BOSS 6.6.4.p01
BESIII Offline Software System
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DQARhopi Class Reference

#include <DQARhopi.h>

+ Inheritance diagram for DQARhopi:

Public Member Functions

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

Detailed Description

Definition at line 10 of file DQARhopi.h.

Constructor & Destructor Documentation

◆ DQARhopi()

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

Definition at line 63 of file DQARhopi.cxx.

63 :
64 Algorithm(name, pSvcLocator) {
65
66 //Declare the properties
67 declareProperty("Vr0cut", m_vr0cut=1.0);
68 declareProperty("Vz0cut", m_vz0cut=5.0);
69 declareProperty("Vctcut", m_cthcut=0.93);
70 declareProperty("EnergyThreshold", m_energyThreshold=0.05);
71 declareProperty("GammaAngCut", m_gammaAngCut=25.0);
72 declareProperty("Test4C", m_test4C = 1);
73 declareProperty("Test5C", m_test5C = 1);
74 declareProperty("CheckDedx", m_checkDedx = 1);
75 declareProperty("CheckTof", m_checkTof = 1);
76}

Member Function Documentation

◆ execute()

StatusCode DQARhopi::execute ( )

Definition at line 304 of file DQARhopi.cxx.

304 {
305
306// std::cout << "execute()" << std::endl;
307
308 MsgStream log(msgSvc(), name());
309 log << MSG::INFO << "in execute()" << endreq;
310
311 setFilterPassed(false);
312
313 SmartDataPtr<Event::EventHeader> eventHeader(eventSvc(),"/Event/EventHeader");
314 int run=eventHeader->runNumber();
315 int event=eventHeader->eventNumber();
316 log << MSG::DEBUG <<"run, evtnum = "
317 << run << " , "
318 << event <<endreq;
319
320 m_run = eventHeader->runNumber();
321 m_rec = eventHeader->eventNumber();
322
323// cout<<"event "<<event<<endl;
324 Ncut0++;
325 SmartDataPtr<EvtRecEvent> evtRecEvent(eventSvc(), EventModel::EvtRec::EvtRecEvent);
326 log << MSG::INFO << "get event tag OK" << endreq;
327 log << MSG::DEBUG <<"ncharg, nneu, tottks = "
328 << evtRecEvent->totalCharged() << " , "
329 << evtRecEvent->totalNeutral() << " , "
330 << evtRecEvent->totalTracks() <<endreq;
331
332 m_nch = evtRecEvent->totalCharged();
333 m_nneu = evtRecEvent->totalNeutral();
334
335 SmartDataPtr<EvtRecTrackCol> evtRecTrkCol(eventSvc(), EventModel::EvtRec::EvtRecTrackCol);
336
337 //
338 // check x0, y0, z0, r0
339 // suggest cut: |z0|<5 && r0<1
340 //
341 Vint iGood, ipip, ipim, ipnp,ipnm;
342 iGood.clear();
343 ipip.clear();
344 ipim.clear();
345 ipnp.clear();
346 ipnm.clear();
347 Vp4 ppip, ppim , ppnp, ppnm;
348 ppip.clear();
349 ppim.clear();
350 ppnp.clear();
351 ppnm.clear();
352
353 Hep3Vector xorigin(0,0,0);
354
355
356 //if (m_reader.isRunNumberValid(runNo)) {
357 IVertexDbSvc* vtxsvc;
358 Gaudi::svcLocator()->service("VertexDbSvc", vtxsvc);
359 if(vtxsvc->isVertexValid()){
360 double* dbv = vtxsvc->PrimaryVertex();
361 double* vv = vtxsvc->SigmaPrimaryVertex();
362 xorigin.setX(dbv[0]);
363 xorigin.setY(dbv[1]);
364 xorigin.setZ(dbv[2]);
365 }
366
367 int nCharge = 0;
368 for(int i = 0; i < evtRecEvent->totalCharged(); i++){
369 EvtRecTrackIterator itTrk=evtRecTrkCol->begin() + i;
370 if(!(*itTrk)->isMdcTrackValid()) continue;
371 if (!(*itTrk)->isMdcKalTrackValid()) continue;
372 RecMdcTrack *mdcTrk = (*itTrk)->mdcTrack();
373 RecMdcKalTrack *mdcKalTrk = (*itTrk)->mdcKalTrack();
374
375 double pch =mdcTrk->p();
376 double x0 =mdcTrk->x();
377 double y0 =mdcTrk->y();
378 double z0 =mdcTrk->z();
379 double phi0=mdcTrk->helix(1);
380 double xv=xorigin.x();
381 double yv=xorigin.y();
382 double Rxy=fabs((x0-xv)*cos(phi0)+(y0-yv)*sin(phi0));
383 double m_vx0 = x0;
384 double m_vy0 = y0;
385 double m_vz0 = z0-xorigin.z();
386 double m_vr0 = Rxy;
387 double m_Vct=cos(mdcTrk->theta());
388// m_tuple1->write();
389 if(fabs(m_vz0) >= m_vz0cut) continue;
390 if(m_vr0 >= m_vr0cut) continue;
391 if(fabs(m_Vct)>=m_cthcut) continue;
392
393 iGood.push_back((*itTrk)->trackId());
394 nCharge += mdcTrk->charge();
395
396 }
397
398 //
399 // Finish Good Charged Track Selection
400 //
401 int nGood = iGood.size();
402 log << MSG::DEBUG << "ngood, totcharge = " << nGood << " , " << nCharge << endreq;
403 if((nGood != 2)||(nCharge!=0)){
404 return StatusCode::SUCCESS;
405 }
406 Ncut1++;
407
408 Vint iGam;
409 iGam.clear();
410 for(int i = evtRecEvent->totalCharged(); i< evtRecEvent->totalTracks(); i++) {
411 EvtRecTrackIterator itTrk=evtRecTrkCol->begin() + i;
412 if(!(*itTrk)->isEmcShowerValid()) continue;
413 RecEmcShower *emcTrk = (*itTrk)->emcShower();
414 Hep3Vector emcpos(emcTrk->x(), emcTrk->y(), emcTrk->z());
415 // find the nearest charged track
416 double dthe = 200.;
417 double dphi = 200.;
418 double dang = 200.;
419 for(int j = 0; j < evtRecEvent->totalCharged(); j++) {
420 EvtRecTrackIterator jtTrk = evtRecTrkCol->begin() + j;
421 if(!(*jtTrk)->isExtTrackValid()) continue;
422 RecExtTrack *extTrk = (*jtTrk)->extTrack();
423 if(extTrk->emcVolumeNumber() == -1) continue;
424 Hep3Vector extpos = extTrk->emcPosition();
425 // double ctht = extpos.cosTheta(emcpos);
426 double angd = extpos.angle(emcpos);
427 double thed = extpos.theta() - emcpos.theta();
428 double phid = extpos.deltaPhi(emcpos);
429 thed = fmod(thed+CLHEP::twopi+CLHEP::twopi+pi, CLHEP::twopi) - CLHEP::pi;
430 phid = fmod(phid+CLHEP::twopi+CLHEP::twopi+pi, CLHEP::twopi) - CLHEP::pi;
431
432 if(fabs(thed) < fabs(dthe)) dthe = thed;
433 if(fabs(phid) < fabs(dphi)) dphi = phid;
434 if(angd < dang) dang = angd;
435 }
436 if(dang>=200) continue;
437 double eraw = emcTrk->energy();
438 dthe = dthe * 180 / (CLHEP::pi);
439 dphi = dphi * 180 / (CLHEP::pi);
440 dang = dang * 180 / (CLHEP::pi);
441 double m_dthe = dthe;
442 double m_dphi = dphi;
443 double m_dang = dang;
444 double m_eraw = eraw;
445// m_tuple2->write();
446 if(eraw < m_energyThreshold) continue;
447 if(dang < m_gammaAngCut) continue;
448 //
449 // good photon cut will be set here
450 //
451 iGam.push_back((*itTrk)->trackId());
452 }
453
454 //
455 // Finish Good Photon Selection
456 //
