BOSS 7.1.1
BESIII Offline Software System
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DQASelHadron Class Reference

#include <DQASelHadron.h>

+ Inheritance diagram for DQASelHadron:

Public Member Functions

 DQASelHadron (const std::string &name, ISvcLocator *pSvcLocator)
 
StatusCode initialize ()
 
StatusCode execute ()
 
StatusCode finalize ()
 

Detailed Description

Definition at line 24 of file DQASelHadron.h.

Constructor & Destructor Documentation

◆ DQASelHadron()

DQASelHadron::DQASelHadron ( const std::string & name,
ISvcLocator * pSvcLocator )

Definition at line 65 of file DQASelHadron.cxx.

65 :
66 Algorithm(name, pSvcLocator) {
67
68 //Declare the properties
69 declareProperty("writentuple",m_writentuple = false);
70 declareProperty("useVertexDB", m_useVertexDB = false );
71 declareProperty("ecms",m_ecms = 3.097);
72 declareProperty("beamangle",m_beamangle = 0.022);
73 declareProperty("Vr0cut", m_vr0cut=1.0);
74 declareProperty("Vz0cut", m_vz0cut=10.0);
75 declareProperty("Coscut", m_coscut=0.93);
76
77 declareProperty("EnergyThreshold", m_energyThreshold=0.04);
78 declareProperty("GammaPhiCut", m_gammaPhiCut=20.0);
79 declareProperty("GammaThetaCut", m_gammaThetaCut=20.0);
80 declareProperty("GammaTrkCut", m_gammaTrkCut=20.0);
81 declareProperty("GammaTLCut", m_gammatlCut=0);
82 declareProperty("GammaTHCut", m_gammathCut=60);
83
84
85
86 declareProperty ("acoll_h_cut", m_acoll_h_cut=10.);
87 declareProperty ("poeb_h_cut", m_poeb_h_cut=0.2);
88 declareProperty ("dtof_h_cut", m_dtof_h_cut=6.);
89 declareProperty ("eop_h_cut", m_eop_h_cut=0.2);
90 declareProperty ("etotal_h_cut", m_etotal_h_cut=0.2);
91 declareProperty ("ngam_h_cut", m_ngam_h_cut=2);
92 declareProperty ("br_h_cut", m_br_h_cut=0.65);
93 declareProperty ("bz_h_cut", m_bz_h_cut=0.7);
94 declareProperty ("thr_h_cut", m_thr_h_cut=0.5);
95
96 //normally, MDC+EMC, otherwise EMC only
97 declareProperty ("m_useEMConly", m_useEMConly= false);
98 declareProperty ("m_usePID", m_usePID= false);// sub-system is under study
99 declareProperty ("m_useMDC", m_useMDC= true);
100 declareProperty ("m_useDEDX", m_useDEDX= false);// not used
101 declareProperty ("m_useTOF", m_useTOF= false);//sub-system is under study
102 declareProperty ("m_useEMC", m_useEMC= true);
103 declareProperty ("m_useMUC", m_useMUC= false);// efficiency
104
105
106}

Member Function Documentation

◆ execute()

StatusCode DQASelHadron::execute ( )

RecMdcKalTrack* mdcKalTrk = 0 ; if((*itTrk)->isMdcKalTrackValid()) mdcKalTrk = (*itTrk)->mdcKalTrack();

Definition at line 337 of file DQASelHadron.cxx.

