Revision ecc5b95a2ba5b8b8fdbe35ad4ef97535fd22927a authored by will-cern on 15 June 2024, 06:52:10 UTC, committed by Danilo Piparo on 15 June 2024, 10:20:08 UTC
ParamHistFunc currently does not adhere to the convention that if it is independent of the variable passed to binBoundaries method that it should return `nullptr`. This is fixed, along with more correct obtaining of the bin boundaries, from the RooDataHist itself.
1 parent c632980
ProofEventProc.C
/// \file
/// \ingroup tutorial_ProofEventProc
///
/// Selector to process trees containing Event structures
///
/// \macro_code
///
/// \author Gerardo Ganis (gerardo.ganis@cern.ch)
#define ProofEventProc_cxx
#include "ProofEventProc.h"
#include <TStyle.h>
#include "TCanvas.h"
#include "TPad.h"
#include "TH1F.h"
#include "TH2F.h"
#include "TParameter.h"
#include "TRandom.h"
#include "TNamed.h"
#include "TROOT.h"
#include "EmptyInclude.h"
//_____________________________________________________________________________
void ProofEventProc::Begin(TTree *)
{
// The Begin() function is called at the start of the query.
// When running with PROOF Begin() is only called on the client.
// The tree argument is deprecated (on PROOF 0 is passed).
TString option = GetOption();
Info("Begin", "starting a simple exercise with process option: %s", option.Data());
}
//_____________________________________________________________________________
void ProofEventProc::SlaveBegin(TTree * /*tree*/)
{
// The SlaveBegin() function is called after the Begin() function.
// When running with PROOF SlaveBegin() is called on each slave server.
// The tree argument is deprecated (on PROOF 0 is passed).
TString option = GetOption();
// How much to read
fFullRead = kFALSE;
TNamed *nm = 0;
if (fInput) {
if ((nm = dynamic_cast<TNamed *>(fInput->FindObject("ProofEventProc_Read")))) {
if (!strcmp(nm->GetTitle(), "readall")) fFullRead = kTRUE;
}
}
if (!nm) {
// Check option
if (option == "readall") fFullRead = kTRUE;
}
Info("SlaveBegin", "'%s' reading", (fFullRead ? "full" : "optimized"));
fPtHist = new TH1F("pt_dist","p_{T} Distribution",100,0,5);
fPtHist->SetDirectory(0);
fPtHist->GetXaxis()->SetTitle("p_{T}");
fPtHist->GetYaxis()->SetTitle("dN/p_{T}dp_{T}");
fOutput->Add(fPtHist);
fPzHist = new TH1F("pz_dist","p_{Z} Distribution",100,0,5.);
fPzHist->SetDirectory(0);
fPzHist->GetXaxis()->SetTitle("p_{Z}");
fPzHist->GetYaxis()->SetTitle("dN/dp_{Z}");
fOutput->Add(fPzHist);
fPxPyHist = new TH2F("px_py","p_{X} vs p_{Y} Distribution",100,-5.,5.,100,-5.,5.);
fPxPyHist->SetDirectory(0);
fPxPyHist->GetXaxis()->SetTitle("p_{X}");
fPxPyHist->GetYaxis()->SetTitle("p_{Y}");
fOutput->Add(fPxPyHist);
// Abort test, if any
TParameter<Int_t> *pi = 0;
if (fInput)
pi = dynamic_cast<TParameter<Int_t> *>(fInput->FindObject("ProofEventProc_TestAbort"));
if (pi) fTestAbort = pi->GetVal();
if (fTestAbort < -1 || fTestAbort > 1) {
Info("SlaveBegin", "unsupported value for the abort test: %d not in [-1,1] - ignore", fTestAbort);
fTestAbort = -1;
} else if (fTestAbort > -1) {
Info("SlaveBegin", "running abort test: %d", fTestAbort);
}
if (fTestAbort == 0)
Abort("Test abortion during init", kAbortProcess);
}
//_____________________________________________________________________________
Bool_t ProofEventProc::Process(Long64_t entry)
{
// The Process() function is called for each entry in the tree (or possibly
// keyed object in the case of PROOF) to be processed. The entry argument
// specifies which entry in the currently loaded tree is to be processed.