457 int nGam = iGam.size();
458
459 log << MSG::DEBUG << "num Good Photon " << nGam << " , " <<evtRecEvent->totalNeutral()<<endreq;
460 if(nGam<2){
461 return StatusCode::SUCCESS;
462 }
463 Ncut2++;
464
465
466 //
467 // Assign 4-momentum to each photon
468 //
469
470 Vp4 pGam;
471 pGam.clear();
472 for(int i = 0; i < nGam; i++) {
473 EvtRecTrackIterator itTrk = evtRecTrkCol->begin() + iGam[i];
474 RecEmcShower* emcTrk = (*itTrk)->emcShower();
475 double eraw = emcTrk->energy();
476 double phi = emcTrk->phi();
477 double the = emcTrk->theta();
478 HepLorentzVector ptrk;
479 ptrk.setPx(eraw*sin(the)*cos(phi));
480 ptrk.setPy(eraw*sin(the)*sin(phi));
481 ptrk.setPz(eraw*cos(the));
482 ptrk.setE(eraw);
483
484// ptrk = ptrk.boost(-0.011,0,0);// boost to cms
485
486 pGam.push_back(ptrk);
487 }
488
489 log << MSG::DEBUG << "liuf1 Good Photon " <<endreq;
490
491
492 for(int i = 0; i < nGood; i++) {//for rhopi without PID
493 EvtRecTrackIterator itTrk = evtRecTrkCol->begin() + iGood[i];
494 if(!(*itTrk)->isMdcTrackValid()) continue;
495 if (!(*itTrk)->isMdcKalTrackValid()) continue;
496 RecMdcTrack* mdcTrk = (*itTrk)->mdcTrack();
497 RecMdcKalTrack* mdcKalTrk = (*itTrk)->mdcKalTrack();
499
500 if(mdcTrk->charge() >0) {
501 ipip.push_back(iGood[i]);
502 HepLorentzVector ptrk;
503 ptrk.setPx(mdcKalTrk->px());
504 ptrk.setPy(mdcKalTrk->py());
505 ptrk.setPz(mdcKalTrk->pz());
506 double p3 = ptrk.mag();
507 ptrk.setE(sqrt(p3*p3+mpi*mpi));
508 ppip.push_back(ptrk);
509 } else {
510 ipim.push_back(iGood[i]);
511 HepLorentzVector ptrk;
512 ptrk.setPx(mdcKalTrk->px());
513 ptrk.setPy(mdcKalTrk->py());
514 ptrk.setPz(mdcKalTrk->pz());
515 double p3 = ptrk.mag();
516 ptrk.setE(sqrt(p3*p3+mpi*mpi));
517 ppim.push_back(ptrk);
518 }
519 }// without PID
520
521 int npip = ipip.size();
522 int npim = ipim.size();
523 log << MSG::DEBUG << "num of pion "<< ipip.size()<<","<<ipim.size()<<endreq;
524 Ncut3++;
525
526
527
528 //***********************************************//
529 // the angle between the two charged tracks //
530 //***********************************************//
531
532 int langcc=0;
533 double dthec = 200.;
534 double dphic = 200.;
535 double dangc = 200.;
536 for(int i=0; i < npip; i++) {
537 EvtRecTrackIterator itTrk=evtRecTrkCol->begin() + ipip[i] ;
538 RecMdcTrack* mdcTrk1 = (*itTrk)->mdcTrack();
539 RecMdcKalTrack* mdcKalTrk1 = (*itTrk)->mdcKalTrack();
540 Hep3Vector emcpos(ppip[i].px(), ppip[i].py(), ppip[i].pz());
541
542 for(int j = 0; j < npim; j++) {
543 EvtRecTrackIterator jtTrk = evtRecTrkCol->begin() + ipim[j];
544 RecMdcTrack* mdcTrk2 = (*jtTrk)->mdcTrack();
545 RecMdcKalTrack* mdcKalTrk2 = (*jtTrk)->mdcKalTrack();
546
547 HepLorentzVector pippim=ppip[i]+ppim[j];
548
549 Hep3Vector extpos(ppim[j].px(), ppim[j].py(), ppim[j].pz());
550
551 double angd = extpos.angle(emcpos);
552 double thed = extpos.theta() - emcpos.theta();
553 double phid = extpos.deltaPhi(emcpos);
554 thed = fmod(thed+CLHEP::twopi+CLHEP::twopi+pi, CLHEP::twopi) - CLHEP::pi;
555 phid = fmod(phid+CLHEP::twopi+CLHEP::twopi+pi, CLHEP::twopi) - CLHEP::pi;
556
557 m_dthec[langcc] = thed * 180 / (CLHEP::pi);
558 m_dphic[langcc] = phid * 180 / (CLHEP::pi);
559 m_dangc[langcc] = angd * 180 / (CLHEP::pi);
560 m_mspippim[langcc] =pippim.m();
561 langcc++;
562 }
563 }
564 m_nangecc=langcc;
565
566 //
567 // Loop each gamma pair, check ppi0 and pTot
568 //
569
570 double m_m2gg,m_momentpi0;
571 HepLorentzVector pTot,p2g;
572
573 log << MSG::DEBUG << "liuf2 Good Photon " <<langcc<<endreq;
574 //******************************************************//
575 // asign the momentum of MDC and KALFIT //
576 // the deposite energy of EMC for charged tracks //
577 //******************************************************//
578 double m_momentpip,m_momentpim,extmot1,extmot2;
579 double emcTg1=0.0;
580 double emcTg2=0.0;
581 double nlaypi1=0;
582 double nhit1=0;
583 double nlaypi2=0;
584 double nhit2=0;
585
586 EvtRecTrackIterator itTrk11 = evtRecTrkCol->begin() + ipip[0];
587 RecMdcTrack* mdcTrk11 = (*itTrk11)->mdcTrack();
588 RecMdcKalTrack* mdcKalTrk11 = (*itTrk11)->mdcKalTrack();
589 RecEmcShower* emcTrk11 = (*itTrk11)->emcShower();
590 RecMucTrack *mucTrk11=(*itTrk11)->mucTrack();
591 double phi01=mdcTrk11->helix(1);
592
593 EvtRecTrackIterator itTrk12 = evtRecTrkCol->begin() + ipim[0];
594 RecMdcTrack* mdcTrk12 = (*itTrk12)->mdcTrack();
595 RecMdcKalTrack* mdcKalTrk12 = (*itTrk12)->mdcKalTrack();
596 RecEmcShower* emcTrk12 = (*itTrk12)->emcShower();
597 RecMucTrack *mucTrk12=(*itTrk12)->mucTrack();
598 double phi02=mdcTrk12->helix(1);
599
600 m_vxpin = mdcTrk11->x();
601 m_vypin = mdcTrk11->y();
602 m_vzpin = mdcTrk11->z()-xorigin.z();
603 m_vrpin = fabs((mdcTrk11->x()-xorigin.x())*cos(phi01)+(mdcTrk11->y()-xorigin.y())*sin(phi01));
604 m_costhepin =cos(mdcTrk11->theta());
605
606 m_momentpip=mdcTrk11->p();
607 m_ppx =mdcTrk11->px();
608 m_ppy =mdcTrk11->py();
609 m_ppz =mdcTrk11->pz();
610
611 m_vxp = mdcKalTrk11->x();
612 m_vyp = mdcKalTrk11->y();
613 m_vzp = mdcKalTrk11->z()-xorigin.z();
614 m_vrp = fabs((mdcKalTrk11->x()-xorigin.x())*cos(phi01)+(mdcKalTrk11->y()-xorigin.y())*sin(phi01));
615 m_costhep =cos(mdcKalTrk11->theta());
616
617 extmot1=mdcKalTrk11->p();
618 m_ppxkal =mdcKalTrk11->px();
619 m_ppykal =mdcKalTrk11->py();
620 m_ppzkal =mdcKalTrk11->pz();
621
622 m_vxmin = mdcTrk12->x();
623 m_vymin = mdcTrk12->y();
624 m_vzmin = mdcTrk12->z();
625 m_vrmin = fabs((mdcTrk12->x()-xorigin.x())*cos(phi02)+(mdcTrk12->y()-xorigin.y())*sin(phi02));
626 m_costhemin =cos(mdcTrk12->theta());
627
628 m_momentpim=mdcTrk12->p();
629 m_mpx =mdcTrk12->px();
630 m_mpy =mdcTrk12->py();
631 m_mpz =mdcTrk12->pz();
632
633 m_vxm = mdcKalTrk12->x();
634 m_vym = mdcKalTrk12->y();
635 m_vzm = mdcKalTrk12->z();
636 m_vrm = fabs((mdcKalTrk12->x()-xorigin.x())*cos(phi02)+(mdcKalTrk12->y()-xorigin.y())*sin(phi02));
637 m_costhem =cos(mdcKalTrk12->theta());