337 {
338 setFilterPassed(false);
339 const double beamEnergy = m_ecms/2.;
340 const HepLorentzVector p_cms(m_ecms*sin(m_beamangle*0.5),0.0,0.0,m_ecms);
341 const Hep3Vector u_cms = -p_cms.boostVector();
342 MsgStream log(msgSvc(), name());
343 log << MSG::INFO << "in execute()" << endreq;
344
345
346 SmartDataPtr<Event::EventHeader> eventHeader(eventSvc(),"/Event/EventHeader");
347 if (!eventHeader)
348 {
349 log << MSG::FATAL << "Could not find Event Header" << endreq;
350 return StatusCode::SUCCESS;
351 }
352
353 m_run = eventHeader->runNumber();
354 m_rec = eventHeader->eventNumber();
355
356
357
358
359 SmartDataPtr<EvtRecEvent> evtRecEvent(eventSvc(), EventModel::EvtRec::EvtRecEvent);
360 if (!evtRecEvent)
361 {
362 log << MSG::FATAL << "Could not find EvtRecEvent" << endreq;
363 return StatusCode::SUCCESS;
364 }
365 log << MSG::INFO <<"ncharg, nneu, tottks = "
366 << evtRecEvent->totalCharged() << " , "
367 << evtRecEvent->totalNeutral() << " , "
368 << evtRecEvent->totalTracks() <<endreq;
369 // if(evtRecEvent->totalNeutral()>30)return sc;
370 m_ncharg = evtRecEvent->totalCharged();
371
372 m_nneu = evtRecEvent->totalNeutral();
373
374
375
376 HepPoint3D vx(0., 0., 0.);
377 HepSymMatrix Evx(3, 0);
378 if (m_useVertexDB) {
379 IVertexDbSvc* vtxsvc;
380 Gaudi::svcLocator()->service("VertexDbSvc", vtxsvc);
381 if(vtxsvc->isVertexValid()){
382 double* dbv = vtxsvc->PrimaryVertex();
383 double* vv = vtxsvc->SigmaPrimaryVertex();
384 // if (m_reader.isRunNumberValid( m_run)) {
385 // HepVector dbv = m_reader.PrimaryVertex( m_run);
386 // HepVector vv = m_reader.SigmaPrimaryVertex( m_run);
387 vx.setX(dbv[0]);
388 vx.setY(dbv[1]);
389 vx.setZ(dbv[2]);
390 Evx[0][0]=vv[0]*vv[0];
391 Evx[0][1]=vv[0]*vv[1];
392 Evx[1][1]=vv[1]*vv[1];
393 Evx[1][2]=vv[1]*vv[2];
394 Evx[2][2]=vv[2]*vv[2];
395 }
396 }
397
398 SmartDataPtr<EvtRecTrackCol> evtRecTrkCol(eventSvc(), EventModel::EvtRec::EvtRecTrackCol);
399 if (!evtRecTrkCol)
400 {
401 log << MSG::FATAL << "Could not find EvtRecTrackCol" << endreq;
402 return StatusCode::SUCCESS;
403 }
404 Vint iGood;
405 iGood.clear();
406
407 int nCharge = 0;
408
409 for(int i = 0; i < evtRecEvent->totalCharged(); i++){
410 EvtRecTrackIterator itTrk=evtRecTrkCol->begin() + i;
411 if(!(*itTrk)->isMdcTrackValid()) continue;
412 if(!(*itTrk)->isMdcKalTrackValid()) continue;
413
414 RecMdcTrack *mdcTrk = (*itTrk)->mdcTrack();
415 double pch=mdcTrk->p();
416 double x0=mdcTrk->x();
417 double y0=mdcTrk->y();
418 double z0=mdcTrk->z();
419// double phi0=mdcTrk->helix(1);
420// double xv=vx.x();
421// double yv=vx.y();
422// double zv=vx.z();
423// double Rxy=(x0-xv)*cos(phi0)+(y0-yv)*sin(phi0);
424// double m_vx0 = x0;
425// double m_vy0 = y0;
426// double m_vz0 = z0;
427// double m_vr0 = Rxy;
428// if(fabs(z0) >= m_vz0cut) continue;
429// if(fabs(Rxy) >= m_vr0cut) continue;
430
431
432// if(fabs(m_vz0) >= m_vz0cut) continue;
433// if(m_vr0 >= m_vr0cut) continue;
434
435
436 HepVector a = mdcTrk->helix();
437 HepSymMatrix Ea = mdcTrk->err();
438 HepPoint3D point0(0.,0.,0.);
439 HepPoint3D IP(vx[0],vx[1],vx[2]);
440 VFHelix helixip(point0,a,Ea);
441 helixip.pivot(IP);
442 HepVector vecipa = helixip.a();
443 double Rvxy0=fabs(vecipa[0]); //the distance to IP in xy plane
444 double Rvz0=vecipa[3]; //the distance to IP in z direction
445 double Rvphi0=vecipa[1];
446 if(fabs(Rvz0) >= m_vz0cut) continue;
447 if(fabs(Rvxy0) >= m_vr0cut) continue;
448
449
450 // double cost = cos(mdcTrk->theta());
451 // if(fabs(cost) >= m_coscut ) continue;
452// iGood.push_back((*itTrk)->trackId());
453 iGood.push_back(i);
454 nCharge += mdcTrk->charge();
455
456 }
457
458
459
460
461
462 //
463 // Finish Good Charged Track Selection
464 //
465 int nGood = iGood.size();
466 m_ngch=nGood;
467 log << MSG::DEBUG << "ngood, totcharge = " << nGood << " , " << nCharge << endreq;
468
469
470 if(m_ngch<2 ||m_ngch>20||(nCharge >4) ) { return StatusCode::SUCCESS; }
471 counter[1]++;
472
473 //
474 // Particle ID
475 //
476 Vint ipip, ipim, iep,iem,imup,imum;
477 ipip.clear();
478 ipim.clear();
479 iep.clear();
480 iem.clear();
481 imup.clear();
482 imum.clear();
483
484 if (m_usePID){
486 for(int i = 0; i < m_ngch; i++) {
487 EvtRecTrackIterator itTrk = evtRecTrkCol->begin() + iGood[i];
488 // if(pid) delete pid;
489 pid->init();
490 pid->setMethod(pid->methodProbability());
491 pid->setChiMinCut(4);
492 pid->setRecTrack(*itTrk);
493 pid->usePidSys(pid->useDedx() | pid->useTof1() | pid->useTof2());//|pid->useEmc()|pid->useMuc()); // use PID sub-system
494 pid->identify(pid->onlyElectron()|pid->onlyMuon()|pid->onlyPion()); // seperater Pion/Kaon/Proton
495 pid->calculate();
496 if(!(pid->IsPidInfoValid())) continue;
497 RecMdcTrack* mdcTrk = (*itTrk)->mdcTrack();
498 /// RecMdcKalTrack* mdcKalTrk = 0 ;
499 /// if((*itTrk)->isMdcKalTrackValid()) mdcKalTrk = (*itTrk)->mdcKalTrack();
500 double prob_pi = pid->probPion();
501 double prob_K = pid->probKaon();
502 double prob_p = pid->probProton();
503 double prob_e = pid->probElectron();
504 double prob_mu = pid->probMuon();
505 // std::cout << "prob "<< prob_pi << ", "<< prob_K << ", "<< prob_p << std::endl;
506 HepLorentzVector ptrk;
507 ptrk.setPx(mdcTrk->px()) ;
508 ptrk.setPy(mdcTrk->py()) ;
509 ptrk.setPz(mdcTrk->pz()) ;
510 double p3 = ptrk.mag() ;
511
512
513
514 m_pidcode[i]=1;
515 m_pidprob[i]=pid->prob(1);
516 m_pidchiDedx[i]=pid->chiDedx(1);
517 m_pidchiTof1[i]=pid->chiTof1(1);
518 m_pidchiTof2[i]=pid->chiTof2(1);
519 if(mdcTrk->charge() > 0) {
520 imup.push_back(iGood[i]);
521
522 }
523 if (mdcTrk->charge() < 0) {
524 imum.push_back(iGood[i]);
525
526 }
527
528
529 }
530 }
531 m_nep = iep.size() ;
532 m_nem = iem.size() ;
533 m_nmup = imup.size() ;
534 m_nmum = imum.size() ;
535
536 counter[2]++;
537
538 //
539 // Good neutral track selection
540 //
541 Vint iGam;
542 iGam.clear();
543 int iphoton=0;
544 for(int i = evtRecEvent->totalCharged(); i< evtRecEvent->totalTracks(); i++) {