// It can be passed to either TTree::GetEntry() or TBranch::GetEntry()
// to read either all or the required parts of the data. When processing
// keyed objects with PROOF, the object is already loaded and is available
// via the fObject pointer.
//
// This function should contain the "body" of the analysis. It can contain
// simple or elaborate selection criteria, run algorithms on the data
// of the event and typically fill histograms.
// WARNING when a selector is used with a TChain, you must use
// the pointer to the current TTree to call GetEntry(entry).
// The entry is always the local entry number in the current tree.
// Assuming that fChain is the pointer to the TChain being processed,
// use fChain->GetTree()->GetEntry(entry).
if (fEntMin == -1 || entry < fEntMin) fEntMin = entry;
if (fEntMax == -1 || entry > fEntMax) fEntMax = entry;
if (fTestAbort == 1) {
Double_t rr = gRandom->Rndm();
if (rr > 0.999) {
Info("Process", "%lld -> %f", entry, rr);
Abort("Testing file abortion", kAbortFile);
return kTRUE;
}
}
if (fFullRead) {
fChain->GetTree()->GetEntry(entry);
} else {
b_event_fNtrack->GetEntry(entry);
}
if (fNtrack > 0) {
if (!fFullRead) b_fTracks->GetEntry(entry);
if (fTracks) {
for (Int_t j=0;j<fTracks->GetEntries();j++){
Track *curtrack = dynamic_cast<Track*>(fTracks->At(j));
if (curtrack) {
fPtHist->Fill(curtrack->GetPt(),1./curtrack->GetPt());
fPxPyHist->Fill(curtrack->GetPx(),curtrack->GetPy());
if (j == 0) fPzHist->Fill(curtrack->GetPz());
}
}
fTracks->Clear("C");
}
}
return kTRUE;
}
//_____________________________________________________________________________
void ProofEventProc::SlaveTerminate()
{
// The SlaveTerminate() function is called after all entries or objects
// have been processed. When running with PROOF SlaveTerminate() is called
// on each slave server.
// Save information about previous element, if any
if (fProcElem) fProcElem->Add(fEntMin, fEntMax);
if (!fProcElems) {
Warning("SlaveTerminate", "no proc elements list found!");
return;
}
// Add proc elements to the output list
TIter nxpe(fProcElems);
TObject *o = 0;
while ((o = nxpe())) { fOutput->Add(o); };
}
//_____________________________________________________________________________
void ProofEventProc::Terminate()
{
// The Terminate() function is the last function to be called during
// a query. It always runs on the client, it can be used to present
// the results graphically or save the results to file.