638
639 extmot2 =mdcKalTrk12->p();
640 m_mpxkal =mdcKalTrk12->px();
641 m_mpykal =mdcKalTrk12->py();
642 m_mpzkal =mdcKalTrk12->pz();
643
644 if((*itTrk11)->isEmcShowerValid()){
645 emcTg1 = emcTrk11->energy();
646 }
647 if((*itTrk12)->isEmcShowerValid()){
648 emcTg2 = emcTrk12->energy();
649 }
650 if((*itTrk11)->isMucTrackValid()){
651 nlaypi1=mucTrk11->numLayers();
652 nhit1 =mucTrk11->numHits();
653 }
654 if((*itTrk12)->isMucTrackValid()){
655 nlaypi2=mucTrk12->numLayers();
656 nhit2 =mucTrk12->numHits();
657 }
658
659 m_laypi1=nlaypi1;
660 m_hit1 =nhit1;
661 m_laypi2=nlaypi2;
662 m_hit2 =nhit2;
663
664 log << MSG::DEBUG << "liuf3 Good Photon " << ipim[0] <<endreq;
665
666 RecMdcKalTrack *pipTrk = (*(evtRecTrkCol->begin()+ipip[0]))->mdcKalTrack();
667 RecMdcKalTrack *pimTrk = (*(evtRecTrkCol->begin()+ipim[0]))->mdcKalTrack();
668
669 log << MSG::DEBUG << "liuf4 Good Photon " <<endreq;
670
671 WTrackParameter wvpipTrk, wvpimTrk,wvkpTrk, wvkmTrk;
672 wvpipTrk = WTrackParameter(mpi, pipTrk->getZHelix(), pipTrk->getZError());
673 wvpimTrk = WTrackParameter(mpi, pimTrk->getZHelix(), pimTrk->getZError());
674
675 wvkpTrk = WTrackParameter(mk, pipTrk->getZHelixK(), pipTrk->getZErrorK());//kaon
676 wvkmTrk = WTrackParameter(mk, pimTrk->getZHelixK(), pimTrk->getZErrorK());//kaon
677
678/* Default is pion, for other particles:
679 wvppTrk = WTrackParameter(mp, pipTrk->getZHelixP(), pipTrk->getZErrorP());//proton
680 wvmupTrk = WTrackParameter(mmu, pipTrk->getZHelixMu(), pipTrk->getZErrorMu());//muon
681 wvepTrk = WTrackParameter(me, pipTrk->getZHelixE(), pipTrk->getZErrorE());//electron
682 wvkpTrk = WTrackParameter(mk, pipTrk->getZHelixK(), pipTrk->getZErrorK());//kaon
683*/
684 //
685 // Test vertex fit
686 //
687
688 HepPoint3D vx(0., 0., 0.);
689 HepSymMatrix Evx(3, 0);
690 double bx = 1E+6;
691 double by = 1E+6;
692 double bz = 1E+6;
693 Evx[0][0] = bx*bx;
694 Evx[1][1] = by*by;
695 Evx[2][2] = bz*bz;
696
697 VertexParameter vxpar;
698 vxpar.setVx(vx);
699 vxpar.setEvx(Evx);
700
701 //****************************************************//
702 // Test vertex fit //
703 //****************************************************//
704
705 VertexFit* vtxfit = VertexFit::instance();
706
707 //****************************************************//
708 // if the charged particle is kaon //
709 //****************************************************//
710 double chi5=9999.0;
711 double jkpi0=-0.5;
712 double jkpkm=0.0;
713 double jkpp0=0.0;
714 double jkmp0=0.0;
715 vtxfit->init();
716 vtxfit->AddTrack(0, wvkpTrk);
717 vtxfit->AddTrack(1, wvkmTrk);
718 vtxfit->AddVertex(0, vxpar,0, 1);
719 if(vtxfit->Fit(0)) {
720 vtxfit->Swim(0);
721 WTrackParameter wkp = vtxfit->wtrk(0);
722 WTrackParameter wkm = vtxfit->wtrk(1);
723
725
726 //
727 // Apply Kinematic 4C fit
728 //
729
730 double chisq = 9999.;
731 for(int i = 0; i < nGam-1; i++) {
732 RecEmcShower *g1Trk = (*(evtRecTrkCol->begin()+iGam[i]))->emcShower();
733 for(int j = i+1; j < nGam; j++) {
734 RecEmcShower *g2Trk = (*(evtRecTrkCol->begin()+iGam[j]))->emcShower();
735 kmfit->init();
736 kmfit->setDynamicerror(1);
737 kmfit->AddTrack(0, wkp);
738 kmfit->AddTrack(1, wkm);
739 kmfit->AddTrack(2, 0.0, g1Trk);
740 kmfit->AddTrack(3, 0.0, g2Trk);
741 kmfit->AddFourMomentum(0, ecms);
742 bool oksq = kmfit->Fit();
743 if(oksq) {
744 double chi2 = kmfit->chisq();
745 if(chi2 < chi5) {
746 HepLorentzVector kpi0 = kmfit->pfit(2) + kmfit->pfit(3);
747 HepLorentzVector kpkm = kmfit->pfit(0) + kmfit->pfit(1);
748 HepLorentzVector kpp0 = kmfit->pfit(0) + kpi0;
749 HepLorentzVector kmp0 = kmfit->pfit(1) + kpi0;
750 chi5 = kmfit->chisq();
751 jkpi0 = kpi0.m();
752 jkpkm= kpkm.m();
753 jkpp0= kpp0.m();
754 jkmp0= kmp0.m();
755 }
756 }
757 }
758 }
759 } // vetex is true
760
761 //****************************************************//
762 // if the charged particles are pions for real //
763 //****************************************************//
764
765 vtxfit->init();
766 vtxfit->AddTrack(0, wvpipTrk);
767 vtxfit->AddTrack(1, wvpimTrk);
768 vtxfit->AddVertex(0, vxpar,0, 1);
769 if(!vtxfit->Fit(0)) return SUCCESS;
770 vtxfit->Swim(0);
771
772 WTrackParameter wpip = vtxfit->wtrk(0);
773 WTrackParameter wpim = vtxfit->wtrk(1);
774
775 log << MSG::DEBUG << "liuf5 Good Photon " <<endreq;
776
778
779 //
780 // Apply Kinematic 4C fit
781 //
782
783 double chisq = 9999.;
784 int ig1 = -1;
785 int ig2 = -1;
786 HepLorentzVector gg1,gg2;
787 for(int i = 0; i < nGam-1; i++) {
788 RecEmcShower *g1Trk = (*(evtRecTrkCol->begin()+iGam[i]))->emcShower();
789 for(int j = i+1; j < nGam; j++) {
790 RecEmcShower *g2Trk = (*(evtRecTrkCol->begin()+iGam[j]))->emcShower();
791 kmfit->init();
792 kmfit->setDynamicerror(1);
793 kmfit->AddTrack(0, wpip);
794 kmfit->AddTrack(1, wpim);
795 kmfit->AddTrack(2, 0.0, g1Trk);
796 kmfit->AddTrack(3, 0.0, g2Trk);
797 kmfit->AddFourMomentum(0, ecms);
798 bool oksq = kmfit->Fit();
799 if(oksq) {
800 double chi2 = kmfit->chisq();
801 if(chi2 < chisq) {
802 chisq = chi2;
803 ig1 = iGam[i];
804 ig2 = iGam[j];
805 gg1 = pGam[i];
806 gg2 = pGam[j];
807 }
808 }
809 }
810 }
811
812 p2g = gg1 + gg2;
813 m_pmax=gg1.e()>gg2.e()?gg1.e():gg2.e();
814 m_m2gg = p2g.m();
815 m_cosang=(gg1.e()-gg2.e())/p2g.rho();
816 m_momentpi0=sqrt(p2g.px()*p2g.px()+p2g.py()*p2g.py()+p2g.pz()*p2g.pz());
817 log << MSG::DEBUG << " chisq for 4c " << chisq <<endreq;
818 if(chisq > 200) {
819 return StatusCode::SUCCESS;
820 }
821
822// select charge track and nneu track
823 Vint jGood;
824 jGood.clear();
825 jGood.push_back(ipip[0]);
826 jGood.push_back(ipim[0]);
827 m_ngch = jGood.size();
828
829 Vint jGgam;
830 jGgam.clear();
831 jGgam.push_back(ig1);
832 jGgam.push_back(ig2);
833 m_nggneu=jGgam.size();
834
835 HepLorentzVector ppip1=ppip[0];
836 HepLorentzVector ppim1=ppim[0];
837
838 HepLorentzVector Ppipboost = ppip1.boost(u_cms);
839 HepLorentzVector Ppimboost = ppim1.boost(u_cms);