545 if(i>=evtRecTrkCol->size())break;
546 EvtRecTrackIterator itTrk=evtRecTrkCol->begin() + i;
547 if(!(*itTrk)->isEmcShowerValid()) continue;
548 RecEmcShower *emcTrk = (*itTrk)->emcShower();
549 Hep3Vector emcpos(emcTrk->x(), emcTrk->y(), emcTrk->z());
550
551 RecEmcID showerId = emcTrk->getShowerId();
552 unsigned int npart = EmcID::barrel_ec(showerId);
553 int n = emcTrk->numHits();
554 int module=emcTrk->module();
555 double x = emcTrk->x();
556 double y = emcTrk->y();
557 double z = emcTrk->z();
558 double dx = emcTrk->dx();
559 double dy = emcTrk->dy();
560 double dth = emcTrk->dtheta();
561 double dph = emcTrk->dphi();
562 double dz = emcTrk->dz();
563 double energy = emcTrk->energy();
564 double dE = emcTrk->dE();
565 double eSeed = emcTrk->eSeed();
566 double e3x3 = emcTrk->e3x3();
567 double e5x5 = emcTrk->e5x5();
568 double secondMoment = emcTrk->secondMoment();
569 double latMoment = emcTrk->latMoment();
570 double getTime = emcTrk->time();
571 double getEAll = emcTrk->getEAll();
572 double a20Moment = emcTrk->a20Moment();
573 double a42Moment = emcTrk->a42Moment();
574 // int phigap=emcTrk->PhiGap();
575 // int thetagap=emcTrk->ThetaGap();
576 // double getETof2x1 = emcTrk->getETof2x1();
577 // double getETof2x3 = emcTrk->getETof2x3();
578 // double getELepton = emcTrk->getELepton();
579 double nseed=0;//(emcTrk->getCluster() )->getSeedSize() ;
580 HepPoint3D EmcPos(x,y,z);
581 m_nemchits[iphoton]=n;
582 m_npart[iphoton]=npart;
583 m_module[iphoton]=module;
584 m_theta[iphoton]=EmcPos.theta();
585 m_phi[iphoton]=EmcPos.phi();
586 m_x[iphoton]=x;
587 m_y[iphoton]=y;
588 m_z[iphoton]=z;
589 m_dx[iphoton]=dx;
590 m_dy[iphoton]=dy;
591 m_dz[iphoton]=dz;
592 m_dtheta[iphoton]=dth;
593 m_dphi[iphoton]=dph;
594 m_energy[iphoton]=energy;
595 m_dE[iphoton]=dE;
596 m_eSeed[iphoton]=eSeed;
597 m_nSeed[iphoton]=nseed;
598 m_e3x3[iphoton]=e3x3;
599 m_e5x5[iphoton]=e5x5;
600 m_secondMoment[iphoton]=secondMoment;
601 m_latMoment[iphoton]=latMoment;
602 m_getTime[iphoton]=getTime;
603 m_getEAll[iphoton]=getEAll;
604 m_a20Moment[iphoton]=a20Moment;
605 m_a42Moment[iphoton]=a42Moment;
606
607 // m_getELepton[iphoton]=getELepton;
608 // m_getETof2x1[iphoton]=getETof2x1;
609 // m_getETof2x3[iphoton]=getETof2x3;
610 // m_PhiGap[iphoton]=phigap;
611 // m_ThetaGap[iphoton]=thetagap;
612 double dthe = 200.;
613 double dphi = 200.;
614 double dang = 200.;
615
616 // find the nearest charged track
617 for(int j = 0; j < nGood; j++) {
618
619
620 EvtRecTrackIterator jtTrk = evtRecTrkCol->begin() +iGood[j];
621 if (!(*jtTrk)->isMdcTrackValid()) continue;
622 RecMdcTrack *jtmdcTrk = (*jtTrk)->mdcTrack();
623 double jtcharge = jtmdcTrk->charge();
624 if(!(*jtTrk)->isExtTrackValid()) continue;
625 RecExtTrack *extTrk = (*jtTrk)->extTrack();
626 if(extTrk->emcVolumeNumber() == -1) continue;
627 Hep3Vector extpos = extTrk->emcPosition();
628 // double ctht = extpos.cosTheta(emcpos);
629 double angd = extpos.angle(emcpos);
630 double thed = extpos.theta() - emcpos.theta();
631 double phid = extpos.deltaPhi(emcpos);
632 thed = fmod(thed+CLHEP::twopi+CLHEP::twopi+pi, CLHEP::twopi) - CLHEP::pi;
633 phid = fmod(phid+CLHEP::twopi+CLHEP::twopi+pi, CLHEP::twopi) - CLHEP::pi;
634
635 if(fabs(thed) < fabs(dthe)) dthe = thed;
636 if(fabs(phid) < fabs(dphi)) dphi = phid;
637 if(angd < dang) dang = angd;
638
639 }
640
641
642
643 //
644 // good photon cut will be set here
645 //
646
647 dthe = dthe * 180 / (CLHEP::pi);
648 dphi = dphi * 180 / (CLHEP::pi);
649 dang = dang * 180 / (CLHEP::pi);
650 double eraw = emcTrk->energy();
651 double phi = emcTrk->phi();
652 double the = emcTrk->theta();
653
654 m_delphi[iphoton]=dphi;
655 m_delthe[iphoton]=dthe;
656 m_delang[iphoton]=dang;
657 if(energy < m_energyThreshold) continue;
658 if(getTime>m_gammathCut||getTime<m_gammatlCut)continue;
659 // if((fabs(dthe) < m_gammaThetaCut) && (fabs(dphi)<m_gammaPhiCut) ) continue;
660 if(dang< m_gammaTrkCut) continue;
661 iphoton++;
662 iGam.push_back(i);
663 if(iphoton>=40)return StatusCode::SUCCESS;
664 }
665
666 int nGam = iGam.size();
667 m_nGam=nGam;
668 // std::cout << "num Good Photon " << m_nGam << " , " <<evtRecEvent->totalNeutral()<<std::endl;
669 //std::cout<<"dbg_4"<<std::endl;
670 counter[3]++;
671
672 double egam_ext=0;
673 double ex_gam=0;
674 double ey_gam=0;
675 double ez_gam=0;
676 double et_gam=0;
677 double e_gam=0;
678 for(int i = 0; i < m_nGam; i++) {
679 EvtRecTrackIterator itTrk = evtRecTrkCol->begin()+ iGam[i];
680 if(!(*itTrk)->isEmcShowerValid()) continue;
681 RecEmcShower* emcTrk = (*itTrk)->emcShower();
682 double eraw = emcTrk->energy();
683 double phi = emcTrk->phi();
684 double the = emcTrk->theta();
685 HepLorentzVector ptrk;
686 ex_gam+=eraw*sin(the)*cos(phi);
687 ey_gam+=eraw*sin(the)*sin(phi);
688 ez_gam+=eraw*cos(the);
689 et_gam+=eraw*sin(the);
690 e_gam+=eraw ;
691 if(eraw>=egam_ext)
692 {
693 egam_ext=eraw;
694 }
695
696 }
697
698
699
700
701
702 double px_had=0;
703 double py_had=0;
704 double pz_had=0;
705 double t_pxy2 = 0;
706 double pt_had=0;
707 double p_had=0;
708 double e_had=0;
709 double p_max=0.;
710 double e_max=0.;
711 //
712 // check good charged track's infomation
713 //
714
715
716
717 double ctrk_theta = -10;
718 double ctrk_phi = -10;
719 for(int i = 0; i < m_ngch; i++ ){
720
721 EvtRecTrackIterator itTrk = evtRecTrkCol->begin() + iGood[i];
722
723 if(!(*itTrk)->isMdcTrackValid()) continue; // MDC information
724 if(!(*itTrk)->isMdcKalTrackValid()) continue;
725
726 RecMdcTrack* mdcTrk = (*itTrk)->mdcTrack();
727 RecMdcKalTrack *mdcKalTrk = (*itTrk)->mdcKalTrack();
728
729
730 // if ( m_ngch==2 &&mdcTrk->charge()>0) i = 0 ;
731 // if ( m_ngch==2 &&mdcTrk->charge()<0) i = 1 ;
732 m_charge[i] = mdcTrk->charge();
733 m_vx0[i] = mdcTrk->x();
734 m_vy0[i] = mdcTrk->y();
735 m_vz0[i] = mdcTrk->z();
736 m_px[i] = mdcTrk->px();
737 m_py[i] = mdcTrk->py();
738 m_pz[i] = mdcTrk->pz();
