35 iGam,
double Ebeam,
int PID_flag,
int Charge_candidate_D)
38 int nGood=iGood.size();
44 double mass_bcgg, delE_tag_temp;
45 int m_chargetag,m_chargepi1,m_chargepi2,m_chargepi3,m_chargepi4;
46 int ik1_temp,ipi1_temp,ipi2_temp,ipi3_temp,ipi4_temp, iGam1_temp, iGam2_temp;
47 HepLorentzVector pddd;
48 HepLorentzVector pddd_temp;
50 IDataProviderSvc* eventSvc =
NULL;
51 Gaudi::svcLocator()->service(
"EventDataSvc", eventSvc);
53 SmartDataPtr<Event::EventHeader> eventHeader(eventSvc,
"/Event/EventHeader");
55 int runNo=eventHeader->runNumber();
56 int rec=eventHeader->eventNumber();
63 if((evtRecEvent->totalCharged() < 4||nGam<2)){
return; }
68 Gaudi::svcLocator()->service(
"SimplePIDSvc", simple_pid);
70 double deltaE_tem = 0.20;
73 Hep3Vector xorigin(0,0,0);
74 HepSymMatrix xoriginEx(3,0);
76 Gaudi::svcLocator()->service(
"VertexDbSvc", vtxsvc);
85 xoriginEx[0][0] = vv[0] * vv[0];
86 xoriginEx[1][1] = vv[1] * vv[1];
87 xoriginEx[2][2] = vv[2] * vv[2];
91 double xv=xorigin.x();
92 double yv=xorigin.y();
93 double zv=xorigin.z();
96 HepPoint3D IP(xorigin[0],xorigin[1],xorigin[2]);
99 HepLorentzVector p2gfit;
100 HepLorentzVector p2gg;
102 for(
int i = 0; i < evtRecEvent->totalCharged(); i++) {
105 int ipi1= (*itTrk)->trackId();
107 if(!(*itTrk)->isMdcKalTrackValid())
continue;
111 m_chargepi1=mdcKalTrk1->
charge();
112 if(m_chargepi1 != 1)
continue;
116 HepSymMatrix Ea1 = mdcKalTrk1->
getZError();
118 VFHelix helixip3_1(point0,a1,Ea1);
119 helixip3_1.
pivot(IP);
120 HepVector vecipa1 = helixip3_1.
a();
122 double dr1 = fabs(vecipa1[0]);
123 double dz1 = fabs(vecipa1[3]);
124 double costheta1 =
cos(mdcKalTrk1->
theta());
126 if ( dr1 >= 15.0)
continue;
127 if ( dz1 >= 25.0)
continue;
128 if ( fabs(costheta1) >= 0.93)
continue;
136 for(
int j = 0; j < evtRecEvent->totalCharged();j++) {
139 int ipi2= (*itTrk)->trackId();
140 if(ipi1==ipi2)
continue;
142 if(!(*itTrk)->isMdcKalTrackValid())
continue;
146 m_chargepi2=mdcKalTrk2->
charge();
147 if((m_chargepi2 + m_chargepi1) != 0)
continue;
151 HepSymMatrix Ea2 = mdcKalTrk2->
getZError();
152 VFHelix helixip3_2(point0,a2,Ea2);
153 helixip3_2.
pivot(IP);
154 HepVector vecipa2 = helixip3_2.
a();
156 double dr2 = fabs(vecipa2[0]);
157 double dz2 = fabs(vecipa2[3]);
158 double costheta2 =
cos(mdcKalTrk2->
theta());
159 if ( dr2 >= 15.0)
continue;
160 if ( dz2 >= 25.0)
continue;
161 if ( fabs(costheta2) >= 0.93)
continue;
166 HepVector pip1_val = HepVector(7,0);
167 HepVector pim1_val = HepVector(7,0);
170 HepLorentzVector ptrktagk0(pip1_val[0]+pim1_val[0],pip1_val[1]+pim1_val[1],pip1_val[2]+pim1_val[2],pip1_val[3]+pim1_val[3]);
171 double m_xmtagk0_tem = ptrktagk0.mag();
172 if(fabs(ptrktagk0.m()-0.498)>0.1)
continue;
174 HepPoint3D vx(xorigin.x(), xorigin.y(), xorigin.z());
175 HepSymMatrix Evx(3, 0);
176 double bx = 1E+6; Evx[0][0] = bx*bx;
177 double by = 1E+6; Evx[1][1] = by*by;
178 double bz = 1E+6; Evx[2][2] = bz*bz;
187 if(!(vtxfit0->
Fit(0)))
continue;
198 for(
int k = 0; k < evtRecEvent->totalCharged(); k++) {
201 int ipi3= (*itTrk)->trackId();
202 if(ipi2==ipi3 || ipi1==ipi3)
continue;
204 if(!(*itTrk)->isMdcKalTrackValid())
continue;
208 m_chargepi3=mdcKalTrk3->
charge();
209 if(
abs(m_chargepi3) != 1)
continue;
213 HepSymMatrix Ea3 = mdcKalTrk3->
getZError();
214 VFHelix helixip3_3(point0,a3,Ea3);
215 helixip3_3.
pivot(IP);
216 HepVector vecipa3 = helixip3_3.
a();
218 double dr3 = fabs(vecipa3[0]);
219 double dz3 = fabs(vecipa3[3]);
220 double costheta3 =
cos(mdcKalTrk3->
theta());
221 if ( dr3 >= 1.0)
continue;
222 if ( dz3 >= 10.0)
continue;
223 if ( fabs(costheta3) >= 0.93)
continue;
235 for(
int l = 0; l < evtRecEvent->totalCharged(); l++) {
238 int ipi4= (*itTrk)->trackId();
239 if(ipi4==ipi3 || ipi4==ipi2 || ipi4 ==ipi1)
continue;
241 if(!(*itTrk)->isMdcKalTrackValid())
continue;
245 m_chargepi4=mdcKalTrk4->
charge();
246 if((m_chargepi4 + m_chargepi3) != 0)
continue;
250 HepSymMatrix Ea4 = mdcKalTrk4->
getZError();
251 VFHelix helixip3_4(point0,a4,Ea4);
252 helixip3_4.