840 Hep3Vector p3pi1 = Ppipboost.vect(); //pi1
841 Hep3Vector p3pi2 = Ppimboost.vect(); //pi2
842 m_anglepm = (p3pi1.angle(p3pi2))* 180 / (CLHEP::pi);
843
844//*******************************************************//
845
846 RecEmcShower *g1Trk = (*(evtRecTrkCol->begin()+ig1))->emcShower();
847 RecEmcShower *g2Trk = (*(evtRecTrkCol->begin()+ig2))->emcShower();
848 kmfit->init();
849 kmfit->setDynamicerror(1);
850 kmfit->AddTrack(0, wpip);
851 kmfit->AddTrack(1, wpim);
852 kmfit->AddTrack(2, 0.0, g1Trk);
853 kmfit->AddTrack(3, 0.0, g2Trk);
854 kmfit->AddFourMomentum(0, ecms);
855 bool oksq = kmfit->Fit();
856 if(!oksq) return SUCCESS;
857
858 HepLorentzVector ppi0 = kmfit->pfit(2) + kmfit->pfit(3);
859 HepLorentzVector prho0 = kmfit->pfit(0) + kmfit->pfit(1);
860 HepLorentzVector prhop = kmfit->pfit(0) + ppi0;
861 HepLorentzVector prhom = kmfit->pfit(1) + ppi0;
862 HepLorentzVector pgam2pi1 = prho0 + kmfit->pfit(2);
863 HepLorentzVector pgam2pi2 = prho0 + kmfit->pfit(3);
864 HepLorentzVector pgam11 =kmfit->pfit(2);
865 HepLorentzVector pgam12 =kmfit->pfit(3);
866
867/*
868 HepLorentzVector ppi0_a=ppi0;
869 HepLorentzVector pgam11_a =pgam11;
870 HepLorentzVector pgam12_a =pgam12;
871
872 Hep3Vector pi0_cms = -ppi0_a.boostVector();
873 HepLorentzVector pgam1 = pgam11_a.boost(pi0_cms);
874 HepLorentzVector pgam2 = pgam12_a.boost(pi0_cms);
875*/
876 m_chi1 = kmfit->chisq();
877 m_mpi0 = ppi0.m();
878 m_prho0= prho0.m();
879 m_prhop= prhop.m();
880 m_prhom= prhom.m();
881 m_good = nGood;
882 m_gam = nGam;
883
884 m_pip = npip;
885 m_pim = npim;
886 m_2gam = m_m2gg;
887 m_outpi0=m_momentpi0;
888 m_outpip=m_momentpip;
889 m_outpim=m_momentpim;
890 m_enpip =emcTg1;
891 m_dcpip =extmot1;
892 m_enpim =emcTg2;
893 m_dcpim =extmot2;
894 m_pipf=kmfit->pfit(0).rho();
895 m_pimf=kmfit->pfit(1).rho();
896 m_pi0f=ppi0.rho();
897
898 m_chi5=chi5;
899 m_kpi0=jkpi0;
900 m_kpkm=jkpkm;
901 m_kpp0=jkpp0;
902 m_kmp0=jkmp0;
903 m_pgam2pi1=pgam2pi1.m();
904 m_pgam2pi2=pgam2pi2.m();
905 cosva1=kmfit->pfit(2).rho();
906 cosva2=kmfit->pfit(3).rho();
907// m_pe1 =pe1;
908// m_pe2 =pe2;
909
910//
911// fill information of dedx and tof
912//
913
914 //
915 // check dedx infomation
916 //
917
918 for(int ii = 0; ii < m_ngch; ii++) {
919// dedx
920 m_ptrk[ii] = 9999.0;
921 m_chie[ii] = 9999.0;
922 m_chimu[ii] = 9999.0;
923 m_chipi[ii] = 9999.0;
924 m_chik[ii] = 9999.0;
925 m_chip[ii] = 9999.0;
926 m_ghit[ii] = 9999.0;
927 m_thit[ii] = 9999.0;
928 m_probPH[ii] = 9999.0;
929 m_normPH[ii] = 9999.0;
930
931//endtof
932 m_cntr_etof[ii] = 9999.0;
933 m_ptot_etof[ii] = 9999.0;
934 m_ph_etof[ii] = 9999.0;
935 m_rhit_etof[ii] = 9999.0;
936 m_qual_etof[ii] = 9999.0;
937 m_te_etof[ii] = 9999.0;
938 m_tmu_etof[ii] = 9999.0;
939 m_tpi_etof[ii] = 9999.0;
940 m_tk_etof[ii] = 9999.0;
941 m_tp_etof[ii] = 9999.0;
942 m_ec_tof[ii] = 9999.0;
943 m_ec_toff_e[ii] = 9999.0;
944 m_ec_toff_mu[ii] = 9999.0;
945 m_ec_toff_pi[ii] = 9999.0;
946 m_ec_toff_k[ii] = 9999.0;
947 m_ec_toff_p[ii] = 9999.0;
948 m_ec_tsig_e[ii] = 9999.0;
949 m_ec_tsig_mu[ii] = 9999.0;
950 m_ec_tsig_pi[ii] = 9999.0;
951 m_ec_tsig_k[ii] = 9999.0;
952 m_ec_tsig_p[ii] = 9999.0;
953
954// barrel tof
955 m_cntr_btof1[ii] = 9999.0;
956 m_ptot_btof1[ii] = 9999.0;
957 m_ph_btof1[ii] = 9999.0;
958 m_zhit_btof1[ii] = 9999.0;
959 m_qual_btof1[ii] = 9999.0;
960 m_te_btof1[ii] = 9999.0;
961 m_tmu_btof1[ii] = 9999.0;
962 m_tpi_btof1[ii] = 9999.0;
963 m_tk_btof1[ii] = 9999.0;
964 m_tp_btof1[ii] = 9999.0;
965 m_b1_tof[ii] = 9999.0;
966 m_b1_toff_e[ii] = 9999.0;
967 m_b1_toff_mu[ii] = 9999.0;
968 m_b1_toff_pi[ii] = 9999.0;
969 m_b1_toff_k[ii] = 9999.0;
970 m_b1_toff_p[ii] = 9999.0;
971 m_b1_tsig_e[ii] = 9999.0;
972 m_b1_tsig_mu[ii] = 9999.0;
973 m_b1_tsig_pi[ii] = 9999.0;
974 m_b1_tsig_k[ii] = 9999.0;
975 m_b1_tsig_p[ii] = 9999.0;
976//pid
977 m_dedx_pid[ii] = 9999.0;
978 m_tof1_pid[ii] = 9999.0;
979 m_tof2_pid[ii] = 9999.0;
980 m_prob_pid[ii] = 9999.0;
981 m_ptrk_pid[ii] = 9999.0;
982 m_cost_pid[ii] = 9999.0;
983 }
984
985
986 int indx0=0;
987 for(int i = 0; i < m_ngch; i++) {
988 EvtRecTrackIterator itTrk = evtRecTrkCol->begin() + jGood[i];
989 if(!(*itTrk)->isMdcTrackValid()) continue;
990 if(!(*itTrk)->isMdcDedxValid())continue;
991 RecMdcTrack* mdcTrk = (*itTrk)->mdcTrack();
992 RecMdcDedx* dedxTrk = (*itTrk)->mdcDedx();
993 m_ptrk[indx0] = mdcTrk->p();
994
995 m_chie[indx0] = dedxTrk->chiE();
996 m_chimu[indx0] = dedxTrk->chiMu();
997 m_chipi[indx0] = dedxTrk->chiPi();
998 m_chik[indx0] = dedxTrk->chiK();
999 m_chip[indx0] = dedxTrk->chiP();
1000 m_ghit[indx0] = dedxTrk->numGoodHits();
1001 m_thit[indx0] = dedxTrk->numTotalHits();
1002 m_probPH[indx0] = dedxTrk->probPH();
1003 m_normPH[indx0] = dedxTrk->normPH();
1004 indx0++;
1005 }
1006
1007
1008 //
1009 // check TOF infomation
1010 //
1011
1012
1013 int indx1=0;
1014 for(int i = 0; i < m_ngch; i++) {
1015 EvtRecTrackIterator itTrk = evtRecTrkCol->begin() + jGood[i];
1016 if(!(*itTrk)->isMdcTrackValid()) continue;
1017 if(!(*itTrk)->isTofTrackValid()) continue;
1018
1019 RecMdcTrack * mdcTrk = (*itTrk)->mdcTrack();
1020 SmartRefVector<RecTofTrack> tofTrkCol = (*itTrk)->tofTrack();
1021
1022 double ptrk = mdcTrk->p();
1023 SmartRefVector<RecTofTrack>::iterator iter_tof = tofTrkCol.begin();
1024 for(;iter_tof != tofTrkCol.end(); iter_tof++ ) {
1025 TofHitStatus *status = new TofHitStatus;
1026 status->setStatus((*iter_tof)->status());
1027 if(!(status->is_barrel())){//endcap
1028 if( !(status->is_counter()) ) continue; // ?
1029 if( status->layer()!=1 ) continue;//layer1
1030 double path=(*iter_tof)->path(); // ?
1031 double tof = (*iter_tof)->tof();
1032 double ph = (*iter_tof)->ph();
1033 double rhit = (*iter_tof)->zrhit();
1034 double qual = 0.0 + (*iter_tof)->quality();
1035 double cntr = 0.0 + (*iter_tof)->tofID();
1036 double texp[5];
1037 double tsig[5];
1038 for(int j = 0; j < 5; j++) {//0 e, 1 mu, 2 pi, 3 K, 4 p