739 m_p[i] = mdcTrk->p();
740 ctrk_theta = mdcTrk->theta();
741 ctrk_phi = mdcTrk->phi();
743 // double ptrk = mdcKalTrk->p() ;
744 m_kal_vx0[i] = mdcKalTrk->x();
745 m_kal_vy0[i] = mdcKalTrk->y();
746 m_kal_vz0[i] = mdcKalTrk->z();
747
748
749 m_kal_px[i] = mdcKalTrk->px();
750 m_kal_py[i] = mdcKalTrk->py();
751 m_kal_pz[i] = mdcKalTrk->pz();
752// m_kal_p[i] = mdcKalTrk->p(); // pxy() and p() are not filled in the reconstruction algorithm
753 t_pxy2 = m_kal_px[i]*m_kal_px[i] + m_kal_py[i]*m_kal_py[i];
754 m_kal_p[i] = sqrt(t_pxy2 + m_kal_pz[i]*m_kal_pz[i]);
755 double ptrk = m_kal_p[i];
756 px_had+=m_kal_px[i];
757 py_had+=m_kal_py[i];
758 pz_had+=m_kal_pz[i];
759 pt_had+=sqrt(t_pxy2);
760 p_had+=m_kal_p[i];
761 e_had+=sqrt(m_kal_p[i]*m_kal_p[i]+xmass[2]*xmass[2]);
762 if(m_useDEDX&&(*itTrk)->isMdcDedxValid()) { // DEDX information
763
764 RecMdcDedx* dedxTrk = (*itTrk)->mdcDedx();
765 m_probPH[i]= dedxTrk->probPH();
766 m_normPH[i]= dedxTrk->normPH();
767
768 m_chie[i] = dedxTrk->chiE();
769 m_chimu[i] = dedxTrk->chiMu();
770 m_chipi[i] = dedxTrk->chiPi();
771 m_chik[i] = dedxTrk->chiK();
772 m_chip[i] = dedxTrk->chiP();
773 m_ghit[i] = dedxTrk->numGoodHits();
774 m_thit[i] = dedxTrk->numTotalHits();
775 }
776
777 if((*itTrk)->isEmcShowerValid()) {
778
779 RecEmcShower *emcTrk = (*itTrk)->emcShower();
780 m_e_emc[i] = emcTrk->energy();
781 m_phi_emc[i] = emcTrk->phi();
782 m_theta_emc[i] = emcTrk->theta();
783 if(m_e_emc[i]>e_max){
784 p_max=m_p[i];
785 e_max=m_e_emc[i];
786 }
787 } else {
788 m_e_emc[i] = 0;
789 m_phi_emc[i] = -10;
790 m_theta_emc[i] = -10;
791 }
792
793
794
795 if(m_useMUC&&(*itTrk)->isMucTrackValid()){
796
797 RecMucTrack* mucTrk = (*itTrk)->mucTrack() ;
798 m_nhit_muc[i] = mucTrk->numHits() ;
799 m_nlay_muc[i] = mucTrk->numLayers() ;
800
801 }
802
803
804 if(m_useTOF&&(*itTrk)->isTofTrackValid()) { //TOF information
805
806 SmartRefVector<RecTofTrack> tofTrkCol = (*itTrk)->tofTrack();
807
808 SmartRefVector<RecTofTrack>::iterator iter_tof = tofTrkCol.begin();
809
810 for(;iter_tof != tofTrkCol.end(); iter_tof++ ) {
811 TofHitStatus *status = new TofHitStatus;
812 status->setStatus((*iter_tof)->status());
813
814 if(!(status->is_barrel())){//endcap
815 if( (status->is_cluster()) ) m_t_etof[i] = (*iter_tof)->tof();
816 if( !(status->is_counter()) ){if(status) delete status; continue;} // ?
817 if( status->layer()!=0 ){if(status) delete status; continue;}//layer1
818 double path=(*iter_tof)->path(); // ?
819 double tof = (*iter_tof)->tof();
820 double ph = (*iter_tof)->ph();
821 double rhit = (*iter_tof)->zrhit();
822 double qual = 0.0 + (*iter_tof)->quality();
823 double cntr = 0.0 + (*iter_tof)->tofID();
824 double texp[5];
825 for(int j = 0; j < 5; j++) {
826 double gb = ptrk/xmass[j];
827 double beta = gb/sqrt(1+gb*gb);
828 texp[j] = path /beta/velc;
829 }
830
831 m_qual_etof[i] = qual;
832 m_tof_etof[i] = tof ;
833 }
834 else {//barrel
835 if( (status->is_cluster()) ) m_t_btof[i] = (*iter_tof)->tof();
836 if( !(status->is_counter()) ){if(status) delete status; continue;} // ?
837 if(status->layer()==1){ //layer1
838 double path=(*iter_tof)->path(); // ?
839 double tof = (*iter_tof)->tof();
840 double ph = (*iter_tof)->ph();
841 double rhit = (*iter_tof)->zrhit();
842 double qual = 0.0 + (*iter_tof)->quality();
843 double cntr = 0.0 + (*iter_tof)->tofID();
844 double texp[5];
845 for(int j = 0; j < 5; j++) {
846 double gb = ptrk/xmass[j];
847 double beta = gb/sqrt(1+gb*gb);
848 texp[j] = path /beta/velc;
849 }
850
851 m_qual_btof1[i] = qual;
852 m_tof_btof1[i] = tof ;
853 }
854
855 if(status->layer()==2){//layer2
856 double path=(*iter_tof)->path(); // ?
857 double tof = (*iter_tof)->tof();
858 double ph = (*iter_tof)->ph();
859 double rhit = (*iter_tof)->zrhit();
860 double qual = 0.0 + (*iter_tof)->quality();
861 double cntr = 0.0 + (*iter_tof)->tofID();
862 double texp[5];
863 for(int j = 0; j < 5; j++) {
864 double gb = ptrk/xmass[j];
865 double beta = gb/sqrt(1+gb*gb);
866 texp[j] = path /beta/velc;
867 }
868
869 m_qual_btof2[i] = qual;
870 m_tof_btof2[i] = tof ;
871 }
872 }
873 if(status) delete status;
874 }
875
876
877
878 }
879
880 }
881
882 //tag
883
884
885 m_hadrontag=0;
887 if(m_ngch != 2 )m_hadrontag=11111;
888 else if(m_ngch == 2 &&nCharge==0) {
889 EvtRecTrackIterator itTrk1;
890
891 EvtRecTrackIterator itTrk2;
892
893 RecMdcKalTrack *mdcKalTrk1;
894
895 RecMdcKalTrack *mdcKalTrk2;
896
897 HepLorentzVector p41e,p42e,p4le;
898 Hep3Vector p31e,p32e,p3le;
899 HepLorentzVector p41m,p42m,p4lm;
900 Hep3Vector p31m,p32m,p3lm;
901 HepLorentzVector p41h,p42h,p4lh;
902 Hep3Vector p31h,p32h,p3lh;
903 WTrackParameter w1_ini,w1_ve,w1_vmu;
904 WTrackParameter w2_ini,w2_ve,w2_vmu;
905 int iip=0;
906 int iim=0;
907 for(int i = 0; i < m_ngch; i++ ){
908 if(m_charge[i]>0)itTrk1= evtRecTrkCol->begin() + iGood[i];
909 if(m_charge[i]<0) itTrk2= evtRecTrkCol->begin() + iGood[i];
910 if(m_charge[i]>0) mdcKalTrk1 = (*itTrk1)->mdcKalTrack();
911 if(m_charge[i]<0) mdcKalTrk2 = (*itTrk2)->mdcKalTrack();
912 if(m_charge[i]>0)iip=i;
913 if(m_charge[i]<0)iim=i;
914
915
916
917 if(m_charge[i]>0) w1_ini=WTrackParameter (xmass[2],mdcKalTrk1->helix(),mdcKalTrk1->err());
918 if(m_charge[i]<0) w2_ini=WTrackParameter (xmass[2],mdcKalTrk2 ->helix(),mdcKalTrk2 ->err());
919 if(m_charge[i]>0) p41h =w1_ini.p();
920 if(m_charge[i]<0) p42h =w2_ini.p();
921 if(m_charge[i]>0) p41h.boost(u_cms);
922 if(m_charge[i]<0) p42h.boost(u_cms);
923 if(m_charge[i]>0) p31h = p41h.vect();
924 if(m_charge[i]<0) p32h = p42h.vect();
925
926 if(m_charge[i]>0) p41e =w1_ini.p();
927 if(m_charge[i]<0) p42e =w2_ini.p();
928 if(m_charge[i]>0) p41e.boost(u_cms);
929 if(m_charge[i]<0) p42e.boost(u_cms);
930 if(m_charge[i]>0) p31e = p41e.vect();
931 if(m_charge[i]<0) p32e = p42e.vect();
932
933
934
935
936 if(m_charge[i]>0){
937 m_px_cms_ep=p41h.px();
938 m_py_cms_ep=p41h.py();
939 m_pz_cms_ep=p41h.pz();
940 m_e_cms_ep=p41h.e();