pivot(IP);
253 HepVector vecipa4 = helixip3_4.
a();
255 double dr4 = fabs(vecipa4[0]);
256 double dz4 = fabs(vecipa4[3]);
257 double costheta4 =
cos(mdcKalTrk4->
theta());
258 if ( dr4 >= 1.0)
continue;
259 if ( dz4 >= 10.0)
continue;
260 if ( fabs(costheta4) >= 0.93)
continue;
269 for(
int m = 0; m < nGam-1; m++) {
270 if(iGam[m]==-1)
continue;
271 RecEmcShower *g1Trk = (*(evtRecTrkCol->begin()+iGam[m]))->emcShower();
272 double eraw1 = g1Trk->
energy();
274 double the1 = g1Trk->
theta();
275 HepLorentzVector ptrkg1,ptrkg10,ptrkg12;
278 ptrkg1.setPz(eraw1*
cos(the1));
281 ptrkg12 = ptrkg1.boost(-0.011,0,0);
283 for(
int n = m+1;
n < nGam;
n++) {
284 if(iGam[
n]==-1)
continue;
285 RecEmcShower *g2Trk = (*(evtRecTrkCol->begin()+iGam[
n]))->emcShower();
286 double eraw2 = g2Trk->
energy();
288 double the2 = g2Trk->
theta();
289 HepLorentzVector ptrkg2,ptrkg20,ptrkg22;
292 ptrkg2.setPz(eraw2*
cos(the2));
295 ptrkg22 = ptrkg2.boost(-0.011,0,0);
298 HepLorentzVector ptrkpi0;
299 ptrkpi0 = ptrkg12+ptrkg22;
300 double m_xmpi0_tem = ptrkpi0.m();
301 if(m_xmpi0_tem>0.150||m_xmpi0_tem<0.115)
continue;
303 bool IsEndcap1 =
false;
bool IsEndcap2 =
false;
304 if(fabs(
cos(the1)) > 0.86 && fabs(
cos(the1)) < 0.92) IsEndcap1 =
true;
305 if(fabs(
cos(the2)) > 0.86 && fabs(
cos(the2)) < 0.92) IsEndcap2 =
true;
306 if(IsEndcap1 && IsEndcap2)
continue;
318 double pi0_chisq = kmfit->
chisq(0);
319 if ( pi0_chisq >= 2500)
continue;
320 HepLorentzVector p2gfit = kmfit->
pfit(0) + kmfit->
pfit(1);
321 p2gfit.boost(-0.011,0,0);
329 if(!vtxfit_2->
Fit(0))
continue;
341 if(!vtxfit->
Fit())
continue;
343 if(vtxfit->
chisq() >999.)
continue;
346 double m_massks1_tem = vtxfit->
p4par().m();
347 if(m_massks1_tem < 0.485 || m_massks1_tem > 0.515)
continue;
348 HepLorentzVector p4kstag = vtxfit->
p4par();
351 HepVector pip2_val = HepVector(7,0);
352 HepVector pim2_val = HepVector(7,0);
353 HepVector ksp_val = HepVector(7,0);
354 HepVector ksm_val = HepVector(7,0);
356 pip2_val = wpip2.
w();
357 pim2_val = wpim2.
w();
361 HepLorentzVector P_PIP2(pip2_val[0],pip2_val[1],pip2_val[2],pip2_val[3]);
362 HepLorentzVector P_PIM2(pim2_val[0],pim2_val[1],pim2_val[2],pim2_val[3]);
363 HepLorentzVector P_KSP(ksp_val[0],ksp_val[1],ksp_val[2],ksp_val[3]);
364 HepLorentzVector P_KSM(ksm_val[0],ksm_val[1],ksm_val[2],ksm_val[3]);
366 p4kstag.boost(-0.011,0,0);
367 P_PIP2.boost(-0.011,0,0);
368 P_PIM2.boost(-0.011,0,0);
369 P_KSP.boost(-0.011,0,0);
370 P_KSM.boost(-0.011,0,0);
373 pddd = P_PIP2 + P_PIM2 + p4kstag + p2gfit;
375 double pk0pipipi0 = pddd.rho();
377 double temp1 = (
ecms/2)*(
ecms/2)-pk0pipipi0*pk0pipipi0 ;
378 if(temp1<0) temp1 =0;
379 double mass_bc_tem = sqrt(temp1);
380 if(mass_bc_tem <1.82 || mass_bc_tem > 1.89)
continue;
382 double delE_tag_tag =
ecms/2-pddd.e();
384 if(fabs(delE_tag_tag)<deltaE_tem) {
385 deltaE_tem = fabs(delE_tag_tag);
386 delE_tag_temp = delE_tag_tag;
387 mass_bcgg = mass_bc_tem;
395 iGam1_temp = iGam[m];
396 iGam2_temp = iGam[
n];
411 if(m_chargetag<0) tagmode=-17;
414 delE_tag = delE_tag_temp;
417 iGoodtag.push_back(ipi1_temp);
418 iGoodtag.push_back(ipi2_temp);
419 iGoodtag.push_back(ipi3_temp);
420 iGoodtag.push_back(ipi4_temp);
422 iGamtag.push_back(iGam1_temp);
423 iGamtag.push_back(iGam2_temp);
424 iGamtag.push_back(9999);
425 iGamtag.push_back(9999);