1039 texp[j] = (*iter_tof)->texp(j);
1040// tsig[j] = (*iter_tof)->sigma(j);
1041// toffset[j] = (*iter_tof)->offset(j);
1042 }
1043 m_cntr_etof[indx1] = cntr;
1044 m_ptot_etof[indx1] = ptrk;
1045 m_ph_etof[indx1] = ph;
1046 m_rhit_etof[indx1] = rhit;
1047 m_qual_etof[indx1] = qual;
1048 m_te_etof[indx1] = tof - texp[0];
1049 m_tmu_etof[indx1] = tof - texp[1];
1050 m_tpi_etof[indx1] = tof - texp[2];
1051 m_tk_etof[indx1] = tof - texp[3];
1052 m_tp_etof[indx1] = tof - texp[4];
1053
1054 m_ec_tof[indx1] = tof;
1055
1056 m_ec_toff_e[indx1] = (*iter_tof)->toffset(0);
1057 m_ec_toff_mu[indx1] = (*iter_tof)->toffset(1);
1058 m_ec_toff_pi[indx1] = (*iter_tof)->toffset(2);
1059 m_ec_toff_k[indx1] = (*iter_tof)->toffset(3);
1060 m_ec_toff_p[indx1] = (*iter_tof)->toffset(4);
1061
1062 m_ec_tsig_e[indx1] = (*iter_tof)->sigma(0);
1063 m_ec_tsig_mu[indx1] = (*iter_tof)->sigma(1);
1064 m_ec_tsig_pi[indx1] = (*iter_tof)->sigma(2);
1065 m_ec_tsig_k[indx1] = (*iter_tof)->sigma(3);
1066 m_ec_tsig_p[indx1] = (*iter_tof)->sigma(4);
1067
1068 }
1069 else {//barrel
1070 if( !(status->is_cluster()) ) continue; // ?
1071 double path=(*iter_tof)->path(); // ?
1072 double tof = (*iter_tof)->tof();
1073 double ph = (*iter_tof)->ph();
1074 double rhit = (*iter_tof)->zrhit();
1075 double qual = 0.0 + (*iter_tof)->quality();
1076 double cntr = 0.0 + (*iter_tof)->tofID();
1077 double texp[5];
1078 for(int j = 0; j < 5; j++) {
1079 texp[j] = (*iter_tof)->texp(j);
1080 }
1081 m_cntr_btof1[indx1] = cntr;
1082 m_ptot_btof1[indx1] = ptrk;
1083 m_ph_btof1[indx1] = ph;
1084 m_zhit_btof1[indx1] = rhit;
1085 m_qual_btof1[indx1] = qual;
1086 m_te_btof1[indx1] = tof - texp[0];
1087 m_tmu_btof1[indx1] = tof - texp[1];
1088 m_tpi_btof1[indx1] = tof - texp[2];
1089 m_tk_btof1[indx1] = tof - texp[3];
1090 m_tp_btof1[indx1] = tof - texp[4];
1091
1092 m_b1_tof[indx1] = tof;
1093
1094 m_b1_toff_e[indx1] = (*iter_tof)->toffset(0);
1095 m_b1_toff_mu[indx1] = (*iter_tof)->toffset(1);
1096 m_b1_toff_pi[indx1] = (*iter_tof)->toffset(2);
1097 m_b1_toff_k[indx1] = (*iter_tof)->toffset(3);
1098 m_b1_toff_p[indx1] = (*iter_tof)->toffset(4);
1099
1100 m_b1_tsig_e[indx1] = (*iter_tof)->sigma(0);
1101 m_b1_tsig_mu[indx1] = (*iter_tof)->sigma(1);
1102 m_b1_tsig_pi[indx1] = (*iter_tof)->sigma(2);
1103 m_b1_tsig_k[indx1] = (*iter_tof)->sigma(3);
1104 m_b1_tsig_p[indx1] = (*iter_tof)->sigma(4);
1105
1106 }
1107 delete status;
1108 }
1109 indx1++;
1110 } // loop all charged track
1111
1112 //
1113 // Assign 4-momentum to each charged track
1114 //
1115 int indx2=0;
1117 for(int i = 0; i < m_ngch; i++) {
1118 EvtRecTrackIterator itTrk = evtRecTrkCol->begin() + jGood[i];
1119 // if(pid) delete pid;
1120 pid->init();
1121 pid->setMethod(pid->methodProbability());
1122// pid->setMethod(pid->methodLikelihood()); //for Likelihood Method
1123
1124 pid->setChiMinCut(4);
1125 pid->setRecTrack(*itTrk);
1126 pid->usePidSys(pid->useDedx() | pid->useTof1() | pid->useTof2()); // use PID sub-system
1127 pid->identify(pid->onlyPion() | pid->onlyKaon()); // seperater Pion/Kaon
1128 // pid->identify(pid->onlyPion());
1129 // pid->identify(pid->onlyKaon());
1130 pid->calculate();
1131 if(!(pid->IsPidInfoValid())) continue;
1132 RecMdcTrack* mdcTrk = (*itTrk)->mdcTrack();
1133
1134 m_dedx_pid[indx2] = pid->chiDedx(2);
1135 m_tof1_pid[indx2] = pid->chiTof1(2);
1136 m_tof2_pid[indx2] = pid->chiTof2(2);
1137 m_prob_pid[indx2] = pid->probPion();
1138
1139// if(pid->probPion() < 0.001 || (pid->probPion() < pid->probKaon())) continue;
1140// if(pid->probPion() < 0.001) continue;
1141// if(pid->pdf(2)<pid->pdf(3)) continue; // for Likelihood Method(0=electron 1=muon 2=pion 3=kaon 4=proton)
1142
1143 RecMdcKalTrack* mdcKalTrk = (*itTrk)->mdcKalTrack();//After ParticleID, use RecMdcKalTrack substitute RecMdcTrack
1144 RecMdcKalTrack::setPidType (RecMdcKalTrack::pion);//PID can set to electron, muon, pion, kaon and proton;The default setting is pion
1145
1146 m_ptrk_pid[indx2] = mdcKalTrk->p();
1147 m_cost_pid[indx2] = cos(mdcTrk->theta());
1148
1149 if(mdcTrk->charge() >0 && pid->probPion() > pid->probKaon()) {
1150 ipnp.push_back(jGood[i]);
1151 HepLorentzVector ptrk;
1152 ptrk.setPx(mdcKalTrk->px());
1153 ptrk.setPy(mdcKalTrk->py());
1154 ptrk.setPz(mdcKalTrk->pz());
1155 double p3 = ptrk.mag();
1156 ptrk.setE(sqrt(p3*p3+mpi*mpi));
1157// ptrk = ptrk.boost(-0.011,0,0);//boost to cms
1158
1159 ppnp.push_back(ptrk);
1160 } //plus charge with with PID
1161 if(mdcTrk->charge() <0 && pid->probPion() > pid->probKaon()) {
1162 ipnm.push_back(jGood[i]);
1163 HepLorentzVector ptrk;
1164 ptrk.setPx(mdcKalTrk->px());
1165 ptrk.setPy(mdcKalTrk->py());
1166 ptrk.setPz(mdcKalTrk->pz());
1167 double p3 = ptrk.mag();
1168 ptrk.setE(sqrt(p3*p3+mpi*mpi));
1169
1170// ptrk = ptrk.boost(-0.011,0,0);//boost to cms
1171
1172 ppnm.push_back(ptrk);
1173 } //minus charge with with PID
1174 }
1175 int npnp = ipnp.size();
1176 int npnm = ipnm.size();
1177
1178 m_pnp = npnp;
1179 m_pnm = npnm;
1180
1181 int iphoton = 0;
1182 for (int i=0; i<m_nggneu; i++)
1183 {
1184 EvtRecTrackIterator itTrk=evtRecTrkCol->begin() + jGgam[i];
1185 if (!(*itTrk)->isEmcShowerValid()) continue;
1186 RecEmcShower *emcTrk = (*itTrk)->emcShower();
1187 m_numHits[iphoton] = emcTrk->numHits();
1188 m_secondmoment[iphoton] = emcTrk->secondMoment();
1189 m_x[iphoton] = emcTrk->x();
1190 m_y[iphoton]= emcTrk->y();
1191 m_z[iphoton]= emcTrk->z();
1192 m_cosemc[iphoton] = cos(emcTrk->theta());
1193 m_phiemc[iphoton] = emcTrk->phi();
1194 m_energy[iphoton] = emcTrk->energy();
1195 m_eSeed[iphoton] = emcTrk->eSeed();
1196 m_e3x3[iphoton] = emcTrk->e3x3();
1197 m_e5x5[iphoton] = emcTrk->e5x5();
1198 m_lat[iphoton] = emcTrk->latMoment();
1199 m_a20[iphoton] = emcTrk->a20Moment();
1200 m_a42[iphoton] = emcTrk->a42Moment();
1201 iphoton++;
1202 }
1203 m_tuple4->write();
1204 Ncut4++;
1205
1206 if(kmfit->chisq()>=chi5) return SUCCESS;
1207 if(pgam2pi2.m()<=1.0) return SUCCESS;
