KVNumberList KVAvailableRunsFile::GetRunList(const KVDBSystem * sys)
{
//Returns list of available run numbers for this data type.
//If 'sys' gives the address of a valid database reaction system, only runs
//corresponding to the system will be included.
KVNumberList runs;
//does runlist exist ?
if (!OpenAvailableRunsFile()) {
Error("GetRunList", "Cannot open available runs file");
return runs;
}
TString fLine;
fLine.ReadLine(fRunlist);
Int_t fRunNumber;
KVDBTable *runs_table = 0;
KVDataBase* db = fDataSet->GetDataBase();
if (!db){
db = new KVDataBase();
db->AddTable("Runs","List of Runs");
}
runs_table = db->GetTable("Runs");
//KVDBTable *runs_table = fDataSet->GetDataBase()->GetTable("Runs");
while (fRunlist.good()) {
TObjArray *toks = fLine.Tokenize('|'); // split into fields
KVString kvs(((TObjString *) toks->At(0))->GetString());
fRunNumber = kvs.Atoi();
delete toks;
if (sys) {
// check run is from right system
KVDBRun *a_run = (KVDBRun *) runs_table->GetRecord(fRunNumber);
if (a_run) {
if (a_run->GetSystem() == sys)
runs.Add(fRunNumber);
}
} else {
// add all runs to list
runs.Add(fRunNumber);
}
fLine.ReadLine(fRunlist);
}
CloseAvailableRunsFile();
return runs;
}
KVNumberList KVAvailableRunsFile::CheckMultiRunfiles()
{
//Returns a list with all runs which occur more than once in the available runs file.
// //does runlist exist ?
// if (!OpenAvailableRunsFile()) {
// Error("CheckMultiRunfiles", "Cannot open available runs file");
// return 0;
// }
//
// TString fLine;
// TList *run_list = new TList;
// fLine.ReadLine(fRunlist);
//
// KVNumberList multiruns;
//
// Int_t fRunNumber;
// KVDBTable *runs_table = fDataSet->GetDataBase()->GetTable("Runs");
//
// while (fRunlist.good()) {
//
// TObjArray *toks = fLine.Tokenize('|'); // split into fields
// KVString kvs(((TObjString *) toks->At(0))->GetString());
// fRunNumber = kvs.Atoi();
// delete toks;
//
// KVDBRun *a_run = (KVDBRun *) runs_table->GetRecord(fRunNumber);
//
// if (!run_list->Contains(a_run)) {
// //first time that run appears
// run_list->Add(a_run);
// } else {
// //run appears >1 times
// multiruns.Add(fRunNumber);
// }
//
// fLine.ReadLine(fRunlist);
// }
// delete run_list;
// CloseAvailableRunsFile();
//
// return multiruns;
ReadFile();
KVNumberList multiruns;
TIter next(fAvailableRuns);
KVNameValueList* run;
while( (run = (KVNameValueList*)next()) ){
if(run->GetIntValue("Occurs")>1) multiruns.Add(run->GetName());
}
return multiruns;
}
//_____________________________________________________________________________________________________//
KVIDGrid* KVIDTelescope::CalculateDeltaE_EGrid(TH2* haa_zz, Bool_t Zonly, Int_t npoints)
{
//Genere une grille dE-E (perte d'energie - energie residuelle)
//Le calcul est fait pour chaque couple comptant de charge (Z) et masse (A)
//au moins un coup dans l'histogramme haa_zz definit :
// Axe X -> Z
// Axe Y -> A
//
//- Si Zonly=kTRUE (kFALSE par defaut), pour un Z donne, le A choisi est la valeur entiere la
//plus proche de la valeur moyenne <A>
//- Si Zonly=kFALSE et que pour un Z donne il n'y a qu'un seul A associe, les lignes correspondants
//a A-1 et A+1 sont ajoutes
//- Si a un Z donne, il n'y a aucun A, pas de ligne tracee
//un noyau de A et Z donne n'est considere que s'il retourne KVNucleus::IsKnown() = kTRUE
//
// Warning : the grid is not added to the list of the telescope and MUST BE DELETED by the user !
