdf());
if(second)
mpipdfs_.second = new_ptr(MPIPDF(second->originalPDF()));
else
mpipdfs_.second = new_ptr(MPIPDF(secondPDF().pdf()));
}
// reset the PDFs stored in the base class
resetPDFs(mpipdfs_);
}
bool ShowerHandler::isResolvedHadron(tPPtr particle) {
if(!HadronMatcher::Check(particle->data())) return false;
for(unsigned int ix=0;ix<particle->children().size();++ix) {
if(particle->children()[ix]->id()==ExtraParticleID::Remnant) return true;
}
return false;
}
HardTreePtr ShowerHandler::generateCKKW(ShowerTreePtr ) const {
return HardTreePtr();
}

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