1208 if(pgam2pi1.m()<=1.0) return SUCCESS;
1209 if(nGam!=2) return SUCCESS;
1210 if(emcTg1/extmot1>=0.8) return SUCCESS;
1211 if(emcTg2/extmot2>=0.8) return SUCCESS;
1212 Ncut5++;
1213
1214 // DQA
1215 TH1 *h(0);
1216 if (m_thsvc->getHist("/DQAHist/Rhopi/mpi0", h).isSuccess()) {
1217 h->Fill(ppi0.m());
1218 } else {
1219 log << MSG::ERROR << "Couldn't retrieve mpi0" << endreq;
1220 }
1221
1222 if(fabs(ppi0.m()-0.135)>=0.015) return SUCCESS;
1223 Ncut6++;
1224
1225 if (m_thsvc->getHist("/DQAHist/Rhopi/mrho0", h).isSuccess()) {
1226 h->Fill(prho0.m());
1227 } else {
1228 log << MSG::ERROR << "Couldn't retrieve mrho0" << endreq;
1229 }
1230
1231
1232 if (m_thsvc->getHist("/DQAHist/Rhopi/mrhop", h).isSuccess()) {
1233 h->Fill(prhop.m());
1234 } else {
1235 log << MSG::ERROR << "Couldn't retrieve mrhop" << endreq;
1236 }
1237
1238 if (m_thsvc->getHist("/DQAHist/Rhopi/mrhom", h).isSuccess()) {
1239 h->Fill(prhom.m());
1240 } else {
1241 log << MSG::ERROR << "Couldn't retrieve mrhom" << endreq;
1242 }
1243
1244
1245 // Pid: 1 - electron, 2 - muon, 3 - pion, 4 - kaon, 5 - proton
1246
1247 (*(evtRecTrkCol->begin()+ipip[0]))->setPartId(3);
1248 (*(evtRecTrkCol->begin()+ipim[0]))->setPartId(3);
1249
1250 // Quality: defined by whether dE/dx or TOF is used to identify particle
1251 // 0 - no dE/dx, no TOF (can be used for dE/dx and TOF calibration)
1252 // 1 - only dE/dx (can be used for TOF calibration)
1253 // 2 - only TOF (can be used for dE/dx calibration)
1254 // 3 - Both dE/dx and TOF
1255
1256 (*(evtRecTrkCol->begin()+ipip[0]))->setQuality(0);
1257 (*(evtRecTrkCol->begin()+ipim[0]))->setQuality(0);
1258
1259 setFilterPassed(true);
1260
1261 return StatusCode::SUCCESS;
1262}
double sin(const BesAngle a)
Definition: BesAngle.h:210
double cos(const BesAngle a)
Definition: BesAngle.h:213
const Hep3Vector u_cms
Definition: DQADtagAlg.cxx:62
EvtRecTrackCol::iterator EvtRecTrackIterator
Definition: EvtRecTrack.h:111
std::vector< HepLorentzVector > Vp4
Definition: Gam4pikp.cxx:53
const double mk
Definition: Gam4pikp.cxx:48
const double mpi
Definition: Gam4pikp.cxx:47
std::vector< int > Vint
Definition: Gam4pikp.cxx:52
int Ncut2
Definition: Ppjrhopi.cxx:53
int Ncut1
Definition: Ppjrhopi.cxx:53
int Ncut0
Definition: Ppjrhopi.cxx:53
int Ncut5
Definition: Ppjrhopi.cxx:53
int Ncut3
Definition: Ppjrhopi.cxx:53
int Ncut6
Definition: Ppjrhopi.cxx:53
int Ncut4
Definition: Ppjrhopi.cxx:53
IMessageSvc * msgSvc()
double latMoment() const
Definition: DstEmcShower.h:52
double a42Moment() const
Definition: DstEmcShower.h:54
double eSeed() const
Definition: DstEmcShower.h:47
double theta() const
Definition: DstEmcShower.h:38
double e3x3() const
Definition: DstEmcShower.h:48
double phi() const
Definition: DstEmcShower.h:39
double secondMoment() const
Definition: DstEmcShower.h:51
double x() const
Definition: DstEmcShower.h:35
double e5x5() const
Definition: DstEmcShower.h:49
double z() const
Definition: DstEmcShower.h:37
int numHits() const
Definition: DstEmcShower.h:30
double a20Moment() const
Definition: DstEmcShower.h:53
double energy() const
Definition: DstEmcShower.h:45
double y() const
Definition: DstEmcShower.h:36
const Hep3Vector emcPosition() const
Definition: DstExtTrack.h:126
const int emcVolumeNumber() const
Definition: DstExtTrack.h:132
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 double theta() const
const double px() const
const double z() const
static void setPidType(PidType pidType)
const double pz() const
const double py() const
const double p() const
const double x() const
const double theta() const
Definition: DstMdcTrack.h:59
const double py() const
Definition: DstMdcTrack.h:56
const int charge() const
Definition: DstMdcTrack.h:53
const double px() const
Definition: DstMdcTrack.h:55
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
virtual bool isVertexValid()=0
virtual double * SigmaPrimaryVertex()=0
virtual double * PrimaryVertex()=0
static KinematicFit * instance()
void setDynamicerror(const bool dynamicerror=1)
Definition: KinematicFit.h:139
double chisq() const
Definition: KinematicFit.h:150
void AddFourMomentum(int number, HepLorentzVector p4)
HepLorentzVector pfit(int n) const
Definition: KinematicFit.h:154
int useTof2() const
int methodProbability() const
int useDedx() const
int onlyKaon() 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 chiTof2(int n) const
void identify(const int pidcase)
Definition: ParticleID.h:103
void usePidSys(const int pidsys)
Definition: ParticleID.h:97
static ParticleID * instance()
Definition: ParticleID.cxx:22
bool IsPidInfoValid() const
double probPion() const
Definition: ParticleID.h:123
double chiTof1(int n) const
void calculate()
Definition: ParticleID.cxx:94
void init()
Definition: ParticleID.cxx:27
double chiDedx(int n) const
const HepVector & getZHelix() const
HepVector & getZHelixK()
const HepSymMatrix & getZError() const
HepSymMatrix & getZErrorK()
bool is_barrel() const
Definition: TofHitStatus.h:26
unsigned int layer() const
Definition: TofHitStatus.h:28
bool is_cluster() const
Definition: TofHitStatus.h:25
void setStatus(unsigned int status)
bool is_counter() const
Definition: TofHitStatus.h:24
void AddTrack(const int number, const double mass, const RecMdcTrack *trk)
Definition: TrackPool.cxx:22
WTrackParameter wtrk(int n) const
Definition: VertexFit.h:84
void init()
Definition: VertexFit.cxx:29
void AddVertex(int number, VertexParameter vpar, std::vector< int > lis)
Definition: VertexFit.cxx:87
static VertexFit * instance()
Definition: VertexFit.cxx:15
void Swim(int n)
Definition: VertexFit.h:64
bool Fit()
Definition: VertexFit.cxx:299
void setEvx(const HepSymMatrix &eVx)
void setVx(const HepPoint3D &vx)
const double ecms
Definition: inclkstar.cxx:42
_EXTERN_ std::string EvtRecEvent
Definition: EventModel.h:111
_EXTERN_ std::string EvtRecTrackCol
Definition: EventModel.h:112
const float pi
Definition: vector3.h:133