941 }
942 if(m_charge[i]<0){
943 m_px_cms_em=p42h.px();
944 m_py_cms_em=p42h.py();
945 m_pz_cms_em=p42h.pz();
946 m_e_cms_em=p42h.e();
947 }
948
949 }
950 double e01=m_e_emc[iip];//m_e_cms_ep;
951 double e02=m_e_emc[iim];//m_e_cms_em;
952
953 int ilarge=( e01 > e02 ) ?iip:iim;
954
955 p4lh=( e01 > e02 ) ?p41h:p42h;
956
957 p3lh=( e01 > e02 ) ?p31h:p32h;
958
959 double acollh= 180.-p31h.angle(p32h)* 180.0 / CLHEP::pi;
960 double acoplh= 180.- (p31h.perpPart()).angle(p32h.perpPart ())* 180.0 / CLHEP::pi;
961 double poeb1h=p41h.rho()/beamEnergy;
962 double poeb2h=p42h.rho()/beamEnergy;
963 double poeblh=p4lh.rho()/beamEnergy;
964
965 double eoeb1=m_e_emc[iip]/beamEnergy;
966 double eoeb2=m_e_emc[iim]/beamEnergy;
967 double eop1=0;
968 if(p41h.rho()>0)eop1=m_e_emc[iip]/p41h.rho();
969 double eop2=0;
970 if(p42h.rho()>0)eop2=m_e_emc[iim]/p42h.rho();
971
972 double eope1=0;
973 if(p41e.rho()>0)eope1=m_e_emc[iip]/p41e.rho();
974 double eope2=0;
975 if(p42e.rho()>0)eope2=m_e_emc[iim]/p42e.rho();
976 double eopm1=0;
977 if(p41m.rho()>0)eopm1=m_e_emc[iip]/p41m.rho();
978 double eopm2=0;
979 if(p42m.rho()>0)eopm2=m_e_emc[iim]/p42m.rho();
980
981 double exoeb1= m_e_emc[iip]*sin(m_theta_emc[iip])*cos(m_phi_emc[iip])/beamEnergy;
982 double eyoeb1= m_e_emc[iip]*sin(m_theta_emc[iip])*sin(m_phi_emc[iip])/beamEnergy;
983 double ezoeb1=m_e_emc[iip]*cos(m_theta_emc[iip])/beamEnergy;
984 double etoeb1=m_e_emc[iip]*sin(m_theta_emc[iip])/beamEnergy;
985
986 double exoeb2= m_e_emc[iim]*sin(m_theta_emc[iim])*cos(m_phi_emc[iim])/beamEnergy;
987 double eyoeb2= m_e_emc[iim]*sin(m_theta_emc[iim])*sin(m_phi_emc[iim])/beamEnergy;
988 double ezoeb2=m_e_emc[iim]*cos(m_theta_emc[iim])/beamEnergy;
989 double etoeb2=m_e_emc[iim]*sin(m_theta_emc[iim])/beamEnergy;
990
991 double eoebl=m_e_emc[ilarge]/beamEnergy;
992
993 double eopl=0;
994 if(p4lh.rho()>0)eopl=m_e_emc[ilarge]/p4lh.rho();
995
996 double exoebl= m_e_emc[ilarge]*sin(m_theta_emc[ilarge])*cos(m_phi_emc[ilarge])/beamEnergy;
997 double eyoebl= m_e_emc[ilarge]*sin(m_theta_emc[ilarge])*sin(m_phi_emc[ilarge])/beamEnergy;
998 double ezoebl=m_e_emc[ilarge]*cos(m_theta_emc[ilarge])/beamEnergy;
999 double etoebl=m_e_emc[ilarge]*sin(m_theta_emc[ilarge])/beamEnergy;
1000
1001 int mucinfo1=(m_nhit_muc[iip]>=2&&m_nlay_muc[iip]>=2 ) ? 1 : 0;
1002 int mucinfo2=(m_nhit_muc[iim]>=2&&m_nlay_muc[iim]>=2) ? 1 : 0;
1003 int mucinfol=(m_nhit_muc[ilarge]>=2&&m_nlay_muc[ilarge]>=2) ? 1 : 0;
1004 int pidel=( e01 > e02 ) ? m_nep : m_nem;
1005 int pidmul=( e01 > e02 ) ? m_nmup : m_nmum;
1006 double deltatof=0.0;
1007
1008
1009// if(m_tof_btof2[iip]*m_tof_btof2[iim]!=0) deltatof+=fabs(m_tof_btof2[iip]-m_tof_btof2[iim]);
1010// if(m_tof_btof1[iip]*m_tof_btof1[iim]!=0)deltatof+=fabs(m_tof_btof1[iip]-m_tof_btof1[iim]);
1011// if(m_tof_etof[iip]*m_tof_etof[iim]!=0)deltatof+=fabs(m_tof_etof[iip]-m_tof_etof[iim]);
1012
1013 // if(!m_endcap) {
1014 if(m_t_btof[iip]*m_t_btof[iim]!=0) deltatof=fabs(m_t_btof[iip]-m_t_btof[iim]);
1015 // }
1016 // else {
1017 // if(m_t_etof[iip]*m_t_etof[iim]!=0)deltatof=fabs(m_t_etof[iip]-m_t_etof[iim]);
1018 // }
1019
1020
1021
1022
1023
1024
1025 // if (acollh>m_acoll_h_cut)m_hadrontag+=1;
1026 if ((acollh>m_acoll_h_cut)||(!m_useEMC||m_nGam>=m_ngam_h_cut))m_hadrontag+=11;
1027 if (!m_useTOF||(deltatof<m_dtof_h_cut))m_hadrontag+=100;
1028 if (!m_useMUC||(mucinfo1==0||mucinfo2==0))m_hadrontag+=1000;
1029 if (!m_useEMC||(fabs(eope1-1)>m_eop_h_cut&&fabs(eope2-1)>m_eop_h_cut))m_hadrontag+=10000;
1030
1031
1032
1033 m_deltatof=deltatof;
1034 m_eop1=eope1;
1035 m_eop2=eope2;
1036 m_eoeb1=eoeb1;
1037 m_eoeb2=eoeb2;
1038
1039 m_etoeb1=etoeb1;
1040 m_etoeb2=etoeb2;
1041 m_mucinfo1=mucinfo1;
1042 m_mucinfo2=mucinfo2;
1043
1044
1045
1046
1047
1048 m_acoll=acollh;
1049 m_acopl=acoplh;
1050 m_poeb1=poeb1h;
1051 m_poeb2=poeb2h;
1052 m_cos_ep=p41h.cosTheta ();
1053 m_cos_em=p42h.cosTheta ();
1054 m_mass_ee=(p41h+p42h).m();
1055
1056
1057
1058
1059
1060 }
1061 double br=0;
1062 double bz=0;
1063 double thr=0;
1064 double evis=0;
1065 WTrackParameter w1_vh,w2_vh,w3_vh;
1066
1067 br=sqrt((px_had+ex_gam)*(px_had+ex_gam)+
1068 (py_had+ey_gam)*(py_had+ey_gam))/(pt_had+et_gam);
1069 bz= fabs(pz_had+ez_gam)/(p_had+e_gam);
1070 thr=p_had+e_gam;
1071 evis=e_had+e_gam;
1072 log << MSG::DEBUG << "hadron " << px_had << " " << py_had << " " << pz_had
1073 << " " << pt_had << " " << p_had << " " << br << " " << bz << endmsg;
1074 log << MSG::DEBUG << "Gamma " << ex_gam << " " << ey_gam << " " << ez_gam
1075 << " " << e_gam << " " << thr/beamEnergy << endmsg;
1076 if(!m_useEMC||((br<m_br_h_cut)&&(bz<m_bz_h_cut)))m_hadrontag+=100000;
1077 if(!m_useEMC||thr/beamEnergy>m_thr_h_cut) m_hadrontag+=1000000;
1078 m_emax=egam_ext;
1079 m_esum=e_gam;
1080 m_br=br;
1081 m_bz=bz;
1082 m_thr=thr;
1083 m_evis=evis;
1084 log << MSG::INFO << "m_hadrontag= "<<m_hadrontag << endreq;
1085// std::cout<<"m_sbhabhatag= "<<m_sbhabhatag<<std::endl;
1086// std::cout<<"m_sdimutag= "<<m_sdimutag<<std::endl;
1087// std::cout<<"m_hadrontag= "<<m_hadrontag<<std::endl;
1088 if(m_hadrontag==1111111){
1089 nhadron++;
1090 for(int i = 0; i < m_ngch; i++ ){
1091// m_ha_costheta->Fill(cos(m_theta[i]));
1092// m_ha_phi->Fill(m_phi[i]);
1093 m_ha_costheta->Fill(ctrk_theta);
1094 m_ha_phi->Fill(ctrk_phi);
1095 }
1096 if(m_ngch >= 3){
1097 RecMdcKalTrack *ktrk0 = (*(evtRecTrkCol->begin() + iGood[0]))->mdcKalTrack();
1098 RecMdcKalTrack *ktrk1 = (*(evtRecTrkCol->begin() + iGood[1]))->mdcKalTrack();
1099 RecMdcKalTrack *ktrk2 = (*(evtRecTrkCol->begin() + iGood[2]))->mdcKalTrack();
1100// w1_vh=WTrackParameter (xmass[2],ktrk0->getZHelix(),ktrk0->getZError());
1101// w2_vh=WTrackParameter (xmass[2],ktrk1->getZHelix(),ktrk1->getZError());
1102// w3_vh=WTrackParameter (xmass[2],ktrk2->getZHelix(),ktrk2->getZError());
1103// vtxfit->init();
1104// vtxfit->AddTrack(0, w1_vh);
1105// vtxfit->AddTrack(1, w2_vh);
1106// vtxfit->AddTrack(2, w3_vh);