if (GetSize() <= 1) return 0;
TClass* cl = new TClass(GetDefaultIDGridClass());
KVIDGrid* idgrid = (KVIDGrid*)cl->New();
delete cl;
idgrid->AddIDTelescope(this);
idgrid->SetOnlyZId(Zonly);
KVDetector* det_de = GetDetector(1);
if (!det_de) return 0;
KVDetector* det_eres = GetDetector(2);
if (!det_eres) return 0;
KVNucleus part;
Info("CalculateDeltaE_EGrid",
"Calculating dE-E grid: dE detector = %s, E detector = %s",
det_de->GetName(), det_eres->GetName());
KVIDCutLine* B_line = (KVIDCutLine*)idgrid->Add("OK", "KVIDCutLine");
Int_t npoi_bragg = 0;
B_line->SetName("Bragg_line");
B_line->SetAcceptedDirection("right");
Double_t SeuilE = 0.1;
for (Int_t nx = 1; nx <= haa_zz->GetNbinsX(); nx += 1) {
Int_t zz = TMath::Nint(haa_zz->GetXaxis()->GetBinCenter(nx));
KVNumberList nlA;
Double_t sumA = 0, sum = 0;
for (Int_t ny = 1; ny <= haa_zz->GetNbinsY(); ny += 1) {
Double_t stat = haa_zz->GetBinContent(nx, ny);
if (stat > 0) {
Double_t val = haa_zz->GetYaxis()->GetBinCenter(ny);
nlA.Add(TMath::Nint(val));
sumA += val * stat;
sum += stat;
}
}
sumA /= sum;
Int_t nA = nlA.GetNValues();
if (nA == 0) {
Warning("CalculateDeltaE_EGrid", "no count for Z=%d", zz);
} else {
if (Zonly) {
nlA.Clear();
nlA.Add(TMath::Nint(sumA));
} else {
if (nA == 1) {
Int_t aref = nlA.Last();
nlA.Add(aref - 1);
nlA.Add(aref + 1);
}
}
part.SetZ(zz);
// printf("zz=%d\n",zz);
nlA.Begin();
while (!nlA.End()) {
Int_t aa = nlA.Next();
part.SetA(aa);
// printf("+ aa=%d known=%d\n",aa,part.IsKnown());
if (part.IsKnown()) {
//loop over energy
//first find :
// ****E1 = energy at which particle passes 1st detector and starts to enter in the 2nd one****
// E2 = energy at which particle passes the 2nd detector
//then perform npoints calculations between these two energies and use these
//to construct a KVIDZALine
Double_t E1, E2;
//find E1
//go from SeuilE MeV to det_de->GetEIncOfMaxDeltaE(part.GetZ(),part.GetA()))
Double_t E1min = SeuilE, E1max = det_de->GetEIncOfMaxDeltaE(zz, aa);
E1 = (E1min + E1max) / 2.;
while ((E1max - E1min) > SeuilE) {
part.SetEnergy(E1);
det_de->Clear();
det_eres->Clear();
det_de->DetectParticle(&part);
det_eres->DetectParticle(&part);
if (det_eres->GetEnergy() > SeuilE) {
//particle got through - decrease energy
E1max = E1;
E1 = (E1max + E1min) / 2.;
} else {
//particle stopped - increase energy
E1min = E1;
E1 = (E1max + E1min) / 2.;
}
}
//add point to Bragg line
Double_t dE_B = det_de->GetMaxDeltaE(zz, aa);
Double_t E_B = det_de->GetEIncOfMaxDeltaE(zz, aa);
Double_t Eres_B = det_de->GetERes(zz, aa, E_B);
B_line->SetPoint(npoi_bragg++, Eres_B, dE_B);
//find E2
//go from E1 MeV to maximum value where the energy loss formula is valid
Double_t E2min = E1, E2max = det_eres->GetEmaxValid(part.GetZ(), part.GetA());
E2 = (E2min + E2max) / 2.;
while ((E2max - E2min > SeuilE)) {
part.SetEnergy(E2);
det_de->Clear();
det_eres->Clear();
det_de->DetectParticle(&part);
det_eres->DetectParticle(&part);
if (part.GetEnergy() > SeuilE) {
//particle got through - decrease energy
E2max = E2;
E2 = (E2max + E2min) / 2.;
} else {
//particle stopped - increase energy
E2min = E2;
E2 = (E2max + E2min) / 2.;
}
}
// printf("z=%d a=%d E1=%lf E2=%lf\n",zz,aa,E1,E2);
KVIDZALine* line = (KVIDZALine*)idgrid->Add("ID", "KVIDZALine");
if (TMath::Even(zz)) line->SetLineColor(4);
line->SetAandZ(aa, zz);
Double_t logE1 = TMath::Log(E1);
Double_t logE2 = TMath::Log(E2);
Double_t dLog = (logE2 - logE1) / (npoints - 1.);
for (Int_t i = 0; i < npoints; i++) {
Double_t E = TMath::Exp(logE1 + i * dLog);
Double_t Eres = 0.;
Int_t niter = 0;
while (Eres < SeuilE && niter <= 20) {
det_de->Clear();
det_eres->Clear();
part.SetEnergy(E);
det_de->DetectParticle(&part);
det_eres->DetectParticle(&part);
Eres = det_eres->GetEnergy();
E += SeuilE;
niter += 1;
}
if (!(niter > 20)) {
Double_t dE = det_de->GetEnergy();
Double_t gEres, gdE;
line->GetPoint(i - 1, gEres, gdE);
line->SetPoint(i, Eres, dE);
}
}
}
}
}
}
return idgrid;
}
//___________________________________________________________________________________________
KVNumberList* KVValues::TransformExpression(KVString& expr)
{
KVNumberList* nl = new KVNumberList();
const char* O = "[";
const char* F = "]";
KVString clone;
clone.Form("%s", expr.Data());
const char* expression = clone.Data();
Int_t nouvert = 0, nferme = 0;
Int_t posouvert = 0, posferme = 0;
Int_t nvar = 0;
Int_t nsize = clone.Length();
for (Int_t ii = 0; ii <= nsize; ii += 1) {
if (expression[ii] == O[0]) {
nouvert += 1;
posouvert = ii;
}
else if (expression[ii] == F[0]) {
nferme += 1;
posferme = ii;
KVString st(clone(posouvert + 1, posferme - posouvert - 1));
if (st.IsDigit()) {
Int_t idx = st.Atoi();
if (0 <= idx && idx < kval_tot) {
nl->Add(idx);
nvar += 1;
}
else {
delete nl;
return 0;
}
}
else {
Int_t idx = GetValuePosition(st.Data());
if (idx == -1) {
delete nl;
return 0;
}
nl->Add(idx);
nvar += 1;
KVString s1;
s1.Form("[%s]", st.Data());
KVString s2;
s2.Form("[%d]", idx);
expr.ReplaceAll(s1, s2);
}
}
else {}
}
if (nouvert != nferme || nvar != nouvert) {
Error("TransformExpr", "nombre [ : %d - nombre de ] : %d - nombre de variables %d", nouvert, nferme, nvar);
}
return nl;
}