◆ finalize()

StatusCode DQARhopi::finalize ( )

Definition at line 1266 of file DQARhopi.cxx.

1266 {
1267 cout<<"total number: "<<Ncut0<<endl;
1268 cout<<"nGood==2, nCharge==0: "<<Ncut1<<endl;
1269 cout<<"nGam>=2: "<<Ncut2<<endl;
1270 cout<<"Pass Pid: "<<Ncut3<<endl;
1271 cout<<"Pass 4C: "<<Ncut4<<endl;
1272 cout<<"final cut without pi0:"<<Ncut5<<endl;
1273 cout<<"final cut with pi0: "<<Ncut6<<endl;
1274 MsgStream log(msgSvc(), name());
1275 log << MSG::INFO << "in finalize()" << endmsg;
1276 return StatusCode::SUCCESS;
1277}

◆ initialize()

StatusCode DQARhopi::initialize ( )

Definition at line 79 of file DQARhopi.cxx.

79 {
80 MsgStream log(msgSvc(), name());
81
82 log << MSG::INFO << "in initialize()" << endmsg;
83
84 StatusCode status;
85
86 NTuplePtr nt4(ntupleSvc(), "DQAFILE/Rhopi");
87 if ( nt4 ) m_tuple4 = nt4;
88 else {
89 m_tuple4 = ntupleSvc()->book ("DQAFILE/Rhopi", CLID_ColumnWiseTuple, "ks N-Tuple example");
90 if ( m_tuple4 ) {
91 status = m_tuple4->addItem ("run", m_run);
92 status = m_tuple4->addItem ("rec", m_rec);
93 status = m_tuple4->addItem ("nch", m_nch);
94 status = m_tuple4->addItem ("nneu", m_nneu);
95 status = m_tuple4->addItem ("chi1", m_chi1);
96 status = m_tuple4->addItem ("mpi0", m_mpi0);
97 status = m_tuple4->addItem ("mprho0", m_prho0);
98 status = m_tuple4->addItem ("mprhop", m_prhop);
99 status = m_tuple4->addItem ("mprhom", m_prhom);
100 status = m_tuple4->addItem ("mgood", m_good);
101 status = m_tuple4->addItem ("mgam", m_gam);
102 status = m_tuple4->addItem ("mpip", m_pip);
103 status = m_tuple4->addItem ("mpim", m_pim);
104 status = m_tuple4->addItem ("m2gam", m_2gam);
105 status = m_tuple4->addItem ("ngch", m_ngch, 0, 10);
106 status = m_tuple4->addItem ("nggneu", m_nggneu,0, 10);
107 status = m_tuple4->addItem ("moutpi0",m_outpi0);
108 status = m_tuple4->addItem ("cosang", m_cosang);
109 status = m_tuple4->addItem ("moutpip",m_outpip);
110 status = m_tuple4->addItem ("moutpim",m_outpim);
111 status = m_tuple4->addItem ("menpip", m_enpip);
112 status = m_tuple4->addItem ("mdcpip", m_dcpip );
113 status = m_tuple4->addItem ("menpim", m_enpim );
114 status = m_tuple4->addItem ("mdcpim", m_dcpim );
115 status = m_tuple4->addItem ("mpipf", m_pipf);
116 status = m_tuple4->addItem ("mpimf", m_pimf);
117 status = m_tuple4->addItem ("mpi0f", m_pi0f);
118
119 status = m_tuple4->addItem ("mpmax", m_pmax);
120 status = m_tuple4->addItem ("mppx", m_ppx);
121 status = m_tuple4->addItem ("mppy", m_ppy);
122 status = m_tuple4->addItem ("mppz", m_ppz);
123 status = m_tuple4->addItem ("mcosthep",m_costhep);
124 status = m_tuple4->addItem ("mppxkal", m_ppxkal);
125 status = m_tuple4->addItem ("mppykal", m_ppykal);
126 status = m_tuple4->addItem ("mppzkal", m_ppzkal);
127 status = m_tuple4->addItem ("mmpx", m_mpx);
128 status = m_tuple4->addItem ("mmpy", m_mpy);
129 status = m_tuple4->addItem ("mmpz", m_mpz);
130 status = m_tuple4->addItem ("mcosthem",m_costhem);
131 status = m_tuple4->addItem ("mmpxkal", m_mpxkal);
132 status = m_tuple4->addItem ("mmpykal", m_mpykal);
133 status = m_tuple4->addItem ("mmpzkal", m_mpzkal);
134
135 status = m_tuple4->addItem ("mvxpin", m_vxpin);
136 status = m_tuple4->addItem ("mvypin", m_vypin);
137 status = m_tuple4->addItem ("mvzpin", m_vzpin);
138 status = m_tuple4->addItem ("mvrpin", m_vrpin);
139 status = m_tuple4->addItem ("mcosthepin",m_costhepin);
140 status = m_tuple4->addItem ("mvxmin", m_vxmin);
141 status = m_tuple4->addItem ("mvymin", m_vymin);
142 status = m_tuple4->addItem ("mvzmin", m_vzmin);
143 status = m_tuple4->addItem ("mvrmin", m_vrmin);
144 status = m_tuple4->addItem ("mcosthemin",m_costhemin);
145 status = m_tuple4->addItem ("mvxp", m_vxp);
146 status = m_tuple4->addItem ("mvyp", m_vyp);
147 status = m_tuple4->addItem ("mvzp", m_vzp);
148 status = m_tuple4->addItem ("mvrp", m_vrp);
149 status = m_tuple4->addItem ("mvxm", m_vxm);
150 status = m_tuple4->addItem ("mvym", m_vym);
151 status = m_tuple4->addItem ("mvzm", m_vzm);
152 status = m_tuple4->addItem ("mvrm", m_vrm);
153 status = m_tuple4->addItem ("nangecc",m_nangecc,0,10);
154 status = m_tuple4->addIndexedItem ("mdthec", m_nangecc, m_dthec);
155 status = m_tuple4->addIndexedItem ("mdphic", m_nangecc, m_dphic);
156 status = m_tuple4->addIndexedItem ("mdangc", m_nangecc, m_dangc);
157 status = m_tuple4->addIndexedItem ("mspippim", m_nangecc, m_mspippim);
158
159 status = m_tuple4->addItem ("angsg", dangsg);
160 status = m_tuple4->addItem ("thesg", dthesg);
161 status = m_tuple4->addItem ("phisg", dphisg);
162 status = m_tuple4->addItem ("cosgth1", cosgth1);
163 status = m_tuple4->addItem ("cosgth2", cosgth2);
164
165 status = m_tuple4->addItem ("mchi5", m_chi5);
166 status = m_tuple4->addItem ("mkpi0", m_kpi0);
167 status = m_tuple4->addItem ("mkpkm", m_kpkm);
168 status = m_tuple4->addItem ("mkpp0", m_kpp0);
169 status = m_tuple4->addItem ("mkmp0", m_kmp0);
170 status = m_tuple4->addItem ("mpgam2pi1",m_pgam2pi1);
171 status = m_tuple4->addItem ("mpgam2pi2",m_pgam2pi2);
172 status = m_tuple4->addItem ("cosva1", cosva1);
173 status = m_tuple4->addItem ("cosva2", cosva2);
174 status = m_tuple4->addItem ("laypi1", m_laypi1);
175 status = m_tuple4->addItem ("hit1", m_hit1);
176 status = m_tuple4->addItem ("laypi2", m_laypi2);
177 status = m_tuple4->addItem ("hit2", m_hit2);
178 status = m_tuple4->addItem ("anglepm", m_anglepm);
179
180 status = m_tuple4->addIndexedItem ("mptrk", m_ngch, m_ptrk);
181 status = m_tuple4->addIndexedItem ("chie", m_ngch, m_chie);
182 status = m_tuple4->addIndexedItem ("chimu", m_ngch,m_chimu);
183 status = m_tuple4->addIndexedItem ("chipi", m_ngch,m_chipi);
184 status = m_tuple4->addIndexedItem ("chik", m_ngch,m_chik);
185 status = m_tuple4->addIndexedItem ("chip", m_ngch,m_chip);
186 status = m_tuple4->addIndexedItem ("probPH", m_ngch,m_probPH);
187 status = m_tuple4->addIndexedItem ("normPH", m_ngch,m_normPH);
188 status = m_tuple4->addIndexedItem ("ghit", m_ngch,m_ghit);
189 status = m_tuple4->addIndexedItem ("thit", m_ngch,m_thit);
190
191 status = m_tuple4->addIndexedItem ("ptot_etof", m_ngch,m_ptot_etof);