1107// vtxfit->AddVertex(0, vxpar,0, 1);
1108// if(vtxfit->Fit(0)) {
1109// m_ha_vx->Fill((vtxfit->vx(0)).x());
1110// m_ha_vy->Fill((vtxfit->vx(0)).y());
1111// m_ha_vz->Fill((vtxfit->vx(0)).z());
1112// }
1113
1114 //ktrk0->setPidType(RecMdcKalTrack::pion);
1115 // ktrk1->setPidType(RecMdcKalTrack::pion);
1116 // ktrk2->setPidType(RecMdcKalTrack::pion);
1117 fvtxfit->init();
1118 fvtxfit->addTrack(0,ktrk0->helix(), ktrk0->err());
1119 fvtxfit->addTrack(1,ktrk1->helix(), ktrk1->err());
1120 fvtxfit->addTrack(2,ktrk2->helix(), ktrk2->err());
1121 if(fvtxfit->Fit()) {
1122 m_ha_vx->Fill((fvtxfit->Vx())[0]);
1123 m_ha_vy->Fill((fvtxfit->Vx())[1]);
1124 m_ha_vz->Fill((fvtxfit->Vx())[2]);
1125 }
1126
1127
1128 }
1129
1130 m_ha_br->Fill(br);
1131 m_ha_bz->Fill(bz);
1132 m_ha_pmax->Fill(p_max);
1133 m_ha_emax->Fill(e_max);
1134 m_ha_etot->Fill(evis);
1135 m_ha_nneu->Fill(nGam);
1136 m_ha_nchg->Fill(m_ngch);
1137 if(m_ngch==0){
1138 n0prong++;
1139
1140 }
1141 if(m_ngch==2&&nCharge == 0){
1142 n2prong++;
1143
1144 }
1145 if(m_ngch==4&&nCharge == 0){
1146 n4prong++;
1147
1148 }
1149
1150 if(m_ngch>4){
1151 ng4prong++;
1152
1153 }
1154 if(m_writentuple)m_tuple1 -> write();
1155 setFilterPassed(true);
1156
1157 }
1158
1159
1160 return StatusCode::SUCCESS;
1161
1162
1163}
double sin(const BesAngle a)
Definition BesAngle.h:210
double cos(const BesAngle a)
Definition BesAngle.h:213
const Hep3Vector u_cms
const HepLorentzVector p_cms(0.034067, 0.0, 0.0, 3.097)
const Int_t n
Double_t x[10]
EvtRecTrackCol::iterator EvtRecTrackIterator
const double xmass[5]
Definition Gam4pikp.cxx:50
const double velc
Definition Gam4pikp.cxx:51
std::vector< int > Vint
Definition Gam4pikp.cxx:52
************Class m_ypar INTEGER m_KeyWgt INTEGER m_KeyIHVP INTEGER m_KeyGPS INTEGER m_IsBeamPolarized INTEGER m_EvtGenInterface DOUBLE PRECISION m_Emin DOUBLE PRECISION m_sphot DOUBLE PRECISION m_Xenph DOUBLE PRECISION m_q2 DOUBLE PRECISION m_PolBeam2 DOUBLE PRECISION m_xErrPb *COMMON c_KK2f $ !CMS energy average $ !Spin Polarization vector first beam $ !Spin Polarization vector second beam $ !Beam energy spread[GeV] $ !minimum hadronization energy[GeV] $ !input READ never touch them !$ !debug facility $ !maximum weight $ !inverse alfaQED $ !minimum real photon energy
Definition KK2f.h:50
IMessageSvc * msgSvc()
double dy() const
double latMoment() const
double a42Moment() const
double eSeed() const
double dphi() const
double theta() const
int module() const
double e3x3() const
double dz() const
double phi() const
double dx() const
double secondMoment() const
double x() const
double e5x5() const
double time() const
double z() const
int numHits() const
double a20Moment() const
double energy() const
double dE() const
double dtheta() const
double y() const
const Hep3Vector emcPosition() const
const int emcVolumeNumber() const
double probPH() const
Definition DstMdcDedx.h:66
double chiE() const
Definition DstMdcDedx.h:59
int numTotalHits() const
Definition DstMdcDedx.h:65
int numGoodHits() const
Definition DstMdcDedx.h:64
double normPH() const
Definition DstMdcDedx.h:67
double chiPi() const
Definition DstMdcDedx.h:61
double chiK() const
Definition DstMdcDedx.h:62
double chiMu() const
Definition DstMdcDedx.h:60
double chiP() const
Definition DstMdcDedx.h:63
const double y() const
const HepVector & helix() const
const double px() const
const double z() const
static void setPidType(PidType pidType)
const double pz() const
const double py() const
const HepSymMatrix & err() const
const double x() const
const double theta() const
Definition DstMdcTrack.h:59
const double py() const
Definition DstMdcTrack.h:56
const HepSymMatrix err() const
const int charge() const
Definition DstMdcTrack.h:53
const double px() const
Definition DstMdcTrack.h:55
const double phi() const
Definition DstMdcTrack.h:60
const double pz() const
Definition DstMdcTrack.h:57
const HepVector helix() const
......
const double z() const
Definition DstMdcTrack.h:63
const double p() const
Definition DstMdcTrack.h:58
const double y() const
Definition DstMdcTrack.h:62
const double x() const
Definition DstMdcTrack.h:61
int numHits() const
Definition DstMucTrack.h:41
int numLayers() const
Definition DstMucTrack.h:42
static unsigned int barrel_ec(const Identifier &id)
Values of different levels (failure returns 0)
Definition EmcID.cxx:38
static FastVertexFit * instance()
void addTrack(const int number, const HepVector helix, const HepSymMatrix err)
HepVector Vx() const
virtual bool isVertexValid()=0
virtual double * SigmaPrimaryVertex()=0
virtual double * PrimaryVertex()=0
int useTof2() const
int methodProbability() const
int useDedx() const
int onlyMuon() const
int onlyElectron() const
int onlyPion() const
int useTof1() const
void setChiMinCut(const double chi=4)
void setRecTrack(EvtRecTrack *trk)
double probKaon() const
Definition ParticleID.h:124
void setMethod(const int method)
Definition ParticleID.h:94
double prob(int n) const
Definition ParticleID.h:114
double chiTof2(int n) const
void identify(const int pidcase)
Definition ParticleID.h:103
double probMuon() const
Definition ParticleID.h:122
double probElectron() const
Definition ParticleID.h:121
void usePidSys(const int pidsys)
Definition ParticleID.h:97
static ParticleID * instance()
bool IsPidInfoValid() const
double probPion() const
Definition ParticleID.h:123
double chiTof1(int n) const
void calculate()
void init()
double probProton() const
Definition ParticleID.h:125
double chiDedx(int n) const
RecEmcID getShowerId() const
RecEmcEnergy getEAll() const
bool is_barrel() const
unsigned int layer() const
bool is_cluster() const
void setStatus(unsigned int status)
bool is_counter() const
HepLorentzVector p() const
double y[1000]
_EXTERN_ std::string EvtRecEvent
Definition EventModel.h:116
_EXTERN_ std::string EvtRecTrackCol
Definition EventModel.h:117
float ptrk
double double * p3
Definition qcdloop1.h:76
const float pi
Definition vector3.h:133

