/* This file is part of MAUS: http://micewww.pp.rl.ac.uk/projects/maus
*
* MAUS is free software: you can redistribute it and/or modify
* it under the terms of the GNU General Public License as published by
* the Free Software Foundation, either version 3 of the License, or
* (at your option) any later version.
*
* MAUS is distributed in the hope that it will be useful,
* but WITHOUT ANY WARRANTY; without even the implied warranty of
* MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
* GNU General Public License for more details.
*
* You should have received a copy of the GNU General Public License
* along with MAUS. If not, see .
*
*/
#include
#include
#include
#include
#include
#include "json/json.h"
#include "Geant4/G4ProcessManager.hh"
#include "Geant4/G4ProcessTable.hh"
#include "Geant4/G4ProcessVector.hh"
#include "Geant4/G4ParticleTypes.hh"
#include "Geant4/G4ParticleTable.hh"
#include "Geant4/G4PionDecayMakeSpin.hh"
#include "Geant4/G4MuonDecayChannelWithSpin.hh"
#include "Geant4/G4MuonRadiativeDecayChannelWithSpin.hh"
#include "Geant4/G4DecayWithSpin.hh"
#include "Geant4/G4DecayPhysics.hh"
#include "Geant4/G4DecayTable.hh"
#include "Geant4/globals.hh"
#include "Geant4/G4StepLimiter.hh"
#include "Geant4/G4UserSpecialCuts.hh"
#include "Geant4/G4UImanager.hh"
#include "Geant4/G4PhysListFactory.hh"
#include "Interface/Squeak.hh"
#include "src/common_cpp/Utils/Globals.hh"
#include "src/common_cpp/Utils/JsonWrapper.hh"
#include "src/common_cpp/Simulation/MAUSPhysicsList.hh"
namespace MAUS {
// Note muMsc and CoulombScat make an error message from G4.9.2 - but are needed
// for G4.9.5 so we leave them in... I could do some logic checking for G4
// version if it is a problem (Rogers)
const std::string MAUSPhysicsList::_scatNames[] = {"muBrems", "hBrems",
"eBrem", "muPairProd", "hPairProd",
"ElectroNuclear", "msc", "muMsc", "CoulombScat"};
const std::string MAUSPhysicsList::_eLossNames[] = {"muBrems", "hBrems",
"eBrem", "muPairProd", "hPairProd",
"muIoni", "hIoni", "eIoni"};
const int MAUSPhysicsList::_nScatNames = 9;
const int MAUSPhysicsList::_nELossNames = 8;
double MAUSPhysicsList::_defaultChargedPiHalfLife = -1;
double MAUSPhysicsList::_defaultChargedMuHalfLife = -1;
MAUSPhysicsList::MAUSPhysicsList(G4VModularPhysicsList* physList)
: G4VUserPhysicsList(), _polDecay(false) {
_list = physList;
_list->RegisterPhysics(new G4DecayPhysics());
}
MAUSPhysicsList::~MAUSPhysicsList() {
for (size_t i = 0; i < _limits.size(); ++i) {
delete _limits[i];
}
for (size_t i = 0; i < _specialCuts.size(); ++i) {
delete _specialCuts[i];
}
delete _list;
}
MAUSPhysicsList* MAUSPhysicsList::GetMAUSPhysicsList() {
Json::Value& dc = *Globals::GetInstance()->GetConfigurationCards();
std::string physModel = JsonWrapper::GetProperty
(dc, "physics_model", JsonWrapper::stringValue).asString();
G4PhysListFactory fact;
if (fact.IsReferencePhysList(physModel)) {
MAUSPhysicsList* mpl =
new MAUSPhysicsList(fact.GetReferencePhysList(physModel));
try {
mpl->Setup();
return mpl;
}
catch (Exception exc) {
delete mpl;
throw exc;
}
} else {
throw(Exception(Exception::recoverable,
"Failed to recognise physics list model "+physModel,
"MAUSPhysicsList::GetMAUSPhysicsList()")
);
}
}
void MAUSPhysicsList::BeginOfReferenceParticleAction() {
Squeak::mout(Squeak::debug)
<< "MAUSPhysicsList::BeginOfReferenceParticleAction() with de model "
<< _refDEModel << std::endl;
SetStochastics(no_scat, _refDEModel, no_hadronic, false);
}
void MAUSPhysicsList:: BeginOfRunAction() {
Squeak::mout(Squeak::debug) << "MAUSPhysicsList::BeginOfRunAction() with"
<< "\n de model " << _dEModel
<< "\n msc model " << _msModel
<< "\n hadronic model " << _hadronicModel
<< "\n particle decay " << _partDecay
<< "\n pi 1/2 life " << _piHalfLife
<< "\n mu 1/2 life " << _muHalfLife
<< "\n polarised muons " << _polDecay
<< std::endl;
SetStochastics(_msModel, _dEModel, _hadronicModel, _partDecay);
}
void MAUSPhysicsList::SetStochastics(scat scatteringModel,
eloss energyLossModel, hadronic hadronicModel,
bool decayModel) {
SetEnergyLoss(energyLossModel);
SetScattering(scatteringModel);
SetHadronic(hadronicModel);
SetDecay(decayModel);
}
void MAUSPhysicsList::SetDecay(bool decay) {
if (decay) {
SetHalfLife(_piHalfLife, _muHalfLife);
} else {
// note that disabling decays makes a G4Exception, as per #1404
// This is a G4 bug.
