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00001 #ifndef Mixing_Base_PileUp_h
00002 #define Mixing_Base_PileUp_h
00003 
00004 #include <memory>
00005 #include <string>
00006 #include <vector>
00007 #include <boost/bind.hpp>
00008 #include "FWCore/Framework/interface/Frameworkfwd.h"
00009 #include "FWCore/Sources/interface/VectorInputSource.h"
00010 #include "DataFormats/Provenance/interface/EventID.h"
00011 #include "FWCore/Framework/interface/EventPrincipal.h"
00012 #include "FWCore/MessageLogger/interface/MessageLogger.h"
00013 
00014 #include "CLHEP/Random/RandPoissonQ.h"
00015 #include "CLHEP/Random/RandFlat.h"
00016 
00017 #include "TRandom.h"
00018 #include "TFile.h"
00019 #include "TH1F.h"
00020 
00021 class TFile;
00022 class TH1F;
00023 
00024 namespace CLHEP {
00025   class RandPoissonQ;
00026   class RandPoisson;
00027 }
00028 
00029 
00030 
00031 namespace edm {
00032   class PileUp {
00033   public:
00034     explicit PileUp(ParameterSet const& pset, double averageNumber, TH1F* const histo, const bool playback);
00035     ~PileUp();
00036 
00037     template<typename T>
00038       void readPileUp(edm::EventID const & signal, std::vector<edm::EventID> &ids, T eventOperator, const int NumPU );
00039 
00040     template<typename T>
00041       void playPileUp(const std::vector<edm::EventID> &ids, T eventOperator);
00042 
00043     double averageNumber() const {return averageNumber_;}
00044     bool poisson() const {return poisson_;}
00045     bool doPileUp() {return none_ ? false :  averageNumber_>0.;}
00046     void dropUnwantedBranches(std::vector<std::string> const& wantedBranches) {
00047       input_->dropUnwantedBranches(wantedBranches);
00048     }
00049     void endJob () {
00050       input_->doEndJob();
00051     }
00052 
00053     void reload(const edm::EventSetup & setup);
00054 
00055     void CalculatePileup(int MinBunch, int MaxBunch, std::vector<int>& PileupSelection, std::vector<float>& TrueNumInteractions);
00056 
00057     //template<typename T>
00058     // void recordEventForPlayback(EventPrincipal const& eventPrincipal,
00059         //                        std::vector<edm::EventID> &ids, T& eventOperator);
00060 
00061     const unsigned int & input()const{return inputType_;}
00062     void input(unsigned int s){inputType_=s;}
00063 
00064   private:
00065     unsigned int  inputType_;
00066     std::string type_;
00067     double averageNumber_;
00068     int const intAverage_;
00069     TH1F* histo_;
00070     bool histoDistribution_;
00071     bool probFunctionDistribution_;
00072     bool poisson_;
00073     bool fixed_;
00074     bool none_;
00075     bool manage_OOT_;
00076     bool poisson_OOT_;
00077     bool fixed_OOT_;
00078 
00079     bool PU_Study_;
00080     std::string Study_type_;
00081 
00082     int  intFixed_OOT_;
00083     int  intFixed_ITPU_;
00084 
00085     std::unique_ptr<ProductRegistry> productRegistry_;
00086     std::unique_ptr<VectorInputSource> const input_;
00087     std::unique_ptr<ProcessConfiguration> processConfiguration_;
00088     std::unique_ptr<EventPrincipal> eventPrincipal_;
00089     std::unique_ptr<CLHEP::RandPoissonQ> poissonDistribution_;
00090     std::unique_ptr<CLHEP::RandPoisson>  poissonDistr_OOT_;
00091 
00092 
00093     TH1F *h1f;
00094     TH1F *hprobFunction;
00095     TFile *probFileHisto;
00096     
00097     //playback info
00098     bool playback_;
00099 
00100     // sequential reading
00101     bool sequential_;
00102 
00103     // force reading pileup events from the same lumisection as the signal event
00104     bool samelumi_;
00105     
00106     // read the seed for the histo and probability function cases
00107     int seed_;
00108   };
00109 
00110 
00111 
00112   template<typename T>
00113   class RecordEventID
00114   {
00115   private:
00116     std::vector<edm::EventID>& ids_;
00117     T& eventOperator_;
00118     int eventCount ;
00119   public:
00120     RecordEventID(std::vector<edm::EventID>& ids, T& eventOperator)
00121       : ids_(ids), eventOperator_(eventOperator), eventCount( 0 ) {}
00122     void operator()(EventPrincipal const& eventPrincipal) {
00123       ids_.push_back(eventPrincipal.id());
00124       eventOperator_(eventPrincipal, ++eventCount);
00125     }
00126   };
00127 
00128 
00139   template<typename T>
00140   void
00141     PileUp::readPileUp(edm::EventID const & signal, std::vector<edm::EventID> &ids, T eventOperator, const int pileEventCnt) {
00142 
00143     // One reason PileUp is responsible for recording event IDs is
00144     // that it is the one that knows how many events will be read.
00145     ids.reserve(pileEventCnt);
00146     RecordEventID<T> recorder(ids,eventOperator);
00147     int read;
00148     if (samelumi_) {
00149       const edm::LuminosityBlockID lumi(signal.run(), signal.luminosityBlock());
00150       if (sequential_)
00151         read = input_->loopSequentialWithID(*eventPrincipal_, lumi, pileEventCnt, recorder);
00152       else
00153         read = input_->loopRandomWithID(*eventPrincipal_, lumi, pileEventCnt, recorder);
00154     } else {
00155       if (sequential_) {
00156         // boost::bind creates a functor from recordEventForPlayback
00157         // so that recordEventForPlayback can insert itself before
00158         // the original eventOperator.
00159 
00160         read = input_->loopSequential(*eventPrincipal_, pileEventCnt, recorder);
00161         //boost::bind(&PileUp::recordEventForPlayback<T>,
00162         //                    boost::ref(*this), _1, boost::ref(ids),
00163         //                             boost::ref(eventOperator))
00164         //  );
00165           
00166       } else  {
00167         read = input_->loopRandom(*eventPrincipal_, pileEventCnt, recorder);
00168         //               boost::bind(&PileUp::recordEventForPlayback<T>,
00169         //                             boost::ref(*this), _1, boost::ref(ids),
00170         //                             boost::ref(eventOperator))
00171         //                 );
00172       }
00173     }
00174     if (read != pileEventCnt)
00175       edm::LogWarning("PileUp") << "Could not read enough pileup events: only " << read << " out of " << pileEventCnt << " requested.";
00176   }
00177 
00178 
00179 
00180   template<typename T>
00181   void
00182     PileUp::playPileUp(const std::vector<edm::EventID> &ids, T eventOperator) {
00183     //TrueNumInteractions.push_back( ids.size() ) ;
00184     input_->loopSpecified(*eventPrincipal_,ids,eventOperator);
00185   }
00186 
00187 
00188 
00191   /*  template<typename T>
00192     void recordEventForPlayback(EventPrincipal const& eventPrincipal,
00193                              std::vector<edm::EventID> &ids, T& eventOperator)
00194     {
00195       ids.push_back(eventPrincipal.id());
00196       eventOperator(eventPrincipal);
00197     }
00198   */
00199 }
00200 
00201 
00202 #endif