◆ finalize()

StatusCode DQASelHadron::finalize ( )

Definition at line 1166 of file DQASelHadron.cxx.

1166 {
1167
1168 MsgStream log(msgSvc(), name());
1169 log << MSG::INFO << "in finalize()" << endmsg;
1170 log << MSG::INFO << counter << endmsg;
1171 log << MSG::ALWAYS << "nhadron = " << nhadron << endmsg;
1172 log << MSG::INFO << "n0prong = " << n0prong << endmsg;
1173 log << MSG::INFO << "n2prong = " << n2prong << endmsg;
1174 log << MSG::INFO << "n4prong = " << n4prong << endmsg;
1175 log << MSG::INFO << "ng4prong = " << ng4prong << endmsg;
1176 return StatusCode::SUCCESS;
1177}

◆ initialize()

StatusCode DQASelHadron::initialize ( )

Definition at line 110 of file DQASelHadron.cxx.

110 {
111 MsgStream log(msgSvc(), name());
112
113 log << MSG::INFO << "in initialize()" << endmsg;
114 StatusCode status;
115 status = service("THistSvc", m_thistsvc);
116 if(status.isFailure() ){
117 log << MSG::INFO << "Unable to retrieve pointer to THistSvc" << endreq;
118 return status;
119 }
120
121
122 m_ha_costheta = new TH1F( "PHY_HAD_SUM_costheta", "PHY_HAD_SUM_costheta", 100, -1, 1 );
123 status = m_thistsvc->regHist("/DQAHist/Hadron/ha_costheta", m_ha_costheta);
124 m_ha_phi = new TH1F( "PHY_HAD_SUM_phi", "PHY_HAD_SUM_phi", 128, -3.2, 3.2 );
125 status = m_thistsvc->regHist("/DQAHist/Hadron/ha_phi", m_ha_phi);
126 m_ha_pmax = new TH1F( "PHY_HAD_SUM_pmax", "PHY_HAD_SUM_pmax", 100, 0, 2 );
127 status = m_thistsvc->regHist("/DQAHist/Hadron/ha_pmax", m_ha_pmax);
128 m_ha_emax = new TH1F( "PHY_HAD_SUM_emax", "PHY_HAD_SUM_emax", 100, 0, 2 );
129 status = m_thistsvc->regHist("/DQAHist/Hadron/ha_emax", m_ha_emax);
130 m_ha_etot = new TH1F( "PHY_HAD_SUM_etot", "PHY_HAD_SUM_etot", 100, 0, 4 );
131 status = m_thistsvc->regHist("/DQAHist/Hadron/ha_etot", m_ha_etot);
132 m_ha_br = new TH1F( "PHY_HAD_SUM_br", "PHY_HAD_SUM_br", 100, 0, 2 );
133 status = m_thistsvc->regHist("/DQAHist/Hadron/ha_br", m_ha_br);
134 m_ha_bz = new TH1F( "PHY_HAD_SUM_bz", "PHY_HAD_SUM_bz", 100, 0, 2 );
135 status = m_thistsvc->regHist("/DQAHist/Hadron/ha_bz", m_ha_bz);
136 m_ha_nneu = new TH1I( "PHY_HAD_SUM_nneu", "PHY_HAD_SUM_nneu", 20, 0, 20 );
137 status = m_thistsvc->regHist("/DQAHist/Hadron/ha_nneu", m_ha_nneu);
138 m_ha_nchg = new TH1I( "PHY_HAD_SUM_nchg", "PHY_HAD_SUM_nchg", 20, 0, 20 );
139 status = m_thistsvc->regHist("/DQAHist/Hadron/ha_nchg", m_ha_nchg);
140
141 m_ha_vx = new TH1F( "PHY_HAD_FLS_vx", "PHY_HAD_FLS_vx", 100, -1., 1.);
142 status = m_thistsvc->regHist("/DQAHist/Hadron/ha_vx", m_ha_vx);
143 m_ha_vy = new TH1F( "PHY_HAD_FLS_vy", "PHY_HAD_FLS_vy", 100, -1., 1.);
144 status = m_thistsvc->regHist("/DQAHist/Hadron/ha_vy", m_ha_vy);
145 m_ha_vz = new TH1F( "PHY_HAD_FLS_vz", "PHY_HAD_FLS_vz", 100, -10.0, 10.);
146 status = m_thistsvc->regHist("/DQAHist/Hadron/ha_vz", m_ha_vz);
147
148
149
150
151
152
153NTuplePtr nt1(ntupleSvc(), "DQAFILE/Hadron");
154if ( nt1 ) m_tuple1 = nt1;
155else {
156 m_tuple1 = ntupleSvc()->book ("DQAFILE/Hadron", CLID_ColumnWiseTuple, "N-Tuple");
157 if ( m_tuple1 ) {
158 status = m_tuple1->addItem ("run", m_run);
159 status = m_tuple1->addItem ("rec", m_rec);
160 status = m_tuple1->addItem ("Nchrg", m_ncharg);
161 status = m_tuple1->addItem ("Nneu", m_nneu,0,40);
162 status = m_tuple1->addItem ("NGch", m_ngch, 0, 40);
163 status = m_tuple1->addItem ("NGam", m_nGam);
164
165
166 status = m_tuple1->addItem ("hadrontag", m_hadrontag);
167
168 status = m_tuple1->addItem ("br", m_br);
169 status = m_tuple1->addItem ("bz", m_bz);
170 status = m_tuple1->addItem ("evis", m_evis);
171 status = m_tuple1->addItem ("thr", m_thr);
172
173 status = m_tuple1->addItem ("acoll", m_acoll);
174 status = m_tuple1->addItem ("acopl", m_acopl);
175 status = m_tuple1->addItem ("deltatof", m_deltatof);
176 status = m_tuple1->addItem ("eop1", m_eop1);
177 status = m_tuple1->addItem ("eop2", m_eop2);
178 status = m_tuple1->addItem ("eoeb1", m_eoeb1);
179 status = m_tuple1->addItem ("eoeb2", m_eoeb2);
180 status = m_tuple1->addItem ("poeb1", m_poeb1);
181 status = m_tuple1->addItem ("poeb2", m_poeb2);
182 status = m_tuple1->addItem ("etoeb1", m_etoeb1);
183 status = m_tuple1->addItem ("etoeb2", m_etoeb2);
184 status = m_tuple1->addItem ("mucinfo1", m_mucinfo1);
185 status = m_tuple1->addItem ("mucinfo2", m_mucinfo2);
186
187 status = m_tuple1->addIndexedItem ("delang",m_nneu, m_delang);
188 status = m_tuple1->addIndexedItem ("delphi",m_nneu, m_delphi);
189 status = m_tuple1->addIndexedItem ("delthe",m_nneu, m_delthe);
190 status = m_tuple1->addIndexedItem ("npart",m_nneu, m_npart);
191 status = m_tuple1->addIndexedItem ("nemchits",m_nneu, m_nemchits);
192 status = m_tuple1->addIndexedItem ("module",m_nneu, m_module);
193 status = m_tuple1->addIndexedItem ("x",m_nneu, m_x);
194 status = m_tuple1->addIndexedItem ("y",m_nneu, m_y);
195 status = m_tuple1->addIndexedItem ("z",m_nneu, m_z);
196// status = m_tuple1->addIndexedItem ("px",m_nneu, m_px);
197// status = m_tuple1->addIndexedItem ("py",m_nneu, m_py);
198// status = m_tuple1->addIndexedItem ("pz",m_nneu, m_pz);
199 status = m_tuple1->addIndexedItem ("theta",m_nneu, m_theta);
200 status = m_tuple1->addIndexedItem ("phi",m_nneu, m_phi);
201 status = m_tuple1->addIndexedItem ("dx",m_nneu, m_dx);
202 status = m_tuple1->addIndexedItem ("dy",m_nneu, m_dy);
203 status = m_tuple1->addIndexedItem ("dz",m_nneu, m_dz);
204 status = m_tuple1->addIndexedItem ("dtheta",m_nneu, m_dtheta);
205 status = m_tuple1->addIndexedItem ("dphi",m_nneu, m_dphi);
206 status = m_tuple1->addIndexedItem ("energy",m_nneu, m_energy);
207 status = m_tuple1->addIndexedItem ("dE",m_nneu, m_dE);
208 status = m_tuple1->addIndexedItem ("eSeed",m_nneu, m_eSeed);
209 status = m_tuple1->addIndexedItem ("nSeed",m_nneu, m_nSeed);
210 status = m_tuple1->addIndexedItem ("e3x3",m_nneu, m_e3x3);
211 status = m_tuple1->addIndexedItem ("e5x5",m_nneu, m_e5x5);
212 status = m_tuple1->addIndexedItem ("secondMoment",m_nneu, m_secondMoment);
213 status = m_tuple1->addIndexedItem ("latMoment",m_nneu, m_latMoment);
214 status = m_tuple1->addIndexedItem ("a20Moment",m_nneu, m_a20Moment);
215 status = m_tuple1->addIndexedItem ("a42Moment",m_nneu, m_a42Moment);