//
// Here we just set the lifetime to be very long (this could cause a
// problem if user sets simulation time to be even longer, default
// max time is 1e9 nanoseconds
double life = std::numeric_limits::max()/10.;
SetHalfLife(life, life);
}
}
void MAUSPhysicsList::SetEnergyLoss(eloss eLossModel) {
double cutDouble = _productionThreshold;
std::stringstream cutStream;
std::string elossActive = "activate";
std::string flucActive = "true";
switch (eLossModel) {
case energyStraggling:
elossActive = "activate";
flucActive = "true";
cutDouble = _productionThreshold;
break;
case dedx:
elossActive = "activate";
flucActive = "false";
cutDouble = 1e12*mm;
break;
case no_eloss:
elossActive = "inactivate";
flucActive = "false";
cutDouble = 1e12*mm;
break;
}
cutStream << cutDouble;
std::vector uiCommand;
uiCommand.push_back("/run/setCut "+cutStream.str());
uiCommand.push_back("/process/eLoss/fluct "+flucActive);
for (int i = 0; i < _nELossNames; i++)
uiCommand.push_back("/process/"+elossActive+" "+_eLossNames[i]);
for (size_t i = 0; i < uiCommand.size(); i++) {
UIApplyCommand(uiCommand[i]);
}
}
void MAUSPhysicsList::SetScattering(scat scatteringModel) {
std::string activation;
switch (scatteringModel) {
case mcs:
activation = "/process/activate ";
break;
case no_scat:
activation = "/process/inactivate ";
break;
}
for (int i = 0; i < _nScatNames; i++) {
UIApplyCommand(activation+_scatNames[i]);
}
}
void MAUSPhysicsList::SetHadronic(hadronic hadronicModel) {
std::string activation;
switch (hadronicModel) {
case all_hadronic:
activation = "/process/activate ";
break;
case no_hadronic:
activation = "/process/inactivate ";
break;
}
G4ProcessVector* pvec = G4ProcessTable::GetProcessTable()->
FindProcesses(fHadronic);
for (int i = 0; i < pvec->size(); i++) {
std::string pname = (*pvec)[i]->GetProcessName();
UIApplyCommand(activation+pname);
}
delete pvec;
}
void MAUSPhysicsList::ConstructParticle() {
_list->ConstructParticle();
if (_polDecay == true) {
G4DecayTable* MuonPlusDecayTable = new G4DecayTable();
MuonPlusDecayTable -> Insert(new G4MuonDecayChannelWithSpin
("mu+", 0.986));
MuonPlusDecayTable -> Insert(new G4MuonRadiativeDecayChannelWithSpin
("mu+", 0.014));
G4MuonPlus::MuonPlusDefinition()->SetDecayTable(MuonPlusDecayTable);
G4DecayTable* MuonMinusDecayTable = new G4DecayTable();
MuonMinusDecayTable -> Insert(new
G4MuonDecayChannelWithSpin("mu-", 0.986));
MuonMinusDecayTable -> Insert(new G4MuonRadiativeDecayChannelWithSpin
("mu-", 0.014));
G4MuonMinus::MuonMinusDefinition()->SetDecayTable(MuonMinusDecayTable);
}
}
void MAUSPhysicsList::ConstructProcess() {
_list->ConstructProcess(); // BUG: Memory leak on G4 side
SetSpecialProcesses();
}
void MAUSPhysicsList::SetSpecialProcesses() {
theParticleIterator->reset(); // from G4VUserPhysicsList
while ( (*theParticleIterator)() ) {
G4ProcessManager* fmanager = theParticleIterator->value()->
GetProcessManager();
// step limiter for G4StepMax parameter; _limits exists for memory cleanup
_limits.push_back(new G4StepLimiter);
fmanager->AddProcess(_limits.back(), -1, -1, 2);
// track limiter for G4KinMax, etc
_specialCuts.push_back(new G4UserSpecialCuts());
fmanager->AddProcess(_specialCuts.back(), -1, -1, 3);
}
if (_polDecay == true) {
G4ProcessManager* pmanager = NULL;
G4ProcessTable* processTable = G4ProcessTable::GetProcessTable();
G4VProcess* decay = NULL;
////////// MUON PLUS ///////////
pmanager = G4MuonPlus::MuonPlus()->GetProcessManager();
G4DecayWithSpin* decayWithSpinPlus = new G4DecayWithSpin();
decay = processTable->FindProcess("Decay", G4MuonPlus::MuonPlus());