192 status = m_tuple4->addIndexedItem ("cntr_etof", m_ngch,m_cntr_etof);
193 status = m_tuple4->addIndexedItem ("te_etof", m_ngch,m_te_etof);
194 status = m_tuple4->addIndexedItem ("tmu_etof", m_ngch,m_tmu_etof);
195 status = m_tuple4->addIndexedItem ("tpi_etof", m_ngch,m_tpi_etof);
196 status = m_tuple4->addIndexedItem ("tk_etof", m_ngch,m_tk_etof);
197 status = m_tuple4->addIndexedItem ("tp_etof", m_ngch,m_tp_etof);
198 status = m_tuple4->addIndexedItem ("ph_etof", m_ngch,m_ph_etof);
199 status = m_tuple4->addIndexedItem ("rhit_etof", m_ngch,m_rhit_etof);
200 status = m_tuple4->addIndexedItem ("qual_etof", m_ngch,m_qual_etof);
201 status = m_tuple4->addIndexedItem ("ec_toff_e", m_ngch,m_ec_toff_e);
202 status = m_tuple4->addIndexedItem ("ec_toff_mu",m_ngch,m_ec_toff_mu);
203 status = m_tuple4->addIndexedItem ("ec_toff_pi",m_ngch,m_ec_toff_pi);
204 status = m_tuple4->addIndexedItem ("ec_toff_k", m_ngch,m_ec_toff_k);
205 status = m_tuple4->addIndexedItem ("ec_toff_p", m_ngch,m_ec_toff_p);
206 status = m_tuple4->addIndexedItem ("ec_tsig_e", m_ngch,m_ec_tsig_e);
207 status = m_tuple4->addIndexedItem ("ec_tsig_mu",m_ngch,m_ec_tsig_mu);
208 status = m_tuple4->addIndexedItem ("ec_tsig_pi",m_ngch,m_ec_tsig_pi);
209 status = m_tuple4->addIndexedItem ("ec_tsig_k", m_ngch,m_ec_tsig_k);
210 status = m_tuple4->addIndexedItem ("ec_tsig_p", m_ngch,m_ec_tsig_p);
211 status = m_tuple4->addIndexedItem ("ec_tof", m_ngch,m_ec_tof);
212 status = m_tuple4->addIndexedItem ("ptot_btof1",m_ngch,m_ptot_btof1);
213 status = m_tuple4->addIndexedItem ("cntr_btof1",m_ngch,m_cntr_btof1);
214 status = m_tuple4->addIndexedItem ("te_btof1", m_ngch,m_te_btof1);
215 status = m_tuple4->addIndexedItem ("tmu_btof1", m_ngch,m_tmu_btof1);
216 status = m_tuple4->addIndexedItem ("tpi_btof1", m_ngch,m_tpi_btof1);
217 status = m_tuple4->addIndexedItem ("tk_btof1", m_ngch,m_tk_btof1);
218 status = m_tuple4->addIndexedItem ("tp_btof1", m_ngch,m_tp_btof1);
219 status = m_tuple4->addIndexedItem ("ph_btof1", m_ngch,m_ph_btof1);
220 status = m_tuple4->addIndexedItem ("zhit_btof1",m_ngch,m_zhit_btof1);
221 status = m_tuple4->addIndexedItem ("qual_btof1",m_ngch,m_qual_btof1);
222 status = m_tuple4->addIndexedItem ("b1_toff_e", m_ngch,m_b1_toff_e);
223 status = m_tuple4->addIndexedItem ("b1_toff_mu",m_ngch,m_b1_toff_mu);
224 status = m_tuple4->addIndexedItem ("b1_toff_pi",m_ngch,m_b1_toff_pi);
225 status = m_tuple4->addIndexedItem ("b1_toff_k", m_ngch,m_b1_toff_k);
226 status = m_tuple4->addIndexedItem ("b1_toff_p", m_ngch,m_b1_toff_p);
227 status = m_tuple4->addIndexedItem ("b1_tsig_e", m_ngch,m_b1_tsig_e);
228 status = m_tuple4->addIndexedItem ("b1_tsig_mu",m_ngch,m_b1_tsig_mu);
229 status = m_tuple4->addIndexedItem ("b1_tsig_pi",m_ngch,m_b1_tsig_pi);
230 status = m_tuple4->addIndexedItem ("b1_tsig_k", m_ngch,m_b1_tsig_k);
231 status = m_tuple4->addIndexedItem ("b1_tsig_p", m_ngch,m_b1_tsig_p);
232 status = m_tuple4->addIndexedItem ("b1_tof", m_ngch,m_b1_tof);
233
234 status = m_tuple4->addIndexedItem ("mdedx_pid", m_ngch,m_dedx_pid);
235 status = m_tuple4->addIndexedItem ("mtof1_pid", m_ngch,m_tof1_pid);
236 status = m_tuple4->addIndexedItem ("mtof2_pid", m_ngch,m_tof2_pid);
237 status = m_tuple4->addIndexedItem ("mprob_pid", m_ngch,m_prob_pid);
238 status = m_tuple4->addIndexedItem ("mptrk_pid", m_ngch,m_ptrk_pid);
239 status = m_tuple4->addIndexedItem ("mcost_pid", m_ngch,m_cost_pid);
240 status = m_tuple4->addItem ("mpnp", m_pnp);
241 status = m_tuple4->addItem ("mpnm", m_pnm);
242
243 status = m_tuple4->addIndexedItem ("numHits", m_nggneu,m_numHits); // Total number of hits
244 status = m_tuple4->addIndexedItem ("secondmoment", m_nggneu,m_secondmoment);
245 status = m_tuple4->addIndexedItem ("mx", m_nggneu,m_x); // Shower coordinates and errors
246 status = m_tuple4->addIndexedItem ("my", m_nggneu,m_y);
247 status = m_tuple4->addIndexedItem ("mz", m_nggneu,m_z);
248 status = m_tuple4->addIndexedItem ("cosemc", m_nggneu,m_cosemc); // Shower Counter angles and errors
249 status = m_tuple4->addIndexedItem ("phiemc", m_nggneu,m_phiemc);
250 status = m_tuple4->addIndexedItem ("energy", m_nggneu,m_energy); // Total energy observed in Emc
251 status = m_tuple4->addIndexedItem ("eseed", m_nggneu,m_eSeed);
252 status = m_tuple4->addIndexedItem ("me9", m_nggneu,m_e3x3);
253 status = m_tuple4->addIndexedItem ("me25", m_nggneu,m_e5x5);
254 status = m_tuple4->addIndexedItem ("mlat", m_nggneu,m_lat);
255 status = m_tuple4->addIndexedItem ("ma20", m_nggneu,m_a20);
256 status = m_tuple4->addIndexedItem ("ma42", m_nggneu,m_a42);
257
258 }
259 else {
260 log << MSG::ERROR << " Cannot book N-tuple:" << long(m_tuple4) << endmsg;
261 return StatusCode::FAILURE;
262 }
263 }
264
265 if(service("THistSvc", m_thsvc).isFailure()) {
266 log << MSG::ERROR << "Couldn't get THistSvc" << endreq;
267 return StatusCode::FAILURE;
268 }
269
270 // "DQAHist" is fixed
271 // "Rhopi" is control sample name, just as ntuple case.
272
273 TH1F* mrho0 = new TH1F("mrho0", "mass for #rho^{0}->#pi^{+}#pi^{-}", 160, 0.0, 3.2);
274 if(m_thsvc->regHist("/DQAHist/Rhopi/mrho0", mrho0).isFailure()) {
275 log << MSG::ERROR << "Couldn't register mrho0" << endreq;
276 }
277
278 TH1F* mrhop = new TH1F("mrhop", "mass for #rho^{+}->#pi^{+}#pi^{0}", 160, 0.0,3.2);
279 if(m_thsvc->regHist("/DQAHist/Rhopi/mrhop", mrhop).isFailure()) {
280 log << MSG::ERROR << "Couldn't register mrhop" << endreq;
281 }
282
283 TH1F* mrhom = new TH1F("mrhom", "mass for #rho^{-}->#pi^{-}#pi^{0}", 160, 0.0, 3.2);
284 if(m_thsvc->regHist("/DQAHist/Rhopi/mrhom", mrhom).isFailure()) {
285 log << MSG::ERROR << "Couldn't register mrhom" << endreq;
286 }
287
288
289 TH1F* mpi0 = new TH1F("mpi0", "mass for #pi^{0}->#gamma #gamma", 50,0.08, 0.18);
290 if(m_thsvc->regHist("/DQAHist/Rhopi/mpi0", mpi0).isFailure()) {
291 log << MSG::ERROR << "Couldn't register mpi0" << endreq;
292 }
293
294 //
295 //--------end of book--------
296 //
297
298 log << MSG::INFO << "successfully return from initialize()" <<endmsg;
299 return StatusCode::SUCCESS;
300
301}
const double mpi0
INTupleSvc * ntupleSvc()

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