216 status = m_tuple1->addIndexedItem ("getTime",m_nneu, m_getTime);
217 status = m_tuple1->addIndexedItem ("getEAll",m_nneu, m_getEAll);
218
219
220
221 status = m_tuple1->addIndexedItem("charge", m_ngch, m_charge);
222 status = m_tuple1->addIndexedItem ("vx", m_ngch, m_vx0);
223 status = m_tuple1->addIndexedItem ("vy", m_ngch, m_vy0);
224 status = m_tuple1->addIndexedItem ("vz", m_ngch, m_vz0);
225
226
227 status = m_tuple1->addIndexedItem ("px", m_ngch, m_px) ;
228 status = m_tuple1->addIndexedItem ("py", m_ngch, m_py) ;
229 status = m_tuple1->addIndexedItem ("pz", m_ngch, m_pz) ;
230 status = m_tuple1->addIndexedItem ("p", m_ngch, m_p) ;
231
232
233
234 status = m_tuple1->addIndexedItem ("kal_vx", m_ngch, m_kal_vx0);
235 status = m_tuple1->addIndexedItem ("kal_vy", m_ngch, m_kal_vy0);
236 status = m_tuple1->addIndexedItem ("kal_vz", m_ngch, m_kal_vz0);
237
238
239 status = m_tuple1->addIndexedItem ("kal_px", m_ngch, m_kal_px) ;
240 status = m_tuple1->addIndexedItem ("kal_py", m_ngch, m_kal_py) ;
241 status = m_tuple1->addIndexedItem ("kal_pz", m_ngch, m_kal_pz) ;
242 status = m_tuple1->addIndexedItem ("kal_p", m_ngch, m_kal_p) ;
243
244
245 status = m_tuple1->addIndexedItem ("probPH" , m_ngch, m_probPH) ;
246 status = m_tuple1->addIndexedItem ("normPH" , m_ngch, m_normPH) ;
247 status = m_tuple1->addIndexedItem ("chie" , m_ngch, m_chie) ;
248 status = m_tuple1->addIndexedItem ("chimu" , m_ngch, m_chimu) ;
249 status = m_tuple1->addIndexedItem ("chipi" , m_ngch, m_chipi) ;
250 status = m_tuple1->addIndexedItem ("chik" , m_ngch, m_chik) ;
251 status = m_tuple1->addIndexedItem ("chip" , m_ngch, m_chip) ;
252 status = m_tuple1->addIndexedItem ("ghit" , m_ngch, m_ghit) ;
253 status = m_tuple1->addIndexedItem ("thit" , m_ngch, m_thit) ;
254
255 status = m_tuple1->addIndexedItem ("e_emc" , m_ngch, m_e_emc) ;
256 status = m_tuple1->addIndexedItem ("phi_emc" , m_ngch, m_phi_emc) ;
257 status = m_tuple1->addIndexedItem ("theta_emc" , m_ngch, m_theta_emc) ;
258
259 status = m_tuple1->addIndexedItem ("nhit_muc" , m_ngch, m_nhit_muc) ;
260 status = m_tuple1->addIndexedItem ("nlay_muc" , m_ngch, m_nlay_muc) ;
261 status = m_tuple1->addIndexedItem ("t_btof" , m_ngch, m_t_btof );
262 status = m_tuple1->addIndexedItem ("t_etof" , m_ngch, m_t_etof );
263 status = m_tuple1->addIndexedItem ("qual_etof" , m_ngch, m_qual_etof );
264 status = m_tuple1->addIndexedItem ("tof_etof" , m_ngch, m_tof_etof );
265 status = m_tuple1->addIndexedItem ("te_etof" , m_ngch, m_te_etof );
266 status = m_tuple1->addIndexedItem ("tmu_etof" , m_ngch, m_tmu_etof );
267 status = m_tuple1->addIndexedItem ("tpi_etof" , m_ngch, m_tpi_etof );
268 status = m_tuple1->addIndexedItem ("tk_etof" , m_ngch, m_tk_etof );
269 status = m_tuple1->addIndexedItem ("tp_etof" , m_ngch, m_tp_etof );
270
271 status = m_tuple1->addIndexedItem ("qual_btof1", m_ngch, m_qual_btof1 );
272 status = m_tuple1->addIndexedItem ("tof_btof1" , m_ngch, m_tof_btof1 );
273 status = m_tuple1->addIndexedItem ("te_btof1" , m_ngch, m_te_btof1 );
274 status = m_tuple1->addIndexedItem ("tmu_btof1" , m_ngch, m_tmu_btof1 );
275 status = m_tuple1->addIndexedItem ("tpi_btof1" , m_ngch, m_tpi_btof1 );
276 status = m_tuple1->addIndexedItem ("tk_btof1" , m_ngch, m_tk_btof1 );
277 status = m_tuple1->addIndexedItem ("tp_btof1" , m_ngch, m_tp_btof1 );
278
279 status = m_tuple1->addIndexedItem ("qual_btof2", m_ngch, m_qual_btof2 );
280 status = m_tuple1->addIndexedItem ("tof_btof2" , m_ngch, m_tof_btof2 );
281 status = m_tuple1->addIndexedItem ("te_btof2" , m_ngch, m_te_btof2 );
282 status = m_tuple1->addIndexedItem ("tmu_btof2" , m_ngch, m_tmu_btof2 );
283 status = m_tuple1->addIndexedItem ("tpi_btof2" , m_ngch, m_tpi_btof2 );
284 status = m_tuple1->addIndexedItem ("tk_btof2" , m_ngch, m_tk_btof2 );
285 status = m_tuple1->addIndexedItem ("tp_btof2" , m_ngch, m_tp_btof2 );
286 status = m_tuple1->addIndexedItem ("pidcode" , m_ngch, m_pidcode);
287 status = m_tuple1->addIndexedItem ("pidprob" , m_ngch, m_pidprob);
288 status = m_tuple1->addIndexedItem ("pidchiDedx" , m_ngch, m_pidchiDedx);
289 status = m_tuple1->addIndexedItem ("pidchiTof1" , m_ngch, m_pidchiTof1);
290 status = m_tuple1->addIndexedItem ("pidchiTof2" , m_ngch, m_pidchiTof2);
291
292 status = m_tuple1->addItem ("px_cms_ep", m_px_cms_ep); //momentum of electron+
293 status = m_tuple1->addItem ("py_cms_ep", m_py_cms_ep); //momentum of electron+
294 status = m_tuple1->addItem ("pz_cms_ep", m_pz_cms_ep); //momentum of electron+
295 status = m_tuple1->addItem ("e_cms_ep", m_e_cms_ep); //momentum of electron+
296 status = m_tuple1->addItem ("cos_ep", m_cos_ep); //momentum of electron+
297 status = m_tuple1->addItem ("px_cms_em", m_px_cms_em); //momentum of electron-
298 status = m_tuple1->addItem ("py_cms_em", m_py_cms_em); //momentum of electron-
299 status = m_tuple1->addItem ("pz_cms_em", m_pz_cms_em); //momentum of electron-
300 status = m_tuple1->addItem ("e_cms_em", m_e_cms_em); //momentum of electron-
301 status = m_tuple1->addItem ("cos_em", m_cos_em); //momentum of electron-
302 status = m_tuple1->addItem ("mass_ee", m_mass_ee); //
303 status = m_tuple1->addItem ("emax", m_emax); //
304 status = m_tuple1->addItem ("esum", m_esum); //
305 status = m_tuple1->addItem ( "npip", m_npip );
306 status = m_tuple1->addItem ( "npim", m_npim );
307 status = m_tuple1->addItem ( "nkp", m_nkp );
308 status = m_tuple1->addItem ( "nkm", m_nkm );
309 status = m_tuple1->addItem ( "np", m_np );
310 status = m_tuple1->addItem ( "npb", m_npb );
311
312 status = m_tuple1->addItem ( "nep", m_nep );
313 status = m_tuple1->addItem ( "nem", m_nem );
314 status = m_tuple1->addItem ( "nmup", m_nmup );
315 status = m_tuple1->addItem ( "nmum", m_nmum );
316
317 }
318 else {
319 log << MSG::ERROR << " Cannot book N-tuple:" << long(m_tuple1) << endmsg;
320 return StatusCode::FAILURE;
321 }
322}
323
324//
325//--------end of book--------
326//
327
328log << MSG::INFO << "successfully return from initialize()" <<endmsg;
329return StatusCode::SUCCESS;
330
331
332
333
334}
INTupleSvc * ntupleSvc()

The documentation for this class was generated from the following files: