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diff --git a/MatrixElement/General/MEvv2vv.cc b/MatrixElement/General/MEvv2vv.cc
--- a/MatrixElement/General/MEvv2vv.cc
+++ b/MatrixElement/General/MEvv2vv.cc
@@ -1,338 +1,341 @@
// -*- C++ -*-
//
// MEvv2vv.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 MEvv2vv class.
//
#include "MEvv2vv.h"
#include "ThePEG/Interface/ClassDocumentation.h"
#include "ThePEG/Persistency/PersistentOStream.h"
#include "ThePEG/Persistency/PersistentIStream.h"
using namespace Herwig;
using ThePEG::Helicity::ScalarWaveFunction;
using ThePEG::Helicity::TensorWaveFunction;
using ThePEG::Helicity::incoming;
using ThePEG::Helicity::outgoing;
void MEvv2vv::doinit() {
GeneralHardME::doinit();
scalar_.resize(numberOfDiags());
vector_.resize(numberOfDiags());
tensor_.resize(numberOfDiags());
initializeMatrixElements(PDT::Spin1, PDT::Spin1,
PDT::Spin1, PDT::Spin1);
for(size_t i = 0; i < numberOfDiags(); ++i) {
HPDiagram diag = getProcessInfo()[i];
tcPDPtr offshell = diag.intermediate;
if(!offshell)
fourPointVertex_ = dynamic_ptr_cast<AbstractVVVVVertexPtr>
(diag.vertices.first);
else if(offshell->iSpin() == PDT::Spin0) {
AbstractVVSVertexPtr vert1 = dynamic_ptr_cast<AbstractVVSVertexPtr>
(diag.vertices.first);
AbstractVVSVertexPtr vert2 = dynamic_ptr_cast<AbstractVVSVertexPtr>
(diag.vertices.second);
scalar_[i] = make_pair(vert1, vert2);
}
else if(offshell->iSpin() == PDT::Spin1) {
AbstractVVVVertexPtr vert1 = dynamic_ptr_cast<AbstractVVVVertexPtr>
(diag.vertices.first);
AbstractVVVVertexPtr vert2 = dynamic_ptr_cast<AbstractVVVVertexPtr>
(diag.vertices.second);
vector_[i] = make_pair(vert1, vert2);
}
else if(offshell->iSpin() == PDT::Spin2) {
AbstractVVTVertexPtr vert1 = dynamic_ptr_cast<AbstractVVTVertexPtr>
(diag.vertices.first);
AbstractVVTVertexPtr vert2 = dynamic_ptr_cast<AbstractVVTVertexPtr>
(diag.vertices.second);
tensor_[i] = make_pair(vert1, vert2);
}
}
}
double MEvv2vv::me2() const {
VBVector va(2), vb(2), vc(3), vd(3);
for(unsigned int i = 0; i < 2; ++i) {
va[i] = VectorWaveFunction(rescaledMomenta()[0], mePartonData()[0], 2*i,
incoming);
vb[i] = VectorWaveFunction(rescaledMomenta()[1], mePartonData()[1], 2*i,
incoming);
}
//always 0 and 2 polarisations
for(unsigned int i = 0; i < 2; ++i) {
vc[2*i] = VectorWaveFunction(rescaledMomenta()[2], mePartonData()[2], 2*i,
outgoing);
vd[2*i] = VectorWaveFunction(rescaledMomenta()[3], mePartonData()[3], 2*i,
outgoing);
}
bool mc = !(mePartonData()[2]->mass() > ZERO);
//massive vector, also 1
if( !mc )
vc[1] = VectorWaveFunction(rescaledMomenta()[2], mePartonData()[2], 1,
outgoing);
bool md = !(mePartonData()[3]->mass() > ZERO);
if( !md )
vd[1] = VectorWaveFunction(rescaledMomenta()[3], mePartonData()[3], 1,
outgoing);
double full_me(0.);
vv2vvHeME(va, vb, vc, mc, vd, md, full_me,true);
#ifndef NDEBUG
if( debugME() ) debug(full_me);
#endif
return full_me;
}
ProductionMatrixElement
MEvv2vv::vv2vvHeME(VBVector & vin1, VBVector & vin2,
VBVector & vout1, bool mc, VBVector & vout2, bool md,
double & me2, bool first) const {
const Energy2 q2(scale());
const Energy mass = vout1[0].mass();
// weights for the selection of the diagram
vector<double> me(numberOfDiags(), 0.);
// weights for the selection of the colour flow
vector<double> flow(numberOfFlows(),0.);
// flow over the helicities and diagrams
for(unsigned int ihel1 = 0; ihel1 < 2; ++ihel1) {
for(unsigned int ihel2 = 0; ihel2 < 2; ++ihel2) {
for(unsigned int ohel1 = 0; ohel1 < 3; ++ohel1) {
if(mc && ohel1 == 1) ++ohel1;