if (pmanager) {
if (decay)
pmanager->RemoveProcess(decay);
pmanager->AddProcess(decayWithSpinPlus);
processTable->Insert(decayWithSpinPlus,
G4MuonPlus::MuonPlus()->GetProcessManager());
// set ordering for PostStepDoIt and AtRestDoIt
pmanager ->SetProcessOrdering(decayWithSpinPlus, idxPostStep);
pmanager ->SetProcessOrdering(decayWithSpinPlus, idxAtRest);
}
////////// MUON MINUS ///////////
pmanager = G4MuonMinus::MuonMinus()->GetProcessManager();
G4DecayWithSpin* decayWithSpinMinus = new G4DecayWithSpin();
decay = processTable->FindProcess("Decay", G4MuonMinus::MuonMinus());
if (pmanager) {
if (decay)
pmanager->RemoveProcess(decay);
pmanager->AddProcess(decayWithSpinMinus);
processTable->Insert(decayWithSpinMinus,
G4MuonMinus::MuonMinus()->GetProcessManager());
// set ordering for PostStepDoIt and AtRestDoIt
pmanager->SetProcessOrdering(decayWithSpinMinus, idxPostStep);
pmanager->SetProcessOrdering(decayWithSpinMinus, idxAtRest);
}
}
}
void MAUSPhysicsList::SetHalfLife(double pionHalfLife, double muonHalfLife) {
if (_defaultChargedPiHalfLife < 0 || _defaultChargedMuHalfLife < 0) {
G4ParticleTable* p_table = G4ParticleTable::GetParticleTable();
_defaultChargedPiHalfLife = p_table->FindParticle(211)->GetPDGLifeTime();
_defaultChargedMuHalfLife = p_table->FindParticle(13)->GetPDGLifeTime();
}
if (pionHalfLife <= 0.)
pionHalfLife = _defaultChargedPiHalfLife;
if (muonHalfLife <= 0.)
muonHalfLife = _defaultChargedMuHalfLife;
SetParticleHalfLife("pi+", pionHalfLife);
SetParticleHalfLife("pi-", pionHalfLife);
SetParticleHalfLife("mu+", muonHalfLife);
SetParticleHalfLife("mu-", muonHalfLife);
}
void MAUSPhysicsList::SetParticleHalfLife(std::string particleName,
double halfLife) {
if (halfLife <= 0.)
throw Exception(Exception::recoverable,
"Negative half life",
"MAUSPhysicsList::SetParticleHalfLife");
std::stringstream ss_in;
ss_in << halfLife;
UIApplyCommand("/particle/select "+particleName);
UIApplyCommand("/particle/property/lifetime "+ss_in.str()+" ns");
UIApplyCommand("/particle/property/dump");
}
void MAUSPhysicsList::Setup() {
Json::Value& dc = *Globals::GetInstance()->GetConfigurationCards();
std::string refPhysicsModel = JsonWrapper::GetProperty(dc,
"reference_physics_processes", JsonWrapper::stringValue).asString();
std::string physicsModel = JsonWrapper::GetProperty(dc, "physics_processes",
JsonWrapper::stringValue).asString();
if (refPhysicsModel == "none")
_refDEModel = no_eloss;
if (refPhysicsModel == "mean_energy_loss")
_refDEModel = dedx;
if (physicsModel == "none") {
_msModel = no_scat;
_dEModel = no_eloss;
_hadronicModel = no_hadronic;
}
if (physicsModel == "mean_energy_loss") {
_msModel = no_scat;
_dEModel = dedx;
_hadronicModel = no_hadronic;
}
if (physicsModel == "standard") {
_msModel = mcs;
_dEModel = energyStraggling;
_hadronicModel = all_hadronic;
}
_partDecay = JsonWrapper::GetProperty(dc, "particle_decay",
JsonWrapper::booleanValue).asBool();
_polDecay = JsonWrapper::GetProperty(dc, "polarised_decay",
JsonWrapper::booleanValue).asBool();
_piHalfLife = JsonWrapper::GetProperty(dc, "charged_pion_half_life",
JsonWrapper::realValue).asDouble();
_muHalfLife = JsonWrapper::GetProperty(dc, "muon_half_life",
JsonWrapper::realValue).asDouble();
_productionThreshold = JsonWrapper::GetProperty(dc, "production_threshold",
JsonWrapper::realValue).asDouble();
}
void MAUSPhysicsList::UIApplyCommand(std::string command) {
Squeak::mout(Squeak::debug)
<< "Apply G4UI command: " << command << std::endl;
G4UImanager::GetUIpointer()->ApplyCommand(command);
}
}