// Check ranges
CheckRanges();
if (gROOT->IsBatch()) return;
TCanvas* canvas = new TCanvas("event","event",800,10,700,780);
canvas->Divide(2,2);
TPad *pad1 = (TPad *) canvas->GetPad(1);
TPad *pad2 = (TPad *) canvas->GetPad(2);
TPad *pad3 = (TPad *) canvas->GetPad(3);
TPad *pad4 = (TPad *) canvas->GetPad(4);
// The number of tracks
pad1->cd();
pad1->SetLogy();
TH1F *hi = dynamic_cast<TH1F*>(fOutput->FindObject("pz_dist"));
if (hi) {
hi->SetFillColor(30);
hi->SetLineColor(9);
hi->SetLineWidth(2);
hi->DrawCopy();
} else { Warning("Terminate", "no pz dist found"); }
// The Pt distribution
pad2->cd();
pad2->SetLogy();
TH1F *hf = dynamic_cast<TH1F*>(fOutput->FindObject("pt_dist"));
if (hf) {
hf->SetFillColor(30);
hf->SetLineColor(9);
hf->SetLineWidth(2);
hf->DrawCopy();
} else { Warning("Terminate", "no pt dist found"); }
// The Px,Py distribution, color surface
TH2F *h2f = dynamic_cast<TH2F*>(fOutput->FindObject("px_py"));
if (h2f) {
// Color surface
pad3->cd();
h2f->DrawCopy("SURF1 ");
// Lego
pad4->cd();
h2f->DrawCopy("CONT2COL");
} else {
Warning("Terminate", "no px py found");
}
// Final update
canvas->cd();
canvas->Update();
}
//_____________________________________________________________________________
void ProofEventProc::CheckRanges()
{
// Check the processed event ranges when there is enough information
// The result is added to the output list
// Must be something in output
if (!fOutput || (fOutput && fOutput->GetSize() <= 0)) return;
// Create the result object and add it to the list
TNamed *nout = new TNamed("Range_Check", "OK");
fOutput->Add(nout);
// Get info to check from the input list
if (!fInput || (fInput && fInput->GetSize() <= 0)) {
nout->SetTitle("No input list");
return;
}
TNamed *ffst = dynamic_cast<TNamed *>(fInput->FindObject("Range_First_File"));
if (!ffst) {
nout->SetTitle("No first file");
return;
}
TNamed *flst = dynamic_cast<TNamed *>(fInput->FindObject("Range_Last_File"));
if (!flst) {
nout->SetTitle("No last file");
return;
}
TParameter<Int_t> *fnum =
dynamic_cast<TParameter<Int_t> *>(fInput->FindObject("Range_Num_Files"));
if (!fnum) {
nout->SetTitle("No number of files");
return;
}
// Check first file
TString fn(ffst->GetTitle()), sfst(ffst->GetTitle());
Ssiz_t ifst = fn.Index("?fst=");
if (ifst == kNPOS) {
nout->SetTitle("No first entry information in first file name");
return;
}
fn.Remove(ifst);
sfst.Remove(0, ifst + sizeof("?fst=") - 1);
if (!sfst.IsDigit()) {
nout->SetTitle("Badly formatted first entry information in first file name");
return;
}
Long64_t fst = (Long64_t) sfst.Atoi();
ProcFileElements *pfef = dynamic_cast<ProcFileElements *>(fOutput->FindObject(fn));
if (!pfef) {
nout->SetTitle("ProcFileElements for first file not found in the output list");
return;
}
if (pfef->GetFirst() != fst) {
TString t = TString::Format("First entry differs {found: %lld, expected: %lld}", pfef->GetFirst(), fst);
nout->SetTitle(t.Data());
return;
}
// Check last file
fn = flst->GetTitle();
TString slst(flst->GetTitle());
Ssiz_t ilst = fn.Index("?lst=");
if (ilst == kNPOS) {
nout->SetTitle("No last entry information in last file name");
return;
}
fn.Remove(ilst);
slst.Remove(0, ilst + sizeof("?lst=") - 1);
if (!slst.IsDigit()) {
nout->SetTitle("Badly formatted last entry information in last file name");
return;
}
Long64_t lst = (Long64_t) slst.Atoi();
ProcFileElements *pfel = dynamic_cast<ProcFileElements *>(fOutput->FindObject(fn));
if (!pfel) {
nout->SetTitle("ProcFileElements for last file not found in the output list");
return;
}
if (pfel->GetLast() != lst) {
nout->SetTitle("Last entry differs");
return;
}
// Check Number of files
Int_t nproc = 0;
TIter nxo(fOutput);
TObject *o = 0;
while ((o = nxo())) {
if (dynamic_cast<ProcFileElements *>(o)) nproc++;
}
if (fnum->GetVal() != nproc) {
nout->SetTitle("Number of processed files differs");
return;
}
}
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