for(unsigned int ohel2 = 0; ohel2 < 3; ++ohel2) {
if(md && ohel2 == 1) ++ohel2;
vector<Complex> flows(numberOfFlows(),0.);
for(HPCount ix = 0; ix < numberOfDiags(); ++ix) {
Complex diag(0.);
const HPDiagram & current = getProcessInfo()[ix];
tcPDPtr offshell = current.intermediate;
if(current.channelType == HPDiagram::sChannel) {
if(offshell->iSpin() == PDT::Spin0) {
ScalarWaveFunction interS =
scalar_[ix].first->evaluate(q2, 1, offshell,
vin1[ihel1], vin2[ihel2]);
diag = scalar_[ix].second->
evaluate(q2, vout1[ohel1], vout2[ohel2], interS);
}
else if(offshell->iSpin() == PDT::Spin1) {
VectorWaveFunction interV = vector_[ix].first->
evaluate(q2, 1, offshell, vin1[ihel1], vin2[ihel2]);
diag = vector_[ix].second->
evaluate(q2, vout1[ohel1], vout2[ohel2], interV);
- if(colour()==Colour88to88 || colour()==Colour88to66bar)
+ if(colour()==Colour88to88)
diag += fourPointVertex_->evaluate(q2, 0, vout1[ohel1], vin2[ihel2],
vout2[ohel2], vin1[ihel1]);
+ else if(colour()==Colour88to66bar)
+ diag -= fourPointVertex_->evaluate(q2, 0, vout1[ohel1], vin2[ihel2],
+ vout2[ohel2], vin1[ihel1]);
}
else if(offshell->iSpin() == PDT::Spin2) {
TensorWaveFunction interT = tensor_[ix].first->
evaluate(q2, 1, offshell, vin1[ihel1], vin2[ihel2]);
diag = tensor_[ix].second->
evaluate(q2, vout1[ohel1], vout2[ohel2],interT);
}
else
assert(false);
}
else if(current.channelType == HPDiagram::tChannel) {
if(offshell->iSpin() == PDT::Spin0) {
if(current.ordered.second) {
ScalarWaveFunction interS = scalar_[ix].
first->evaluate(q2, 3, offshell, vin1[ihel1],vout1[ohel1], mass);
diag = scalar_[ix].second->
evaluate(q2, vin2[ihel2], vout2[ohel2], interS);
}
else {
ScalarWaveFunction interS = scalar_[ix].first->
evaluate(q2, 3, offshell, vin2[ihel2],vout1[ohel1], mass);
diag = scalar_[ix].second->
evaluate(q2, vin1[ihel1], vout2[ohel2], interS);
}
}
else if(offshell->iSpin() == PDT::Spin1) {
if(current.ordered.second) {
VectorWaveFunction interV = vector_[ix].
first->evaluate(q2, 3, offshell, vin1[ihel1],vout1[ohel1], mass);
diag = vector_[ix].second->
evaluate(q2, vin2[ihel2], interV, vout2[ohel2]);
if(colour()==Colour88to88 || colour()==Colour88to66bar)
diag += fourPointVertex_->evaluate(q2, 0, vin1[ihel1], vin2[ihel2],
vout1[ohel1], vout2[ohel2]);
}
else {
if(offshell->CC()) offshell = offshell->CC();
VectorWaveFunction interV = vector_[ix].first->
evaluate(q2, 3, offshell, vin2[ihel2],vout1[ohel1], mass);
diag = vector_[ix].second->
evaluate(q2, vin1[ihel1], interV, vout2[ohel2]);
if(colour()==Colour88to88 || colour()==Colour88to66bar)
diag += fourPointVertex_->
evaluate(q2, 0, vin2[ihel2], vin1[ihel1],
vout1[ohel1], vout2[ohel2]);
}
}
else if(offshell->iSpin() == PDT::Spin2) {
if(current.ordered.second) {
TensorWaveFunction interT = tensor_[ix].first->
evaluate(q2, 3, offshell, vin1[ihel1],vout1[ohel1], mass);
diag = tensor_[ix].second->
evaluate(q2, vin2[ihel2], vout2[ohel2], interT);
}
else {
TensorWaveFunction interT = tensor_[ix].first->
evaluate(q2, 3, offshell, vin2[ihel2],vout1[ohel1], mass);
diag = tensor_[ix].second->
evaluate(q2, vin1[ihel1], vout2[ohel2], interT);
}
}
else
assert(false);
}
else if(current.channelType == HPDiagram::fourPoint) {
if(colour()==Colour88to88||colour()==Colour88to66bar)
diag = 0.;
else
diag = fourPointVertex_->evaluate(q2, 0, vin1[ihel1], vin2[ihel2],
vout1[ohel1], vout2[ohel2]);
}
else
assert(false);
me[ix] += norm(diag);
diagramME()[ix](2*ihel1, 2*ihel2, ohel1, ohel2) = diag;
//Compute flows
for(size_t iy = 0; iy < current.colourFlow.size(); ++iy) {
assert(current.colourFlow[iy].first<flows.size());
flows[current.colourFlow[iy].first] +=
current.colourFlow[iy].second * diag;
}
}
// MEs for the different colour flows
for(unsigned int iy = 0; iy < numberOfFlows(); ++iy)
flowME()[iy](2*ihel1, 2*ihel2, ohel1, ohel2) = flows[iy];
//Now add flows to me2 with appropriate colour factors
for(size_t ii = 0; ii < numberOfFlows(); ++ii)
for(size_t ij = 0; ij < numberOfFlows(); ++ij)
me2 += getColourFactors()[ii][ij]*(flows[ii]*conj(flows[ij])).real();
// contribution to the colour flow
for(unsigned int ii = 0; ii < numberOfFlows(); ++ii) {
flow[ii] += getColourFactors()[ii][ii]*norm(flows[ii]);
}
}
}
}
}
// if not computing the cross section return the selected colour flow
if(!first) return flowME()[colourFlow()];
me2 = selectColourFlow(flow,me,me2);
return flowME()[colourFlow()];
}
void MEvv2vv::persistentOutput(PersistentOStream & os) const {
os << scalar_ << vector_ << tensor_ << fourPointVertex_;
}
void MEvv2vv::persistentInput(PersistentIStream & is, int) {
is >> scalar_ >> vector_ >> tensor_ >> fourPointVertex_;
initializeMatrixElements(PDT::Spin1, PDT::Spin1,
PDT::Spin1, PDT::Spin1);
}
ClassDescription<MEvv2vv> MEvv2vv::initMEvv2vv;
// Definition of the static class description member.
void MEvv2vv::Init() {
static ClassDocumentation<MEvv2vv> documentation
("This is the implementation of the 2 to 2 ME for a pair"
"of massless vector-bosons to a pair of vector bosons");
}
void MEvv2vv::constructVertex(tSubProPtr sub) {
ParticleVector ext = hardParticles(sub);
// set wave functions with real momenta
VBVector v1, v2, v3, v4;
VectorWaveFunction(v1, ext[0], incoming, false, true);
VectorWaveFunction(v2, ext[1], incoming, false, true);
//function to calculate me2 expects massless incoming vectors
// and this constructor sets the '1' polarisation at element [2]
//in the vector
bool mc = !(ext[2]->data().mass() > ZERO);
bool md = !(ext[3]->data().mass() > ZERO);
VectorWaveFunction(v3, ext[2], outgoing, true, mc);
VectorWaveFunction(v4, ext[3], outgoing, true, md);
// Need to use rescale momenta to calculate matrix element
setRescaledMomenta(ext);
// wave functions with rescaled momenta
VectorWaveFunction vr1(rescaledMomenta()[0],
ext[0]->dataPtr(), incoming);
VectorWaveFunction vr2(rescaledMomenta()[1],
ext[1]->dataPtr(), incoming);
VectorWaveFunction vr3(rescaledMomenta()[2],
ext[2]->dataPtr(), outgoing);
VectorWaveFunction vr4(rescaledMomenta()[3],
ext[3]->dataPtr(), outgoing);
for( unsigned int ihel = 0; ihel < 2; ++ihel ) {
vr1.reset(2*ihel);
v1[ihel] = vr1;
vr2.reset(2*ihel);
v2[ihel] = vr2;
vr3.reset(2*ihel);
v3[2*ihel] = vr3;
vr4.reset(2*ihel);
v4[2*ihel] = vr4;
}
if( !mc ) {
vr3.reset(1);
v3[1] = vr3;
}
if( !md ) {
vr4.reset(1);
v4[1] = vr4;
}
double dummy(0.);
ProductionMatrixElement pme = vv2vvHeME(v1, v2, v3, mc, v4, md, dummy,false);
#ifndef NDEBUG
if( debugME() ) debug(dummy);
#endif
createVertex(pme,ext);
}
void MEvv2vv::debug(double me2) const {
if( !generator()->logfile().is_open() ) return;
if( mePartonData()[0]->id() != 21 || mePartonData()[1]->id() != 21 ||
mePartonData()[2]->id() != 5100021 ||
mePartonData()[3]->id() != 5100021 ) return;
tcSMPtr sm = generator()->standardModel();
double gs4 = sqr( 4.*Constants::pi*sm->alphaS(scale()) );
Energy2 s(sHat());
Energy2 mf2 = meMomenta()[2].m2();
Energy2 t3(tHat() - mf2), u4(uHat() - mf2);
Energy4 s2(sqr(s)), t3s(sqr(t3)), u4s(sqr(u4));
Energy4 num = s2 + t3s + u4s;
double analytic = 3.*mf2*( mf2*num/t3s/u4s - num/s/t3/u4 ) + 1.
+ sqr(num)*num/4./s2/t3s/u4s - t3*u4/s2;
analytic *= 9.*gs4/8.;
double diff = abs( analytic - me2 );
if( diff > 1e-4 ) {
generator()->log()
<< mePartonData()[0]->PDGName() << ","
<< mePartonData()[1]->PDGName() << "->"
<< mePartonData()[2]->PDGName() << ","
<< mePartonData()[3]->PDGName() << " difference: "
<< setprecision(10) << diff << " ratio: " << analytic/me2 << '\n';
}
}
diff --git a/Models/Sextet/SextetGVVVertex.cc b/Models/Sextet/SextetGVVVertex.cc
--- a/Models/Sextet/SextetGVVVertex.cc
+++ b/Models/Sextet/SextetGVVVertex.cc
@@ -1,78 +1,75 @@
// -*- C++ -*-
//
// This is the implementation of the non-inlined, non-templated member
// functions of the SextetGVVVertex class.
//
#include "SextetModel.h"
#include "SextetGVVVertex.h"
#include "SextetParticles.h"
#include "ThePEG/Interface/ClassDocumentation.h"
#include "ThePEG/EventRecord/Particle.h"
#include "ThePEG/Repository/UseRandom.h"
#include "ThePEG/Repository/EventGenerator.h"
#include "ThePEG/Utilities/DescribeClass.h"
using namespace Herwig;
IBPtr SextetGVVVertex::clone() const {
return new_ptr(*this);
}
IBPtr SextetGVVVertex::fullclone() const {
return new_ptr(*this);
}
-// *** Attention *** The following static variable is needed for the type
-// description system in ThePEG. Please check that the template arguments
-// are correct (the class and its base class), and that the constructor
-// arguments are correct (the class name and the name of the dynamically
-// loadable library where the class implementation can be found).
+// The following static variable is needed for the type
+// description system in ThePEG.
DescribeNoPIOClass<SextetGVVVertex,Helicity::VVVVertex>
describeSextetGVVVertex("Herwig::SextetGVVVertex", "HwSextetModel.so");
void SextetGVVVertex::Init() {
static ClassDocumentation<SextetGVVVertex> documentation
("The SextetGVVVertex class implements the coupling of the gluon to two"
" vector sextet particles");
}
void SextetGVVVertex::doinit() {
orderInGs(1);
orderInGem(0);
SextetModelPtr model =
dynamic_ptr_cast<SextetModelPtr>(generator()->standardModel());
if(!model) throw Exception() << "Must be using the SextetModel"
<< " in SextetGVVVertex::doinit()"
<< Exception::runerror;
if(model->VectorDoubletY16Enabled()) {
addToList(21,ParticleID::VectorDQY16P,
ParticleID::VectorDQY16Pbar);
addToList(21,ParticleID::VectorDQY16M,
ParticleID::VectorDQY16Mbar);
}
if(model->VectorDoubletY56Enabled()) {
addToList(21,ParticleID::VectorDQY56P,
ParticleID::VectorDQY56Pbar);
addToList(21,ParticleID::VectorDQY56M,
ParticleID::VectorDQY56Mbar);
}
VVVVertex::doinit();
}
void SextetGVVVertex::setCoupling(Energy2 q2, tcPDPtr p1, tcPDPtr p2,
tcPDPtr p3) {
if(q2 != q2Last_ || coupLast_ == 0.) {
q2Last_ = q2;
coupLast_ = strongCoupling(q2);
}
if((p1->id()==ParticleID::g&&p2->id()>0&&p3->id()<0)||
(p2->id()==ParticleID::g&&p3->id()>0&&p1->id()<0)||
(p3->id()==ParticleID::g&&p1->id()>0&&p2->id()<0))
norm(-coupLast_);
else
norm( coupLast_);
}
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