dd/dd7/KalmanKinematicFit_8cxx_source.html

#include <cmath>

#include "VertexFit/KalmanKinematicFit.h"

#include "VertexFit/KinematicConstraints.h"

#include "VertexFit/HTrackParameter.h"

#include "TStopwatch.h"

#include "TGraph2D.h"


const int KalmanKinematicFit::NTRKPAR = 4;

const int KalmanKinematicFit::Resonance = 1;

const int KalmanKinematicFit::TotalEnergy = 2;

const int KalmanKinematicFit::TotalMomentum = 4;

const int KalmanKinematicFit::Position = 8;

const int KalmanKinematicFit::ThreeMomentum = 16;

const int KalmanKinematicFit::FourMomentum = 32;

const int KalmanKinematicFit::EqualMass = 64;

//TGraph2D *g = new TGraph2D("/ihepbatch/bes/yanl/6.5.0//TestRelease/TestRelease-00-00-62/run/gamma/new/graph.dat");


KalmanKinematicFit * KalmanKinematicFit::m_pointer = 0;


KalmanKinematicFit * KalmanKinematicFit::instance() {

    if(m_pointer) return m_pointer;

    m_pointer = new KalmanKinematicFit();

    return m_pointer;

}


KalmanKinematicFit::KalmanKinematicFit(){;}


KalmanKinematicFit::~KalmanKinematicFit() {

    //       if(m_pointer) delete m_pointer;

    delete m_pointer;

}


void KalmanKinematicFit::init() {

    clearWTrackOrigin();

    clearWTrackInfit();

    clearWTrackList();

    //gamma shape

    clearGammaShape();

    clearGammaShapeList();

    clearMapkinematic();

    clearMappositionA();

    clearMappositionB();

    clearone();

    cleartwo();

    setBeamPosition(HepPoint3D(0.0,0.0,0.0));

    setVBeamPosition(HepSymMatrix(3,0));

    //=============

    m_kc.clear();

    m_chisq.clear();

    m_chi = 9999.;

    m_niter = 10;

    m_chicut = 200.;

    m_chiter = 0.005;

    m_espread = 0.0;

    m_collideangle = 11e-3;

    m_flag = 0;

    m_dynamicerror = 0;

    m_nc = 0;

    m_cpu = HepVector(10, 0);

    m_virtual_wtrk.clear();

    m_graph2d = 0;

    //  m_graph2d = TGraph2D("/ihepbatch/bes/yanl/6.5.0//TestRelease/TestRelease-00-00-62/run/gamma/new/graph.dat");

}


//

//  Add Resonance

//


void KalmanKinematicFit::AddResonance(int number, double mres, int n1) {

    std::vector<int> tlis = AddList(n1);

    AddResonance(number, mres, tlis);

}


void KalmanKinematicFit::AddResonance(int number, double mres, int n1, int n2) {

    std::vector<int> tlis = AddList(n1, n2);

    AddResonance(number, mres, tlis);

}


void KalmanKinematicFit::AddResonance(int number, double mres, int n1, int n2, int n3) {

    std::vector<int> tlis = AddList(n1, n2, n3);

    AddResonance(number, mres, tlis);

}


void KalmanKinematicFit::AddResonance(int number, double mres, int n1, int n2, int n3, int n4) {

    std::vector<int> tlis = AddList(n1, n2, n3, n4);

    AddResonance(number, mres, tlis);

}


void KalmanKinematicFit::AddResonance(int number, double mres, int n1, int n2, int n3, int n4,

        int n5) {

    std::vector<int> tlis = AddList(n1, n2, n3, n4, n5);

    AddResonance(number, mres, tlis);

}


void KalmanKinematicFit::AddResonance(int number, double mres, int n1, int n2, int n3, int n4,

        int n5, int n6) {

    std::vector<int> tlis = AddList(n1, n2, n3, n4, n5, n6);

    AddResonance(number, mres, tlis);

}


void KalmanKinematicFit::AddResonance(int number, double mres, int n1, int n2, int n3, int n4,

        int n5, int n6, int n7) {

    std::vector<int> tlis = AddList(n1, n2, n3, n4, n5, n6, n7);

    AddResonance(number, mres, tlis);

}


void KalmanKinematicFit::AddResonance(int number, double mres, int n1, int n2, int n3, int n4,

        int n5, int n6, int n7, int n8) {

    std::vector<int> tlis = AddList(n1, n2, n3, n4, n5, n6, n7, n8);

    AddResonance(number, mres, tlis);

}


void KalmanKinematicFit::AddResonance(int number, double mres, int n1, int n2, int n3, int n4,

        int n5, int n6, int n7, int n8, int n9) {

    std::vector<int> tlis = AddList(n1, n2, n3, n4, n5, n6, n7, n8, n9);

    AddResonance(number, mres, tlis);

}


void KalmanKinematicFit::AddResonance(int number, double mres, int n1, int n2, int n3, int n4,

        int n5, int n6, int n7, int n8, int n9, int n10) {

    std::vector<int> tlis = AddList(n1, n2, n3, n4, n5, n6, n7, n8, n9, n10);

    AddResonance(number, mres, tlis);

}


void KalmanKinematicFit::AddResonance(int number, double mres, int n1, int n2, int n3, int n4,

        int n5, int n6, int n7, int n8, int n9,

        int n10, int n11) {

    std::vector<int> tlis = AddList(n1, n2, n3, n4, n5, n6, n7, n8, n9, n10, n11);

    AddResonance(number, mres, tlis);

}


void KalmanKinematicFit::AddResonance(int number, double mres, int n1, int n2, int n3, int n4,

        int n5, int n6, int n7, int n8, int n9,

        int n10, int n11, int n12) {

    std::vector<int> tlis = AddList(n1, n2, n3, n4, n5, n6, n7, n8, n9, n10, n11, n12);

    AddResonance(number, mres, tlis);

}


void KalmanKinematicFit::AddResonance(int number, double mres, std::vector<int> tlis) {

    KinematicConstraints kc;

    HepSymMatrix Vre = HepSymMatrix(1,0);

    kc.ResonanceConstraints(mres, tlis, Vre);

    m_kc.push_back(kc);

    if((unsigned int) number != m_kc.size()-1)

        std::cout << "wrong kinematic constraints index" << std::endl;

}


//

//  Add TotalMomentum

//


void KalmanKinematicFit::AddTotalMomentum(int number, double ptot, int n1) {

    std::vector<int> tlis = AddList(n1);

    AddTotalMomentum(number, ptot, tlis);

}

void KalmanKinematicFit::AddTotalMomentum(int number, double ptot, int n1, int n2) {

    std::vector<int> tlis = AddList(n1, n2);

    AddTotalMomentum(number, ptot, tlis);

}


void KalmanKinematicFit::AddTotalMomentum(int number, double ptot, int n1, int n2, int n3) {

    std::vector<int> tlis = AddList(n1, n2, n3);

    AddTotalMomentum(number, ptot, tlis);

}


void KalmanKinematicFit::AddTotalMomentum(int number, double ptot, int n1, int n2, int n3, int n4) {

    std::vector<int> tlis = AddList(n1, n2, n3, n4);

    AddTotalMomentum(number, ptot, tlis);

}


void KalmanKinematicFit::AddTotalMomentum(int number, double ptot, int n1, int n2, int n3, int n4,

        int n5) {

    std::vector<int> tlis = AddList(n1, n2, n3, n4, n5);

    AddTotalMomentum(number, ptot, tlis);

}


void KalmanKinematicFit::AddTotalMomentum(int number, double ptot, int n1, int n2, int n3, int n4,

        int n5, int n6) {

    std::vector<int> tlis = AddList(n1, n2, n3, n4, n5, n6);

    AddTotalMomentum(number, ptot, tlis);

}


void KalmanKinematicFit::AddTotalMomentum(int number, double ptot, int n1, int n2, int n3, int n4,

        int n5, int n6, int n7) {

    std::vector<int> tlis = AddList(n1, n2, n3, n4, n5, n6, n7);

    AddTotalMomentum(number, ptot, tlis);

}


void KalmanKinematicFit::AddTotalMomentum(int number, double ptot, int n1, int n2, int n3, int n4,

        int n5, int n6, int n7, int n8) {

    std::vector<int> tlis = AddList(n1, n2, n3, n4, n5, n6, n7, n8);

    AddTotalMomentum(number, ptot, tlis);

}


void KalmanKinematicFit::AddTotalMomentum(int number, double ptot, int n1, int n2, int n3, int n4,

        int n5, int n6, int n7, int n8, int n9) {

    std::vector<int> tlis = AddList(n1, n2, n3, n4, n5, n6, n7, n8, n9);

    AddTotalMomentum(number, ptot, tlis);

}


void KalmanKinematicFit::AddTotalMomentum(int number, double ptot, int n1, int n2, int n3, int n4,

        int n5, int n6, int n7, int n8, int n9,

        int n10) {

    std::vector<int> tlis = AddList(n1, n2, n3, n4, n5, n6, n7, n8, n9, n10);

    AddTotalMomentum(number, ptot, tlis);

}


void KalmanKinematicFit::AddTotalMomentum(int number, double ptot, int n1, int n2, int n3, int n4,

        int n5, int n6, int n7, int n8, int n9,

        int n10, int n11) {

    std::vector<int> tlis = AddList(n1, n2, n3, n4, n5, n6, n7, n8, n9, n10, n11);

    AddTotalMomentum(number, ptot, tlis);

}


void KalmanKinematicFit::AddTotalMomentum(int number, double ptot, int n1, int n2, int n3, int n4,

        int n5, int n6, int n7, int n8, int n9,

        int n10, int n11, int n12) {

    std::vector<int> tlis = AddList(n1, n2, n3, n4, n5, n6, n7, n8, n9, n10, n11, n12);

    AddTotalMomentum(number, ptot, tlis);

}


void KalmanKinematicFit::AddTotalMomentum(int number, double ptot, std::vector<int> tlis) {

    KinematicConstraints kc;

    kc.TotalMomentumConstraints(ptot, tlis);

    m_kc.push_back(kc);

    if((unsigned int) number != m_kc.size()-1)

        std::cout << "wrong kinematic constraints index" << std::endl;

}


//

//  Add TotalEnergy

//


void KalmanKinematicFit::AddTotalEnergy(int number, double etot, int n1) {

    std::vector<int> tlis = AddList(n1);

    AddTotalEnergy(number, etot, tlis);

}

void KalmanKinematicFit::AddTotalEnergy(int number, double etot, int n1, int n2) {

    std::vector<int> tlis = AddList(n1, n2);

    AddTotalEnergy(number, etot, tlis);

}


void KalmanKinematicFit::AddTotalEnergy(int number, double etot, int n1, int n2, int n3) {

    std::vector<int> tlis = AddList(n1, n2, n3);

    AddTotalEnergy(number, etot, tlis);

}


void KalmanKinematicFit::AddTotalEnergy(int number, double etot, int n1, int n2, int n3, int n4) {

    std::vector<int> tlis = AddList(n1, n2, n3, n4);

    AddTotalEnergy(number, etot, tlis);

}


void KalmanKinematicFit::AddTotalEnergy(int number, double etot, int n1, int n2, int n3, int n4,

        int n5) {

    std::vector<int> tlis = AddList(n1, n2, n3, n4, n5);

    AddTotalEnergy(number, etot, tlis);

}


void KalmanKinematicFit::AddTotalEnergy(int number, double etot, int n1, int n2, int n3, int n4,

        int n5, int n6) {

    std::vector<int> tlis = AddList(n1, n2, n3, n4, n5, n6);

    AddTotalEnergy(number, etot, tlis);

}


void KalmanKinematicFit::AddTotalEnergy(int number, double etot, int n1, int n2, int n3, int n4,

        int n5, int n6, int n7) {

    std::vector<int> tlis = AddList(n1, n2, n3, n4, n5, n6, n7);

    AddTotalEnergy(number, etot, tlis);

}


void KalmanKinematicFit::AddTotalEnergy(int number, double etot, int n1, int n2, int n3, int n4,

        int n5, int n6, int n7, int n8) {

    std::vector<int> tlis = AddList(n1, n2, n3, n4, n5, n6, n7, n8);

    AddTotalEnergy(number, etot, tlis);

}


void KalmanKinematicFit::AddTotalEnergy(int number, double etot, int n1, int n2, int n3, int n4,

        int n5, int n6, int n7, int n8, int n9) {

    std::vector<int> tlis = AddList(n1, n2, n3, n4, n5, n6, n7, n8, n9);

    AddTotalEnergy(number, etot, tlis);

}


void KalmanKinematicFit::AddTotalEnergy(int number, double etot, int n1, int n2, int n3, int n4,

        int n5, int n6, int n7, int n8, int n9,

        int n10) {

    std::vector<int> tlis = AddList(n1, n2, n3, n4, n5, n6, n7, n8, n9, n10);

    AddTotalEnergy(number, etot, tlis);

}


void KalmanKinematicFit::AddTotalEnergy(int number, double etot, int n1, int n2, int n3, int n4,

        int n5, int n6, int n7, int n8, int n9,

        int n10, int n11) {

    std::vector<int> tlis = AddList(n1, n2, n3, n4, n5, n6, n7, n8, n9, n10, n11);

    AddTotalEnergy(number, etot, tlis);

}


void KalmanKinematicFit::AddTotalEnergy(int number, double etot, int n1, int n2, int n3, int n4,

        int n5, int n6, int n7, int n8, int n9,

        int n10, int n11, int n12) {

    std::vector<int> tlis = AddList(n1, n2, n3, n4, n5, n6, n7, n8, n9, n10, n11, n12);

    AddTotalEnergy(number, etot, tlis);

}


void KalmanKinematicFit::AddTotalEnergy(int number, double etot, std::vector<int> tlis) {

    KinematicConstraints kc;

    kc.TotalEnergyConstraints(etot, tlis);

    m_kc.push_back(kc);

    if((unsigned int) number != m_kc.size()-1)

        std::cout << "wrong kinematic constraints index" << std::endl;

}

//

//  Equal Mass constraints

//


void KalmanKinematicFit::AddEqualMass(int number, std::vector<int> tlis1, std::vector<int> tlis2)  {

    KinematicConstraints kc;

    HepSymMatrix Vne = HepSymMatrix(1,0);

    kc.EqualMassConstraints(tlis1, tlis2, Vne);

    m_kc.push_back(kc);

    if((unsigned int) number != m_kc.size()-1)

        std::cout << "wrong kinematic constraints index" << std::endl;

}


//

//  Total 3-momentum constraints

//


void KalmanKinematicFit::AddThreeMomentum(int number, Hep3Vector p3) {

    std::vector<int>  tlis;

    tlis.clear();

    WTrackParameter wtrk;

    KinematicConstraints kc;


    for(int i = 0; i < numberWTrack(); i++) {

        tlis.push_back(i);

    }

    kc.ThreeMomentumConstraints(p3, tlis);

    m_kc.push_back(kc);

    if((unsigned int) number != m_kc.size()-1)

        std::cout << "wrong kinematic constraints index" << std::endl;

}


//

//  Total 4-momentum constraints

//


void KalmanKinematicFit::AddFourMomentum(int number, HepLorentzVector p4) {


    std::vector<int> tlis;

    tlis.clear();

    KinematicConstraints kc;


    for(int i = 0; i < numberWTrack(); i++) {

        tlis.push_back(i);

    }


    HepSymMatrix Vme = HepSymMatrix(4,0);

    Vme[0][0] = 2*m_espread*m_espread*sin(m_collideangle)*sin(m_collideangle);

    Vme[0][3] = 2*m_espread*m_espread*sin(m_collideangle);

    Vme[3][3] = 2*m_espread*m_espread;


    kc.FourMomentumConstraints(p4, tlis, Vme);

    m_kc.push_back(kc);

    if((unsigned int) number != m_kc.size()-1)

        std::cout << "wrong kinematic constraints index" << std::endl;

}


void KalmanKinematicFit::AddFourMomentum(int number, double etot ){


    HepLorentzVector p4(0.0, 0.0, 0.0, etot);

    std::vector<int> tlis;

    tlis.clear();

    KinematicConstraints kc;


    for(int i = 0; i < numberWTrack(); i++) {

        tlis.push_back(i);

    }

    HepSymMatrix Vme = HepSymMatrix (4,0);

    Vme[3][3] = 2*m_espread*m_espread;

    kc.FourMomentumConstraints(p4, tlis, Vme);

    m_kc.push_back(kc);

    if((unsigned int) number != m_kc.size()-1)

        std::cout << "wrong kinematic constraints index" << std::endl;

}


void KalmanKinematicFit::fit() {


    KinematicConstraints kc;

    int nc = m_nc;

    int ntrk = numberWTrack();


    TStopwatch timer;


    timer.Start();

    //cout<<" =====calculate AC_{0}A^{T}====="<<endl;

    HepSymMatrix AC(m_nc, 0);

    AC = m_C0.similarity(m_A);

    timer.Stop();

    m_cpu[1] += timer.CpuTime();


    timer.Start();

    //cout<<" =====calculate W====="<<endl;

    int ifail;

    m_W = HepSymMatrix(m_nc, 0);

    m_W = (m_Vm + m_C0.similarity(m_A)).inverse(ifail);

    //cout<<" =====calculate D , D^{-1}====="<<endl;

    int ifailD;

    m_Dinv =  m_D0inv + m_W.similarity(m_B.T());

    m_D = m_Dinv.inverse(ifailD);

    timer.Stop();

    m_cpu[2] += timer.CpuTime();


    timer.Start();

    //cout<<"===== G equals r ====="<<endl;

    HepVector G(m_nc, 0);

    G = m_A * (m_p0 - m_p) + m_B * (m_q0 - m_q)+ m_G;

    //cout<<"===== calculate KQ, Kp======"<<endl;

    m_KQ = HepMatrix(numbertwo(), m_nc, 0);

    m_KQ = m_D * m_BT * m_W;


    m_KP = HepMatrix(numberone(), m_nc, 0);

    m_KP = m_C0 * m_AT * m_W - m_C0 * m_AT * m_W * m_B * m_KQ;

    // ===== update track par =====

    m_p = m_p0 - m_KP * G;

    m_q = m_q0 - m_KQ * G;

    timer.Stop();

    m_cpu[4] += timer.CpuTime();


    timer.Start();

    //===== caluculate chi2 =====

    m_chi = (m_W.similarity(G.T()) - m_Dinv.similarity((m_q - m_q0).T()))[0][0];

    timer.Stop();

    m_cpu[3] += timer.CpuTime();

    timer.Start();

    if(m_dynamicerror ==1)

        gda();


    timer.Stop();

    m_cpu[6] += timer.CpuTime();


}


void KalmanKinematicFit::upCovmtx() {

    HepMatrix E(numberone(), numbertwo(), 0);

    E = -m_C0 * m_A.T() * m_KQ.T();

    m_C = m_C0 - m_W.similarity((m_A*m_C0).T()) + m_Dinv.similarity(E);

}


void KalmanKinematicFit::fit(int n) {

    if(m_chisq.size() == 0) {

        for(unsigned int i = 0; i < m_kc.size(); i++)

            m_chisq.push_back(9999.0);

    }


    KinematicConstraints kc;

    int nc = m_nc;

    int ntrk = numberWTrack();


    //cout<<" =====calculate AC_{0}A^{T}====="<<endl;

    HepSymMatrix AC(m_nc, 0);

    AC = m_C0.similarity(m_A);


    //cout<<" =====calculate W====="<<endl;

    int ifail;

    m_W = HepSymMatrix(m_nc, 0);

    m_W = (m_Vm + m_C0.similarity(m_A)).inverse(ifail);

    //cout<<" =====calculate D , D^{-1}====="<<endl;

    int ifailD;

    m_Dinv =  m_D0inv + m_W.similarity(m_B.T());

    m_D = m_Dinv.inverse(ifailD);


    //cout<<"===== G equals r ====="<<endl;

    HepVector G(m_nc, 0);

    G = m_A * (m_p0 - m_p) + m_B * (m_q0 - m_q)+ m_G;

    //cout<<"===== calculate KQ, Kp======"<<endl;

    m_KQ = HepMatrix(numbertwo(), m_nc, 0);

    m_KQ = m_D * m_BT * m_W;


    m_KP = HepMatrix(numberone(), m_nc, 0);

    m_KP = m_C0 * m_AT * m_W - m_C0 * m_AT * m_W * m_B * m_KQ;

    // ===== update track par =====

    m_p = m_p0 - m_KP * G;

    m_q = m_q0 - m_KQ * G;


    //===== caluculate chi2 =====

    m_chisq[n] = (m_W.similarity(G.T()) - m_Dinv.similarity((m_q - m_q0).T()))[0][0];

    if(m_dynamicerror ==1)

        gda();

}


bool KalmanKinematicFit::Fit() {

    bool okfit = false;

    TStopwatch timer;

    m_nktrk = numberWTrack();

    m_p0 = HepVector(numberone(), 0);

    m_p  = HepVector(numberone(), 0);

    m_q0 = HepVector(numbertwo(), 0);

    m_q  = HepVector(numbertwo(), 0);

    m_C0 = HepSymMatrix(numberone(), 0);

    m_C  = HepSymMatrix(numberone(), 0);

    m_D0inv = HepSymMatrix(numbertwo(), 0);

    m_D  = HepSymMatrix(numbertwo(), 0);


    HepVector  m_p_tmp = HepVector(numberone(), 0);

    HepVector  m_q_tmp = HepVector(numbertwo(), 0);

    HepMatrix  m_A_tmp;

    HepSymMatrix m_W_tmp;

    HepMatrix  m_KQ_tmp;

    HepSymMatrix m_Dinv_tmp;

    for(int i = 0; i < numberWTrack(); i++) {

        setWTrackInfit(i, wTrackOrigin(i));

        int pa = mappositionA()[i] + 1;

        int pb = mappositionB()[i] + 1;

        int ptype = mapkinematic()[i];

        switch(ptype) {

            case 0 : {

                         HepVector w1(4, 0);

                         HepSymMatrix Ew1(4, 0);

                         for(int j = 0; j < 3; j++) {

                             w1[j] = wTrackOrigin(i).w()[j];

                         }

                         w1[3] = wTrackOrigin(i).mass();


                         for(int m = 0; m < 3; m++) {

                             for(int n = 0; n < 3; n++) {

                                 Ew1[m][n] = wTrackOrigin(i).Ew()[m][n];

                             }

                         }

                         setPOrigin(pa, w1);

                         setPInfit(pa, w1);

                         setCOrigin(pa, Ew1);

                         break;

                     }

            case 1 : {

                         setPOrigin(pa, (wTrackOrigin(i).plmp()).sub(1, 4));

                         setPInfit(pa, (wTrackOrigin(i).plmp()).sub(1, 4));

                         setCOrigin(pa, (wTrackOrigin(i).Vplm()).sub(1, 4));

                         break;

                     }

            case 2 : {

                         setQOrigin(pb, (wTrackOrigin(i).w()).sub(1, NTRKPAR));

                         setQInfit(pb, (wTrackOrigin(i).w()).sub(1, NTRKPAR));

                         HepSymMatrix Dinv(4,0);

                         setDOriginInv(pb, Dinv);

                         break;

                     }

            case 3 : {

                         setPOrigin(pa, (wTrackOrigin(i).plmp()).sub(3, 3));

                         setPInfit(pa, (wTrackOrigin(i).plmp()).sub(3, 3));

                         setCOrigin(pa, (wTrackOrigin(i).Vplm()).sub(3, 3));

                         setQOrigin(pb, (wTrackOrigin(i).plmp()).sub(1, 2));

                         setQInfit(pb, (wTrackOrigin(i).plmp()).sub(1, 2));

                         setQOrigin(pb+2, (wTrackOrigin(i).plmp()).sub(4, 4));

                         setQInfit(pb+2, (wTrackOrigin(i).plmp()).sub(4, 4));

                         HepSymMatrix Dinv(3,0);

                         setDOriginInv(pb, Dinv);

                         break;

                     }

            case 4 : {

                         setPOrigin(pa, (wTrackOrigin(i).plmp()).sub(1, 2));

                         setPInfit(pa, (wTrackOrigin(i).plmp()).sub(1, 2));

                         setCOrigin(pa, (wTrackOrigin(i).Vplm()).sub(1, 2));

                         setQOrigin(pb, (wTrackOrigin(i).plmp()).sub(3, 4));

                         setQInfit(pb, (wTrackOrigin(i).plmp()).sub(3, 4));

                         HepSymMatrix Dinv(2,0);

                         setDOriginInv(pb, Dinv);

                         break;

                     }

            case 5 : {

                         setPOrigin(pa, (wTrackOrigin(i).plmp()).sub(1, 3));

                         setPInfit(pa, (wTrackOrigin(i).plmp()).sub(1, 3));

                         setCOrigin(pa, (wTrackOrigin(i).Vplm()).sub(1, 3));

                         setQOrigin(pb, (wTrackOrigin(i).plmp()).sub(4, 4));

                         setQInfit(pb, (wTrackOrigin(i).plmp()).sub(4, 4));

                         HepSymMatrix Dinv(1,0);

                         setDOriginInv(pb, Dinv);

                         break;

                     }

            case 6 : {

                         setPOrigin(pa, (wTrackOrigin(i).w()).sub(5, 7));

                         setPOrigin(pa+3, (wTrackOrigin(i).w()).sub(4, 4));

                         setPInfit(pa, (wTrackOrigin(i).w()).sub(5, 7));

                         setPInfit(pa+3, (wTrackOrigin(i).w()).sub(4, 4));

                         setCOrigin(pa, (wTrackOrigin(i).Ew()).sub(5,7));

                         setCOrigin(pa+3, (wTrackOrigin(i).Ew()).sub(4,4));

                         HepVector beam(3,0);

                         beam[0] = getBeamPosition().x();

                         beam[1] = getBeamPosition().y();

                         beam[2] = getBeamPosition().z();

                         setQOrigin(pb, beam);

                         setQInfit(pb, beam);

                         HepSymMatrix Dinv(3, 0);

                         int ifail;

                         Dinv = getVBeamPosition().inverse(ifail);

                         setDOriginInv(pb, Dinv);

                         break;

                     }

            case 7 : {

                         HepVector w1(4, 0);

                         HepSymMatrix Ew1(4, 0);

                         for(int j = 0; j < 3; j++) {

                             w1[j] = wTrackOrigin(i).w()[j];

                         }

                         w1[3] = wTrackOrigin(i).mass();


                         for(int m = 0; m < 3; m++) {

                             for(int n = 0; n < 3; n++) {

                                 Ew1[m][n] = wTrackOrigin(i).Ew()[m][n];

                             }

                         }

                         setPOrigin(pa, w1);

                         setPInfit(pa, w1);

                         setCOrigin(pa, Ew1);

                         break;

                     }


        }

    }


    //

    // iteration

    //


    std::vector<double> chisq;

    chisq.clear();

    int nc = 0;

    for(int i = 0; i < m_kc.size(); i++)

        nc += m_kc[i].nc();


    m_A = HepMatrix(nc, numberone(), 0);

    m_AT = HepMatrix(numberone(), nc, 0);

    m_B = HepMatrix(nc, numbertwo(), 0);

    m_BT = HepMatrix(numbertwo(), nc, 0);

    m_G = HepVector(nc, 0);

    m_Vm = HepSymMatrix(nc, 0);

    int num1 = 0;

    for(unsigned int i = 0; i < m_kc.size(); i++) {

        KinematicConstraints kc = m_kc[i];

        m_Vm.sub(num1+1,kc.Vmeasure());

        num1 = num1 + kc.nc();

    }


    double tmp_chisq = 999;

    bool flag_break = 0;

    for(int it = 0; it < m_niter; it++) {

        timer.Start();

        m_nc = 0;

        for(unsigned int i = 0; i < m_kc.size(); i++) {

            KinematicConstraints kc = m_kc[i];

            updateConstraints(kc);

        }

        timer.Stop();

        m_cpu[0] += timer.CpuTime();

        fit();

        //

        //reset origin parameters for virtual particle

        //

        //                if(it == 0){

        //                    for(int i = 0; i < numberWTrack(); i++) {

        //                      //  setWTrackInfit(i, wTrackOrigin(i));

        //                        int pa = mappositionA()[i] + 1;

        //                        int pb = mappositionB()[i] + 1;

        //                        int ptype = mapkinematic()[i];

        //                        switch(ptype) {

        //                           case 3 : {

        //                                         setPOrigin(pa, m_p.sub(pa, pa));

        //                                         setPInfit(pa,  m_p.sub(pa, pa));

        //                                         setQOrigin(pb, m_q.sub(pb, pb+2));

        //                                         setQInfit(pb,  m_q.sub(pb, pb+2));

        //                                         break;

        //                                    }

        //                           case 4 : {

        //                                        setPOrigin(pa, (wTrackOrigin(i).plmp()).sub(1, 2));

        //                                        setPInfit(pa, (wTrackOrigin(i).plmp()).sub(1, 2));

        //                                        setCOrigin(pa, (wTrackOrigin(i).Vplm()).sub(1, 2));

        //                                        setQOrigin(pb, (wTrackOrigin(i).plmp()).sub(3, 4));

        //                                        setQInfit(pb, (wTrackOrigin(i).plmp()).sub(3, 4));

        //                                        HepSymMatrix Dinv(2,0);

        //                                        setDOriginInv(pb, Dinv);

        //                                        break;

        //                                    }

        //                           case 5 : {

        //                                        setPOrigin(pa, (wTrackOrigin(i).plmp()).sub(1, 3));

        //                                        setPInfit(pa, (wTrackOrigin(i).plmp()).sub(1, 3));

        //                                        setCOrigin(pa, (wTrackOrigin(i).Vplm()).sub(1, 3));

        //                                        setQOrigin(pb, (wTrackOrigin(i).plmp()).sub(4, 4));

        //                                        setQInfit(pb, (wTrackOrigin(i).plmp()).sub(4, 4));

        //                                        HepSymMatrix Dinv(1,0);

        //                                        setDOriginInv(pb, Dinv);

        //                                        break;

        //                                    }

        //                           case 6 : {

        //                                        setPOrigin(pa, (wTrackOrigin(i).w()).sub(5, 7));

        //                                        setPOrigin(pa+3, (wTrackOrigin(i).w()).sub(4, 4));

        //                                        setPInfit(pa, (wTrackOrigin(i).w()).sub(5, 7));

        //                                        setPInfit(pa+3, (wTrackOrigin(i).w()).sub(4, 4));

        //                                        setCOrigin(pa, (wTrackOrigin(i).Ew()).sub(5,7));

        //                                        setCOrigin(pa+3, (wTrackOrigin(i).Ew()).sub(4,4));

        //                                        HepVector beam(3,0);

        //                                        beam[0] = getBeamPosition().x();

        //                                        beam[1] = getBeamPosition().y();

        //                                        beam[2] = getBeamPosition().z();

        //                                        setQOrigin(pb, beam);

        //                                        setQInfit(pb, beam);

        //                                        HepSymMatrix Dinv(3, 0);

        //                                        int ifail;

        //                                        Dinv = getVBeamPosition().inverse(ifail);

        //                                        setDOriginInv(pb, Dinv);

        //                                        break;

        //                                    }

        //

        //                        }

        //                    }

        //

        //                }

        //

        //

        //===================reset over=============================

        //

        chisq.push_back(m_chi);

        if(it > 0) {

            double delchi = chisq[it]- chisq[it-1];

            if(fabs(delchi) < m_chiter){

                flag_break =1;

                break;

            }

        }

    }

    if(!flag_break) {

        return okfit;

    }

    if(m_chi > m_chicut) return okfit;

    timer.Start();

    timer.Stop();

    m_cpu[5] += timer.CpuTime();

    okfit = true;

    return okfit;


}


bool KalmanKinematicFit::Fit(int n) {

    bool okfit = false;

    if(n < 0 || (unsigned int)n >= m_kc.size()) return okfit;

    m_nktrk = numberWTrack();

    m_p0 = HepVector(numberone(), 0);

    m_p  = HepVector(numberone(), 0);

    m_q0 = HepVector(numbertwo(), 0);

    m_q  = HepVector(numbertwo(), 0);

    m_C0 = HepSymMatrix(numberone(), 0);

    m_C  = HepSymMatrix(numberone(), 0);

    m_D0inv = HepSymMatrix(numbertwo(), 0);

    m_D  = HepSymMatrix(numbertwo(), 0);


    for(int i = 0; i < numberWTrack(); i++) {

        setWTrackInfit(i, wTrackOrigin(i));

        int pa = mappositionA()[i] + 1;

        int pb = mappositionB()[i] + 1;

        int ptype = mapkinematic()[i];

        switch(ptype) {

            case 0 : {

                         HepVector w1(4, 0);

                         HepSymMatrix Ew1(4, 0);

                         for(int j = 0; j < 3; j++) {

                             w1[j] = wTrackOrigin(i).w()[j];

                         }

                         w1[3] = wTrackOrigin(i).mass();


                         for(int m = 0; m < 3; m++) {

                             for(int n = 0; n < 3; n++) {

                                 Ew1[m][n] = wTrackOrigin(i).Ew()[m][n];

                             }

                         }

                         setPOrigin(pa, w1);

                         setPInfit(pa, w1);

                         setCOrigin(pa, Ew1);

                         break;

                     }

            case 1 : {

                         setPOrigin(pa, (wTrackOrigin(i).plmp()).sub(1, 4));

                         setPInfit(pa, (wTrackOrigin(i).plmp()).sub(1, 4));

                         setCOrigin(pa, (wTrackOrigin(i).Vplm()).sub(1, 4));

                         break;

                     }

            case 2 : {

                         setQOrigin(pb, (wTrackOrigin(i).w()).sub(1, NTRKPAR));

                         setQInfit(pb, (wTrackOrigin(i).w()).sub(1, NTRKPAR));

                         HepSymMatrix Dinv(4,0);

                         setDOriginInv(pb, Dinv);

                         break;

                     }

            case 3 : {

                         setPOrigin(pa, (wTrackOrigin(i).plmp()).sub(3, 3));

                         setPInfit(pa, (wTrackOrigin(i).plmp()).sub(3, 3));

                         setCOrigin(pa, (wTrackOrigin(i).Vplm()).sub(3, 3));

                         setQOrigin(pb, (wTrackOrigin(i).w()).sub(1, 3));

                         setQInfit(pb, (wTrackOrigin(i).w()).sub(1, 3));

                         HepSymMatrix Dinv(3,0);

                         setDOriginInv(pb, Dinv);

                         break;

                     }

            case 4 : {

                         setPOrigin(pa, (wTrackOrigin(i).plmp()).sub(1, 2));

                         setPInfit(pa, (wTrackOrigin(i).plmp()).sub(1, 2));

                         setCOrigin(pa, (wTrackOrigin(i).Vplm()).sub(1, 2));

                         setQOrigin(pb, (wTrackOrigin(i).plmp()).sub(3, 4));

                         setQInfit(pb, (wTrackOrigin(i).plmp()).sub(3, 4));

                         HepSymMatrix Dinv(2,0);

                         setDOriginInv(pb, Dinv);

                         break;

                     }

            case 5 : {

                         setPOrigin(pa, (wTrackOrigin(i).plmp()).sub(1, 3));

                         setPInfit(pa, (wTrackOrigin(i).plmp()).sub(1, 3));

                         setCOrigin(pa, (wTrackOrigin(i).Vplm()).sub(1, 3));

                         setQOrigin(pb, (wTrackOrigin(i).plmp()).sub(4, 4));

                         setQInfit(pb, (wTrackOrigin(i).plmp()).sub(4, 4));

                         HepSymMatrix Dinv(1,0);

                         setDOriginInv(pb, Dinv);

                         break;

                     }

            case 6 : {

                         setPOrigin(pa, (wTrackOrigin(i).w()).sub(5, 7));

                         setPOrigin(pa+3, (wTrackOrigin(i).w()).sub(4, 4));

                         setPInfit(pa, (wTrackOrigin(i).w()).sub(5, 7));

                         setPInfit(pa+3, (wTrackOrigin(i).w()).sub(4, 4));

                         setCOrigin(pa, (wTrackOrigin(i).Ew()).sub(5,7));

                         setCOrigin(pa+3, (wTrackOrigin(i).Ew()).sub(4,4));

                         HepVector beam(3,0);

                         beam[0] = getBeamPosition().x();

                         beam[1] = getBeamPosition().y();

                         beam[2] = getBeamPosition().z();

                         setQOrigin(pb, beam);

                         setQInfit(pb, beam);

                         HepSymMatrix Dinv(3, 0);

                         int ifail;

                         Dinv = getVBeamPosition().inverse(ifail);


                         setDOriginInv(pb, Dinv);

                         break;

                     }


            case 7 : {

                         HepVector w1(4, 0);

                         HepSymMatrix Ew1(4, 0);

                         for(int j = 0; j < 3; j++) {

                             w1[j] = wTrackOrigin(i).w()[j];

                         }

                         w1[3] = wTrackOrigin(i).mass();


                         for(int m = 0; m < 3; m++) {

                             for(int n = 0; n < 3; n++) {

                                 Ew1[m][n] = wTrackOrigin(i).Ew()[m][n];

                             }

                         }

                         setPOrigin(pa, w1);

                         setPInfit(pa, w1);

                         setCOrigin(pa, Ew1);

                         break;

                     }

        }

    }


    //

    // iteration

    //


    std::vector<double> chisq;

    chisq.clear();

    int nc = 0;

    //  for(int i = 0; i < m_kc.size(); i++)

    nc += m_kc[n].nc();


    m_A = HepMatrix(nc, numberone(), 0);

    m_AT = HepMatrix(numberone(), nc, 0);

    m_B = HepMatrix(nc, numbertwo(), 0);

    m_BT = HepMatrix(numbertwo(), nc, 0);

    m_G = HepVector(nc, 0);

    m_Vm = HepSymMatrix(nc, 0);

    int num1 = 0;

    KinematicConstraints kc = m_kc[n];

    m_Vm.sub(num1+1,kc.Vmeasure());

    num1 =  kc.nc();

    for(int it = 0; it < m_niter; it++) {

        m_nc = 0;

        KinematicConstraints kc = m_kc[n];

        updateConstraints(kc);

        fit(n);


        chisq.push_back(m_chisq[n]);


        if(it > 0) {


            double delchi = chisq[it]- chisq[it-1];

            if(fabs(delchi) < m_chiter)

                break;

        }

    }

    if(m_chisq[n] >= m_chicut) {

        return okfit;

    }

    //update track parameter and its covariance matrix

    //upCovmtx();


    okfit = true;


    return okfit;


}


void KalmanKinematicFit::BuildVirtualParticle( int n) {

    upCovmtx();

    KinematicConstraints kc = m_kc[n];

    int ntrk = (kc.Ltrk()).size();

    int charge = 0;

    HepVector w(7, 0);

    HepSymMatrix ew1(7, 0);

    HepSymMatrix ew2(7, 0);

    HepVector w4(4, 0);

    HepSymMatrix ew4(4, 0);

    HepMatrix dwdp(4, 4, 0);

    dwdp[0][0] = 1;

    dwdp[1][1] = 1;

    dwdp[2][2] = 1;

    dwdp[3][3] = 1;

    for (int i = 0; i < ntrk; i++) {

        int itk = (kc.Ltrk())[i];

        charge += wTrackInfit(itk).charge();

        w4 = w4 + dwdp * pInfit(itk);

        //              ew = ew + (getCInfit(itk)).similarity(dwdp);

    }

    HepMatrix I(4, numberone(), 0);

    for(int j2=0; j2<ntrk; j2++){

        I[0][0+j2*4] = 1;

        I[1][1+j2*4] = 1;

        I[2][2+j2*4] = 1;

        I[3][3+j2*4] = 1;

    }

    ew4 = m_C.similarity(I);

    HepMatrix J(7,4,0);

    double px = w4[0];

    double py = w4[1];

    double pz = w4[2];

    double e = w4[3];

    double pt = sqrt(px*px + py*py);

    double p0 = sqrt(px*px + py*py + pz*pz);

    double m =  sqrt(e*e - p0*p0);

    J[0][0] = -py;

    J[0][1] = -(pz*px*pt)/(p0*p0);

    J[0][2] = -m*px/(p0*p0);

    J[0][3] = e*px/(p0*p0);

    J[1][0] = px;

    J[1][1] = -(pz*py*pt)/(p0*p0);

    J[1][2] = -m*py/(p0*p0);

    J[1][3] = e*py/(p0*p0);

    J[2][0] = 0;

    J[2][1] = pt*pt*pt/(p0*p0);

    J[2][2] = -m*pz/(p0*p0);

    J[2][3] = e*pz/(p0*p0);

    J[3][0] = 0;

    J[3][1] = 0;

    J[3][2] = 0;

    J[3][3] = 1;

    ew1 = ew4.similarity(J);

    ew2[0][0] = ew1[0][0];

    ew2[1][1] = ew1[1][1];

    ew2[2][2] = ew1[2][2];

    ew2[3][3] = ew1[3][3];

    w[0] = w4[0];

    w[1] = w4[1];

    w[2] = w4[2];

    w[3] = w4[3];

    WTrackParameter vwtrk;

    vwtrk.setCharge(charge);

    vwtrk.setW(w);

    vwtrk.setEw(ew2);

    vwtrk.setMass(m);

    m_virtual_wtrk.push_back(vwtrk);

}


void KalmanKinematicFit::gda(){

    //        TGraph2D *g = new TGraph2D("/ihepbatch/bes/yanl/6.5.0//TestRelease/TestRelease-00-00-62/run/gamma/new/graph.dat");

    for(int i = 0; i < numberWTrack(); i++) {

        if ((wTrackOrigin(i)).type() == 2 ){

            int n ;

            for(int j = 0; j < numberGammaShape(); j++) {

                if(i==GammaShapeList(j))  n = j;

            }

            int pa = mappositionA()[i] + 1;

            int pb = mappositionB()[i] + 1;

            int ptype = mapkinematic()[i];

            HepSymMatrix Ew(NTRKPAR, 0);

            HepLorentzVector p1 = p4Infit(i);

            HepLorentzVector p2 = p4Origin(i);

            double eorigin = pOrigin(i)[3];

            HepMatrix dwda1(NTRKPAR, 3, 0);

            dwda1[0][0] = 1;

            dwda1[1][1] = - (p2.e()*p2.e())/(p2.px()*p2.px() + p2.py()*p2.py());

            //            dwda1[1][1] = - (p1.e()*p1.e())/(p1.px()*p1.px() + p1.py()*p1.py());

            dwda1[3][2] = 1;

            HepSymMatrix emcmea1(3, 0);

            double pk = p1[3];

            //                      double pk = GammaShapeValue(n).peak(p1[3]);

            emcmea1[0][0] = GammaShapeValue(n).getdphi() * GammaShapeValue(n).getdphi();

            emcmea1[1][1] = GammaShapeValue(n).getdthe() * GammaShapeValue(n).getdthe()*(1/(1 - p2.cosTheta()*p2.cosTheta())) *(1/(1 - p2.cosTheta()*p2.cosTheta()));

            //            cout<<"delta lambda ="<<emcmea1[1][1]<<endl;

            emcmea1[2][2] = GammaShapeValue(n).de(eorigin,pk)*GammaShapeValue(n).de(eorigin,pk);

            //                        double tmp_e22 = m_graph2d->Interpolate(eorigin, pk);

            //                        if(fabs((eorigin/pk)-1)<0.05&&tmp_e22==0)emcmea1[2][2] = 0.025*pk*0.025;

            //                        else  emcmea1[2][2] = (tmp_e22*tmp_e22);

            //                        emcmea1[2][2] = m_graph2d->Interpolate(eorigin, pk)*m_graph2d->Interpolate(eorigin, pk);

            //                      emcmea1[2][2] = GammaShapeValue(n).de(eorigin,pk) * GammaShapeValue(n).de(eorigin,pk);

            //         cout<<"dy_e  ="<<GammaShapeValue(n).de(eorigin,pk)<<endl;

            //        Ew = emcmea1.similarity(dwda1);

            Ew[0][0] = emcmea1[0][0];

            Ew[1][1] = emcmea1[1][1];

            Ew[3][3] = emcmea1[2][2];

            //            cout<<"Ew ="<<Ew<<endl;

            if(ptype==6)

                setCOrigin(pa+3, Ew.sub(4,4));

            else setCOrigin(pa,Ew);

        }

    }

}


HepVector  KalmanKinematicFit::pull(int n){

    upCovmtx();

    int pa = mappositionA()[n] + 1;

    int pb = mappositionB()[n] + 1 ;

    int ptype = mapkinematic()[n];

    switch(ptype) {

        case 0 :{

                    HepVector W(7,0);

                    HepSymMatrix Ew(7,0);

                    HepVector W1(7,0);

                    HepSymMatrix Ew1(7,0);

                    WTrackParameter wtrk = wTrackOrigin(n);

                    W = wTrackOrigin(n).w();

                    Ew = wTrackOrigin(n).Ew();

                    for(int i=0; i<4; i++) {

                        W[i] = pInfit(n)[i];

                    }

                    for(int j=0; j<4; j++) {

                        for(int k=0; k<4; k++) {

                            Ew[j][k] = getCInfit(n)[j][k];

                        }

                    }

                    W1 = W;

                    double px = p4Infit(n).px();

                    double py = p4Infit(n).py();

                    double pz = p4Infit(n).pz();

                    double m =  p4Infit(n).m();

                    double e =  p4Infit(n).e();

                    HepMatrix J(7, 7, 0);

                    J[0][0] = 1;

                    J[1][1] = 1;

                    J[2][2] = 1;

                    J[3][0] = px/e;

                    J[3][1] = py/e;

                    J[3][2] = pz/e;

                    J[3][3] = m/e;

                    J[4][4] = 1;

                    J[5][5] = 1;

                    J[6][6] = 1;

                    Ew1 = Ew.similarity(J);


                    wtrk.setW(W1);

                    wtrk.setEw(Ew1);

                    setWTrackInfit(n, wtrk);


                    HTrackParameter horigin = HTrackParameter(wTrackOrigin(n));

                    HTrackParameter hinfit = HTrackParameter(wTrackInfit(n));

                    HepVector a0 = horigin.hel();

                    HepVector a1 = hinfit.hel();

                    HepSymMatrix v0 = horigin.eHel();

                    HepSymMatrix v1 = hinfit.eHel();

                    HepVector pull(9,0);

                    for (int k=0; k<5; k++) {

                        pull[k] = (a0[k]-a1[k])/sqrt(abs(v0[k][k]-v1[k][k]));

                    }

                    for (int l=5; l<9; l++) {

                        pull[l] = (wTrackOrigin(n).w()[l-5] - wTrackInfit(n).w()[l-5])/sqrt(abs(wTrackOrigin(n).Ew()[l-5][l-5] - wTrackInfit(n).Ew()[l-5][l-5]));

                    }

                    return pull;

                    break;

                }

        case 1 : {

                     HepVector a0(4,0);

                     HepVector a1(4,0);

                     a0 = m_p0.sub(pa, pa+3);

                     a1 = m_p.sub(pa, pa+3);

                     HepSymMatrix v1 = getCInfit(n);

                     HepSymMatrix v0 = getCOrigin(n);

                     HepVector pull(3,0);

                     for (int k=0; k<2; k++) {

                         pull[k] = (a0[k]-a1[k])/sqrt(v0[k][k]-v1[k][k]);

                     }

                     pull[2] = (a0[3]-a1[3])/sqrt(v0[3][3]-v1[3][3]);

                     return pull;

                     break;

                 }

                 //        case 2 : {

                 //        return pull;

                 //        break;

                 //        }

                 //        case 3 : {

                 //        return pull;

                 //        break;

                 //        }

                 //        case 4 : {

                 //        return pull;

                 //        break;

                 //        }

        case 5 : {

                     HepLorentzVector p0 = p4Origin(n);

                     HepLorentzVector p1 = p4Infit(n);

                     HepVector a0(2,0);

                     HepVector a1(2,0);

                     a0[0] = p4Origin(n).phi();

                     a1[0] = p4Infit(n).phi();

                     a0[1] = p4Origin(n).pz()/p4Origin(n).perp();

                     a1[1] = p4Infit(n).pz()/p4Infit(n).perp();

                     HepMatrix Jacobi(2, 4, 0);

                     Jacobi[0][0] = - p4Infit(n).py()/p4Infit(n).perp2();

                     Jacobi[0][1] =   p4Infit(n).px()/p4Infit(n).perp2();

                     Jacobi[1][0] = - (p4Infit(n).px()/p4Infit(n).perp()) * (p4Infit(n).pz()/p4Infit(n).perp2());

                     Jacobi[1][1] = - (p4Infit(n).py()/p4Infit(n).perp()) * (p4Infit(n).pz()/p4Infit(n).perp2());

                     Jacobi[1][2] = 1/p4Infit(n).perp();

                     HepSymMatrix v1 = getCInfit(n).similarity(Jacobi);

                     HepSymMatrix v0 = wTrackOrigin(n).Vplm().sub(1,2);

                     HepVector pull(2,0);

                     for (int k=0; k<2; k++) {

                         pull[k] = (a0[k]-a1[k])/sqrt(v0[k][k]-v1[k][k]);

                     }

                     return pull;

                     break;

                 }

    }

}


HepVector KalmanKinematicFit::pInfit(int n) const {

    int pa = mappositionA()[n] + 1;

    int pb = mappositionB()[n] + 1;

    int ptype = mapkinematic()[n];

    switch(ptype) {

        case 0 : {

                     double mass = m_p.sub(pa+3, pa+3)[0];

                     HepVector p4(4,0);

                     p4[0] = m_p.sub(pa,pa)[0];

                     p4[1] = m_p.sub(pa+1, pa+1)[0];

                     p4[2] = m_p.sub(pa+2, pa+2)[0];

                     p4[3] = sqrt(p4[0]*p4[0] + p4[1]*p4[1] + p4[2]*p4[2] + mass * mass);

                     return p4;

                     break;

                 }

        case 1 : {

                     double phi = m_p.sub(pa, pa)[0];

                     double lambda = m_p.sub(pa+1, pa+1)[0];

                     double mass = m_p.sub(pa+2, pa+2)[0];

                     double E = m_p.sub(pa+3, pa+3)[0];

                     double p0 = sqrt(E*E - mass*mass);

                     HepVector p4(4,0);

                     p4[0] = p0*cos(phi)/sqrt(1 + lambda*lambda);

                     p4[1] = p0*sin(phi)/sqrt(1 + lambda*lambda);

                     p4[2] = p0*lambda/sqrt(1 + lambda*lambda);

                     p4[3] = sqrt(p0*p0 + mass*mass);

                     return p4;

                     break;

                 }

        case 2 : {

                     return m_q.sub(pb, pb+3);

                     break;

                 }

        case 3 : {

                     double mass = (m_p.sub(pa, pa))[0];

                     double phi = m_q.sub(pb, pb)[0];

                     double lambda = m_q.sub(pb+1, pb+1)[0];

                     double E = m_q.sub(pb+2, pb+2)[0];

                     double p0 = sqrt(E*E - mass*mass);

                     HepVector p4(4,0);

                     p4[0] = p0*cos(phi)/sqrt(1 + lambda*lambda);

                     p4[1] = p0*sin(phi)/sqrt(1 + lambda*lambda);

                     p4[2] = p0*lambda/sqrt(1 + lambda*lambda);

                     p4[3] = sqrt(p0*p0 + mass*mass);

                     return p4;

                     break;

                 }

        case 4 : {

                     double phi = m_p.sub(pa, pa)[0];

                     double lambda = m_p.sub(pa+1, pa+1)[0];

                     double mass = m_q.sub(pb, pb)[0];

                     double E = m_q.sub(pb+1, pb+1)[0];

                     double p0 = sqrt(E*E - mass*mass);

                     HepVector p4(4,0);

                     p4[0] = p0*cos(phi)/sqrt(1 + lambda*lambda);

                     p4[1] = p0*sin(phi)/sqrt(1 + lambda*lambda);

                     p4[2] = p0*lambda/sqrt(1 + lambda*lambda);

                     p4[3] = sqrt(p0*p0 + mass*mass);

                     return p4;

                     break;

                 }

        case 5 : {

                     double phi = m_p.sub(pa, pa)[0];

                     double lambda = m_p.sub(pa+1, pa+1)[0];

                     double mass = m_p.sub(pa+2, pa+2)[0];

                     double p0 = m_q.sub(pb, pb)[0];

                     HepVector p4(4,0);

                     p4[0] = p0*cos(phi)/sqrt(1 + lambda*lambda);

                     p4[1] = p0*sin(phi)/sqrt(1 + lambda*lambda);

                     p4[2] = p0*lambda/sqrt(1 + lambda*lambda);

                     p4[3] = sqrt(p0*p0 + mass*mass);

                     return p4;

                     break;

                 }

        case 6 : {

                     double x = m_p.sub(pa, pa)[0] - m_q.sub(pb, pb)[0];

                     double y = m_p.sub(pa+1, pa+1)[0] - m_q.sub(pb+1, pb+1)[0];

                     double z = m_p.sub(pa+2, pa+2)[0] - m_q.sub(pb+2, pb+2)[0];

                     double p0 = m_p.sub(pa+3, pa+3)[0];

                     double R = sqrt(x*x + y*y + z*z);

                     HepVector p4(4,0);

                     p4[0] = p0*x/R;

                     p4[1] = p0*y/R;

                     p4[2] = p0*z/R;

                     p4[3] = p0;

                     return p4;

                     break;

                 }

        case 7 : {

                     double mass = m_p.sub(pa+3, pa+3)[0];

                     HepVector p4(4,0);

                     p4[0] = m_p.sub(pa,pa)[0];

                     p4[1] = m_p.sub(pa+1, pa+1)[0];

                     p4[2] = m_p.sub(pa+2, pa+2)[0];

                     p4[3] = sqrt(p4[0]*p4[0] + p4[1]*p4[1] + p4[2]*p4[2] + mass * mass);

                     return p4;

                     break;

                 }

    }

}


HepVector KalmanKinematicFit::pOrigin(int n) const {

    int pa = mappositionA()[n] + 1;

    int pb = mappositionB()[n] + 1;

    int ptype = mapkinematic()[n];

    switch(ptype) {

        case 0 : {

                     double mass = m_p0.sub(pa+3, pa+3)[0];

                     HepVector p4(4,0);

                     p4[0] = m_p0.sub(pa,pa)[0];

                     p4[1] = m_p0.sub(pa+1, pa+1)[0];

                     p4[2] = m_p0.sub(pa+2, pa+2)[0];

                     p4[3] = sqrt(p4[0]*p4[0] + p4[1]*p4[1] + p4[2]*p4[2] + mass * mass);

                     return p4;

                     break;

                 }

        case 1 : {

                     double phi = m_p0.sub(pa, pa)[0];

                     double lambda = m_p0.sub(pa+1, pa+1)[0];

                     double mass = m_p0.sub(pa+2, pa+2)[0];

                     double E = m_p0.sub(pa+3, pa+3)[0];

                     double p0 = sqrt(E*E - mass*mass);

                     HepVector p4(4,0);

                     p4[0] = p0*cos(phi)/sqrt(1 + lambda*lambda);

                     p4[1] = p0*sin(phi)/sqrt(1 + lambda*lambda);

                     p4[2] = p0*lambda/sqrt(1 + lambda*lambda);

                     p4[3] = sqrt(p0*p0 + mass*mass);

                     return p4;

                     break;

                 }

        case 2 : {

                     return m_q0.sub(pb, pb+3);

                     break;

                 }

        case 3 : {

                     double mass = (m_p0.sub(pa, pa))[0];

                     double phi = m_q0.sub(pb, pb)[0];

                     double lambda = m_q0.sub(pb+1, pb+1)[0];

                     double E = m_q0.sub(pb+2, pb+2)[0];

                     double p0 = sqrt(E*E - mass*mass);

                     HepVector p4(4,0);

                     p4[0] = p0*cos(phi)/sqrt(1 + lambda*lambda);

                     p4[1] = p0*sin(phi)/sqrt(1 + lambda*lambda);

                     p4[2] = p0*lambda/sqrt(1 + lambda*lambda);

                     p4[3] = sqrt(p0*p0 + mass*mass);

                     return p4;

                     break;

                 }

        case 4 : {

                     double phi = m_p0.sub(pa, pa)[0];

                     double lambda = m_p0.sub(pa+1, pa+1)[0];

                     double mass = m_q0.sub(pb, pb)[0];

                     double E = m_q0.sub(pb+1, pb+1)[0];

                     double p0 = sqrt(E*E - mass*mass);

                     HepVector p4(4,0);

                     p4[0] = p0*cos(phi)/sqrt(1 + lambda*lambda);

                     p4[1] = p0*sin(phi)/sqrt(1 + lambda*lambda);

                     p4[2] = p0*lambda/sqrt(1 + lambda*lambda);

                     p4[3] = sqrt(p0*p0 + mass*mass);

                     return p4;

                     break;

                 }

        case 5 : {

                     double phi = m_p0.sub(pa, pa)[0];

                     double lambda = m_p0.sub(pa+1, pa+1)[0];

                     double mass = m_p0.sub(pa+2, pa+2)[0];

                     double p0 = m_q0.sub(pb, pb)[0];

                     HepVector p4(4,0);

                     p4[0] = p0*cos(phi)/sqrt(1 + lambda*lambda);

                     p4[1] = p0*sin(phi)/sqrt(1 + lambda*lambda);

                     p4[2] = p0*lambda/sqrt(1 + lambda*lambda);

                     p4[3] = sqrt(p0*p0 + mass*mass);

                     return p4;

                     break;

                 }

        case 6 : {

                     double x = m_p0.sub(pa, pa)[0] - m_q0.sub(pb, pb)[0];

                     double y = m_p0.sub(pa+1, pa+1)[0] - m_q0.sub(pb+1, pb+1)[0];

                     double z = m_p0.sub(pa+2, pa+2)[0] - m_q0.sub(pb+2, pb+2)[0];

                     double p0 = m_p0.sub(pa+3, pa+3)[0];

                     double R = sqrt(x*x + y*y + z*z);

                     HepVector p4(4,0);

                     p4[0] = p0*x/R;

                     p4[1] = p0*y/R;

                     p4[2] = p0*z/R;

                     p4[3] = p0;

                     return p4;

                     break;

                 }

        case 7 : {

                     double mass = m_p0.sub(pa+3, pa+3)[0];

                     HepVector p4(4,0);

                     p4[0] = m_p0.sub(pa,pa)[0];

                     p4[1] = m_p0.sub(pa+1, pa+1)[0];

                     p4[2] = m_p0.sub(pa+2, pa+2)[0];

                     p4[3] = sqrt(p4[0]*p4[0] + p4[1]*p4[1] + p4[2]*p4[2] + mass * mass);

                     return p4;

                     break;

                 }

    }

}


HepSymMatrix KalmanKinematicFit::getCOrigin(int n) const {

    int pa = mappositionA()[n] + 1;

    int pb = mappositionB()[n] + 1;

    int ptype = mapkinematic()[n];

    switch(ptype) {

        case 0 : {

                     return m_C0.sub(pa, pa+NTRKPAR-1);

                     break;

                 }

        case 1 : {

                     return m_C0.sub(pa, pa+NTRKPAR-1);

                     break;

                 }

        case 3 : {

                     return m_C0.sub(pa, pa);

                     break;

                 }

        case 4 : {

                     return m_C0.sub(pa, pa+1);

                     break;

                 }

        case 5 : {

                     return m_C0.sub(pa, pa+2);

                     break;

                 }

        case 7 : {

                     return m_C0.sub(pa, pa+NTRKPAR-1);

                     break;

                 }


    }

}


HepSymMatrix KalmanKinematicFit::getCInfit(int n) const {

    int pa = mappositionA()[n] + 1;

    int pb = mappositionB()[n] + 1;

    int ptype = mapkinematic()[n];

    switch(ptype) {

        case 0 : {

                     return m_C.sub(pa, pa+NTRKPAR-1);

                     break;

                 }

        case 1 : {

                     return m_C.sub(pa, pa+NTRKPAR-1);

                     break;

                 }

        case 3 : {

                     return m_C.sub(pa, pa);

                     break;

                 }

        case 4 : {

                     return m_C.sub(pa, pa+1);

                     break;

                 }

        case 5 : {

                     return m_C.sub(pa, pa+2);

                     break;

                 }

        case 7 : {

                     return m_C.sub(pa, pa+NTRKPAR-1);

                     break;

                 }

    }

}


void KalmanKinematicFit::updateConstraints(KinematicConstraints k ) {

    KinematicConstraints kc = k;


    int type = kc.Type();

    switch(type) {

        case  Resonance: {

                             //

                             //  E^2 - px^2 - py^2 - pz^2 = mres^2

                             //

                             double mres = kc.mres();

                             HepLorentzVector pmis;

                             for(unsigned int j = 0; j< (kc.Ltrk()).size(); j++){

                                 int n = (kc.Ltrk())[j];

                                 pmis = pmis + p4Infit(n);

                             }

                             for(unsigned int j = 0; j< (kc.Ltrk()).size(); j++){

                                 int n = (kc.Ltrk())[j];

                                 double lambda = p4Infit(n).pz()/p4Infit(n).perp();

                                 double a1 = 1 + lambda*lambda;

                                 int pa = mappositionA()[n] + 1;

                                 int pb = mappositionB()[n] + 1;

                                 int ptype = mapkinematic()[n];

                                 switch(ptype) {

                                     case 0 :{

                                                 HepMatrix ta(1, NTRKPAR, 0);

                                                 ta[0][0] = -2 * pmis.px() + 2 * pmis.e() * p4Infit(n).px() / p4Infit(n).e();

                                                 ta[0][1] = -2 * pmis.py() + 2 * pmis.e() * p4Infit(n).py() / p4Infit(n).e();

                                                 ta[0][2] = -2 * pmis.pz() + 2 * pmis.e() * p4Infit(n).pz() / p4Infit(n).e();

                                                 ta[0][3] = 2 * pmis.e() * p4Infit(n).m() / p4Infit(n).e();

                                                 setA(m_nc,pa,ta);

                                                 setAT(pa, m_nc, ta.T());

                                                 break;

                                             }

                                     case 1 :  {

                                                   HepMatrix ta(1, NTRKPAR, 0);

                                                   double a1 = lambda * lambda + 1;

                                                   ta[0][0] = 2 * pmis.px() * p4Infit(n).py() - 2 * pmis.py() * p4Infit(n).px();

                                                   ta[0][1] = 2 * pmis.px() * p4Infit(n).px() * lambda/sqrt(a1) + 2 * pmis.py() * (p4Infit(n)).py() * lambda/sqrt(a1) - 2 * pmis.pz() * (p4Infit(n)).pz() /(sqrt(a1) * lambda);

                                                   ta[0][2] =  2 * pmis.px() * (p4Infit(n)).px() * p4Infit(n).m() /((p4Infit(n)).rho() * p4Infit(n).rho()) + 2 * pmis.py() * (p4Infit(n)).py() * p4Infit(n).m()/((p4Infit(n)).rho() * p4Infit(n).rho())+ 2 * pmis.pz() * (p4Infit(n)).pz() * p4Infit(n).m()/((p4Infit(n)).rho() * p4Infit(n).rho());

                                                   ta[0][3] = 2 * pmis.e()  - 2 * pmis.px() * (p4Infit(n)).px() * p4Infit(n).e() /((p4Infit(n)).rho() * p4Infit(n).rho())- 2 * pmis.py() * (p4Infit(n)).py() * p4Infit(n).e()/((p4Infit(n)).rho() * p4Infit(n).rho())- 2 * pmis.pz() * (p4Infit(n)).pz() * p4Infit(n).e()/((p4Infit(n)).rho() * p4Infit(n).rho());

                                                   setA(m_nc,pa,ta);

                                                   setAT(pa, m_nc, ta.T());

                                                   break;

                                               }

                                     case 2 :  {

                                                   HepMatrix tb(1, 4, 0);

                                                   tb[0][0] = -2 * pmis.px();

                                                   tb[0][1] = -2 * pmis.py();

                                                   tb[0][2] = -2 * pmis.pz();

                                                   tb[0][3] = 2 * pmis.e();

                                                   setB(m_nc,pb,tb);

                                                   setBT(pb,m_nc,tb.T());

                                                   break;

                                               }

                                     case 3 :  {

                                                   HepMatrix ta(1, 1, 0);

                                                   double a1 = lambda * lambda + 1;

                                                   ta[0][0] =  2 * pmis.px() * (p4Infit(n)).px() * p4Infit(n).m() /((p4Infit(n)).rho() * p4Infit(n).rho()) + 2 * pmis.py() * (p4Infit(n)).py() * p4Infit(n).m()/((p4Infit(n)).rho() * p4Infit(n).rho())+ 2 * pmis.pz() * (p4Infit(n)).pz() * p4Infit(n).m()/((p4Infit(n)).rho() * p4Infit(n).rho());

                                                   setA(m_nc,pa,ta);

                                                   setAT(pa, m_nc, ta.T());

                                                   HepMatrix tb(1, 3, 0);

                                                   tb[0][0] = 2 * pmis.px() * p4Infit(n).py() - 2 * pmis.py() * p4Infit(n).px();

                                                   tb[0][1] = 2 * pmis.px() * p4Infit(n).px() * lambda/sqrt(a1) + 2 * pmis.py() * (p4Infit(n)).py() * lambda/sqrt(a1) - 2 * pmis.pz() * (p4Infit(n)).pz() /(sqrt(a1) * lambda);

                                                   tb[0][2] = 2 * pmis.e()  - 2 * pmis.px() * (p4Infit(n)).px() * p4Infit(n).e() /((p4Infit(n)).rho() * p4Infit(n).rho())- 2 * pmis.py() * (p4Infit(n)).py() * p4Infit(n).e()/((p4Infit(n)).rho() * p4Infit(n).rho())- 2 * pmis.pz() * (p4Infit(n)).pz() * p4Infit(n).e()/((p4Infit(n)).rho() * p4Infit(n).rho());

                                                   setB(m_nc,pb,tb);

                                                   setBT(pb,m_nc,tb.T());

                                                   break;

                                               }

                                     case 4 :  {

                                                   HepMatrix ta(1, 2, 0);

                                                   double a1 = lambda * lambda + 1;

                                                   ta[0][0] = 2 * pmis.px() * p4Infit(n).py() - 2 * pmis.py() * p4Infit(n).px();

                                                   ta[0][1] = 2 * pmis.px() * p4Infit(n).px() * lambda/sqrt(a1) + 2 * pmis.py() * (p4Infit(n)).py() * lambda/sqrt(a1) - 2 * pmis.pz() * (p4Infit(n)).pz() /(sqrt(a1) * lambda);

                                                   setA(m_nc,pa,ta);

                                                   setAT(pa, m_nc, ta.T());


                                                   HepMatrix tb(1, 2, 0);

                                                   tb[0][0] =  2 * pmis.px() * (p4Infit(n)).px() * p4Infit(n).m() /((p4Infit(n)).rho() * p4Infit(n).rho()) + 2 * pmis.py() * (p4Infit(n)).py() * p4Infit(n).m()/((p4Infit(n)).rho() * p4Infit(n).rho())+ 2 * pmis.pz() * (p4Infit(n)).pz() * p4Infit(n).m()/((p4Infit(n)).rho() * p4Infit(n).rho());

                                                   tb[0][1] = 2 * pmis.e()  - 2 * pmis.px() * (p4Infit(n)).px() * p4Infit(n).e() /((p4Infit(n)).rho() * p4Infit(n).rho())- 2 * pmis.py() * (p4Infit(n)).py() * p4Infit(n).e()/((p4Infit(n)).rho() * p4Infit(n).rho())- 2 * pmis.pz() * (p4Infit(n)).pz() * p4Infit(n).e()/((p4Infit(n)).rho() * p4Infit(n).rho());

                                                   setB(m_nc,pb,tb);

                                                   setBT(pb, m_nc, tb.T());

                                                   break;

                                               }

                                     case 5 :  {

                                                   HepMatrix ta(1, 3, 0);

                                                   ta[0][0] = 2 * pmis.px() * p4Infit(n).py() - 2 * pmis.py() * p4Infit(n).px();

                                                   ta[0][1] = 2 * pmis.px() * p4Infit(n).px() * lambda/sqrt(a1)+ 2 * pmis.py() * (p4Infit(n)).py() * lambda/sqrt(a1) - 2 * pmis.pz() * (p4Infit(n)).pz() /(sqrt(a1) * lambda);

                                                   ta[0][2] = 2 * pmis.e() * (p4Infit(n)).m()/(p4Infit(n)).e();

                                                   setA(m_nc,pa,ta);

                                                   setAT(pa, m_nc, ta.T());

                                                   HepMatrix tb(1, 1, 0);

                                                   tb[0][0] = 2 * pmis.e() * (p4Infit(n)).rho()/(p4Infit(n)).e() - 2 * pmis.px() * (p4Infit(n)).px()/(p4Infit(n)).rho() - 2 * pmis.py() * (p4Infit(n)).py()/(p4Infit(n)).rho() - 2 * pmis.pz() * (p4Infit(n)).pz()/(p4Infit(n)).rho();

                                                   setB(m_nc,pb,tb);

                                                   setBT(pb, m_nc, tb.T());

                                                   break;

                                               }

                                     case 7 :{

                                                 HepMatrix ta(1, NTRKPAR, 0);

                                                 ta[0][0] = -2 * pmis.px() + 2 * pmis.e() * p4Infit(n).px() / p4Infit(n).e();

                                                 ta[0][1] = -2 * pmis.py() + 2 * pmis.e() * p4Infit(n).py() / p4Infit(n).e();

                                                 ta[0][2] = -2 * pmis.pz() + 2 * pmis.e() * p4Infit(n).pz() / p4Infit(n).e();

                                                 ta[0][3] = 2 * pmis.e() * p4Infit(n).m() / p4Infit(n).e();

                                                 setA(m_nc,pa,ta);

                                                 setAT(pa, m_nc, ta.T());

                                                 break;

                                             }

                                 }

                             }


                             HepVector dc(1, 0);

                             dc[0] = pmis.m2() - mres * mres;

                             m_G[m_nc] = dc[0];

                             m_nc+=1;


                             break;

                         }

        case TotalEnergy: {

                              //

                              //  E - Etot = 0

                              //

                              double etot = kc.etot();

                              HepLorentzVector pmis;

                              for(unsigned int j = 0; j < (kc.Ltrk()).size(); j++){

                                  int n = (kc.Ltrk())[j];

                                  pmis = pmis + p4Infit(n);

                              }


                              for(unsigned int j = 0; j < (kc.Ltrk()).size(); j++) {

                                  int n = (kc.Ltrk())[j];

                                  int pa = mappositionA()[n] + 1;

                                  int pb = mappositionB()[n] + 1;

                                  int ptype = mapkinematic()[n];

                                  switch(ptype) {

                                      case 0 :{

                                                  HepMatrix ta(1, NTRKPAR, 0);

                                                  ta[0][0] = p4Infit(n).px()/p4Infit(n).e();

                                                  ta[0][1] = p4Infit(n).py()/p4Infit(n).e();

                                                  ta[0][2] = p4Infit(n).pz()/p4Infit(n).e();

                                                  ta[0][3] = p4Infit(n).m()/p4Infit(n).e();

                                                  setA(m_nc,pa,ta);

                                                  setAT(pa, m_nc, ta.T());

                                                  break;

                                              }

                                      case 1: {

                                                  HepMatrix ta(1, NTRKPAR, 0);

                                                  ta[0][3] = 1.0;

                                                  setA(m_nc,pa,ta);

                                                  setAT(pa, m_nc, ta.T());

                                                  break;

                                              }

                                      case 2: {

                                                  HepMatrix tb(1, 4, 0);

                                                  tb[0][3] = 1.0;

                                                  setA(m_nc,pb,tb);

                                                  setAT(pb, m_nc, tb.T());

                                                  break;

                                              }

                                      case 3: {

                                                  HepMatrix ta(1, 1, 0);

                                                  ta[0][0] = p4Infit(n).m()/p4Infit(n).e();

                                                  setA(m_nc,pa,ta);

                                                  setAT(pa, m_nc, ta.T());


                                                  HepMatrix tb(1, 3, 0);

                                                  setB(m_nc,pb,tb);

                                                  setBT(pb, m_nc, tb.T());

                                                  break;

                                              }

                                      case 4: {

                                                  HepMatrix ta(1, 2, 0);

                                                  setA(m_nc,pa,ta);

                                                  setAT(pa, m_nc, ta.T());


                                                  HepMatrix tb(1, 2, 0);

                                                  tb[0][0] = 0.0;

                                                  tb[0][1] = 1.0;

                                                  //   tb[0][0] = p4Infit(n).m()/p4Infit(n).e();

                                                  //   tb[0][1] = p4Infit(n).rho()/p4Infit(n).e();

                                                  setB(m_nc,pb,tb);

                                                  setBT(pb, m_nc, tb.T());

                                                  break;

                                              }

                                      case 5: {

                                                  HepMatrix ta(1, 3, 0);

                                                  ta[0][2] = p4Infit(n).m()/p4Infit(n).e();

                                                  setA(m_nc,pa,ta);

                                                  setAT(pa, m_nc, ta.T());


                                                  HepMatrix tb(1, 1, 0);

                                                  tb[0][0] = p4Infit(n).rho()/p4Infit(n).e();

                                                  setB(m_nc,pb,tb);

                                                  setBT(pb, m_nc, tb.T());

                                                  break;

                                              }

                                      case 7 :{

                                                  HepMatrix ta(1, NTRKPAR, 0);

                                                  ta[0][0] = p4Infit(n).px()/p4Infit(n).e();

                                                  ta[0][1] = p4Infit(n).py()/p4Infit(n).e();

                                                  ta[0][2] = p4Infit(n).pz()/p4Infit(n).e();

                                                  ta[0][3] = p4Infit(n).m()/p4Infit(n).e();

                                                  setA(m_nc,pa,ta);

                                                  setAT(pa, m_nc, ta.T());

                                                  break;

                                              }

                                  }


                              }


                              HepVector dc(1, 0);

                              dc[0] = pmis.e() - etot;

                              m_G[m_nc] = dc[0];

                              m_nc+=1;

                              break;

                          }

        case TotalMomentum: {

                                //

                                //  sqrt(px^2+py^2+pz^2) - ptot = 0

                                //

                                double ptot = kc.ptot();

                                HepLorentzVector pmis;

                                for(unsigned int j = 0; j< (kc.Ltrk()).size(); j++){

                                    int n = (kc.Ltrk())[j];

                                    pmis = pmis + p4Infit(n);

                                }


                                for(unsigned int j = 0; j < (kc.Ltrk()).size(); j++) {

                                    int n = (kc.Ltrk())[j];

                                    int pa = mappositionA()[n] + 1;

                                    int pb = mappositionB()[n] + 1;

                                    int ptype = mapkinematic()[n];

                                    double lambda = p4Infit(n).pz()/p4Infit(n).perp();

                                    switch(ptype) {

                                        case 0 : {

                                                     HepMatrix ta(1, NTRKPAR, 0);

                                                     ta[0][0] = pmis.px()/pmis.rho();

                                                     ta[0][1] = pmis.py()/pmis.rho();

                                                     ta[0][2] = pmis.pz()/pmis.rho();

                                                     setA(m_nc,pa,ta);

                                                     setAT(pa, m_nc, ta.T());

                                                     break;

                                                 }

                                        case 1 : {

                                                     HepMatrix ta(1, NTRKPAR, 0);

                                                     ta[0][0] = - (pmis.px()/pmis.rho()) * p4Infit(n).py() + (pmis.px()/pmis.rho())*p4Infit(n).px();

                                                     ta[0][1] = - (pmis.px()/pmis.rho()) * p4Infit(n).px() * (lambda/(1 + lambda*lambda)) - (pmis.py()/pmis.rho()) * p4Infit(n).py() * (lambda/(1 + lambda*lambda)) + (pmis.pz()/pmis.rho()) * p4Infit(n).pz() * (1/(lambda * (1 + lambda*lambda)));

                                                     ta[0][2] =  -((pmis.px()/pmis.rho()) * p4Infit(n).m()/(p4Infit(n).rho()*p4Infit(n).rho())) * (p4Infit(n).px() + p4Infit(n).py() +p4Infit(n).pz());

                                                     ta[0][3] = ((pmis.px()/pmis.rho()) * p4Infit(n).e()/(p4Infit(n).rho()*p4Infit(n).rho())) * (p4Infit(n).px() + p4Infit(n).py() +

                                                             p4Infit(n).pz());


                                                     setA(m_nc,pa,ta);

                                                     setAT(pa, m_nc, ta.T());

                                                     break;

                                                 }

                                        case 2 : {

                                                     HepMatrix tb(1, 4, 0);

                                                     tb[0][0] = pmis.px()/pmis.rho();

                                                     tb[0][1] = pmis.py()/pmis.rho();

                                                     tb[0][2] = pmis.pz()/pmis.rho();

                                                     setB(m_nc,pb,tb);

                                                     setBT(pb, m_nc, tb.T());

                                                     break;

                                                 }

                                        case 3 : {

                                                     HepMatrix ta(1, 1, 0);

                                                     setA(m_nc,pa,ta);

                                                     setAT(pa, m_nc, ta.T());

                                                     HepMatrix tb(1, 3, 0);

                                                     tb[0][0] = pmis.px()/pmis.rho();

                                                     tb[0][1] = pmis.py()/pmis.rho();

                                                     tb[0][2] = pmis.pz()/pmis.rho();

                                                     setB(m_nc,pb,tb);

                                                     setBT(pb, m_nc, tb.T());

                                                     break;

                                                 }

                                        case 4 : {

                                                     HepMatrix ta(1, 2, 0);

                                                     ta[0][0] = - (pmis.px()/pmis.rho()) * p4Infit(n).py() + (pmis.px()/pmis.rho())*p4Infit(n).px();

                                                     ta[0][1] = - (pmis.px()/pmis.rho()) * p4Infit(n).px() * (lambda/(1 + lambda*lambda)) - (pmis.py()/pmis.rho()) * p4Infit(n).py() * (lambda/(1 + lambda*lambda)) + (pmis.pz()/pmis.rho()) * p4Infit(n).pz() * (1/(lambda * (1 + lambda*lambda)));

                                                     setA(m_nc,pa,ta);

                                                     setAT(pa, m_nc, ta.T());


                                                     HepMatrix tb(1, 2, 0);

                                                     tb[0][0] =  -((pmis.px()/pmis.rho()) * p4Infit(n).m()/(p4Infit(n).rho()*p4Infit(n).rho())) * (p4Infit(n).px() + p4Infit(n).py() +p4Infit(n).pz());

                                                     tb[0][1] = ((pmis.px()/pmis.rho()) * p4Infit(n).e()/(p4Infit(n).rho()*p4Infit(n).rho())) * (p4Infit(n).px() + p4Infit(n).py() +

                                                             p4Infit(n).pz());

                                                     //             tb[0][1] =  (pmis.px()/pmis.rho()) * (p4Infit(n).px()/p4Infit(n).rho()) + (pmis.py()/pmis.rho()) * (p4Infit(n).py()/p4Infit(n).rho()) + (pmis.pz()/pmis.rho()) * (p4Infit(n).pz()/p4Infit(n).rho());

                                                     setB(m_nc,pb,tb);

                                                     setBT(pb, m_nc, tb.T());

                                                     break;

                                                 }

                                        case 5 : {

                                                     HepMatrix ta(1, 3, 0);

                                                     ta[0][0] = - (pmis.px()/pmis.rho()) * p4Infit(n).py() + (pmis.px()/pmis.rho())*p4Infit(n).px();

                                                     ta[0][1] = - (pmis.px()/pmis.rho()) * p4Infit(n).px() * (lambda/(1 + lambda*lambda)) - (pmis.py()/pmis.rho()) * p4Infit(n).py() * (lambda/(1 + lambda*lambda)) + (pmis.pz()/pmis.rho()) * p4Infit(n).pz() * (1/(lambda * (1 + lambda*lambda)));

                                                     setA(m_nc,pa,ta);

                                                     setAT(pa, m_nc, ta.T());


                                                     HepMatrix tb(1, 1, 0);

                                                     tb[0][0] =  (pmis.px()/pmis.rho()) * (p4Infit(n).px()/p4Infit(n).rho()) + (pmis.py()/pmis.rho()) * (p4Infit(n).py()/p4Infit(n).rho()) + (pmis.pz()/pmis.rho()) * (p4Infit(n).pz()/p4Infit(n).rho());

                                                     setB(m_nc,pb,tb);

                                                     setBT(pb, m_nc, tb.T());

                                                     break;

                                                 }

                                        case 7 : {

                                                     HepMatrix ta(1, NTRKPAR, 0);

                                                     ta[0][0] = pmis.px()/pmis.rho();

                                                     ta[0][1] = pmis.py()/pmis.rho();

                                                     ta[0][2] = pmis.pz()/pmis.rho();

                                                     setA(m_nc,pa,ta);

                                                     setAT(pa, m_nc, ta.T());

                                                     break;

                                                 }

                                    }

                                }


                                HepVector dc(1, 0);

                                dc[0] = pmis.rho() - ptot;

                                m_G[m_nc] = dc[0];

                                m_nc+=1;

                                break;

                            }


        case ThreeMomentum: {

                                //

                                //  px - p3x = 0

                                //  py - p3y = 0

                                //  pz - p3z = 0

                                //

                                Hep3Vector p3 = kc.p3();

                                HepLorentzVector pmis;

                                for(unsigned int j = 0; j< (kc.Ltrk()).size(); j++){

                                    int n = (kc.Ltrk())[j];

                                    pmis = pmis + p4Infit(n);

                                }

                                for(unsigned int j = 0; j < (kc.Ltrk()).size(); j++) {

                                    int n = (kc.Ltrk())[j];

                                    int pa = mappositionA()[n] + 1;

                                    int pb = mappositionB()[n] + 1;

                                    int ptype = mapkinematic()[n];

                                    double lambda = p4Infit(n).pz()/p4Infit(n).perp();

                                    switch(ptype) {

                                        case 0 : {

                                                     HepMatrix ta(kc.nc(), NTRKPAR, 0);

                                                     ta[0][0] = 1.0;

                                                     ta[1][1] = 1.0;

                                                     ta[2][2] = 1.0;

                                                     setA(m_nc, pa, ta);

                                                     setAT(pa, m_nc, ta.T());

                                                     break;

                                                 }

                                        case 1 : {

                                                     HepMatrix ta(kc.nc(), NTRKPAR, 0);

                                                     ta[0][0] = -p4Infit(n).py();

                                                     ta[0][1] = -p4Infit(n).px()*(lambda/sqrt(1 + lambda*lambda));

                                                     ta[0][2] = -p4Infit(n).m()*p4Infit(n).px()/(p4Infit(n).rho()*p4Infit(n).rho());

                                                     ta[0][3] = p4Infit(n).e()*p4Infit(n).px()/(p4Infit(n).rho()*p4Infit(n).rho());

                                                     ta[1][0] = p4Infit(n).px();

                                                     ta[1][1] = -p4Infit(n).py()*(lambda/sqrt(1 + lambda*lambda));

                                                     ta[1][2] = -p4Infit(n).m()*p4Infit(n).py()/(p4Infit(n).rho()*p4Infit(n).rho());

                                                     ta[1][3] = p4Infit(n).e()*p4Infit(n).py()/(p4Infit(n).rho()*p4Infit(n).rho());

                                                     ta[2][0] = 0;

                                                     ta[2][1] = p4Infit(n).pz()*(1/(lambda * (1 + lambda*lambda)));

                                                     ta[2][2] = -p4Infit(n).m()*p4Infit(n).pz()/(p4Infit(n).rho()*p4Infit(n).rho());

                                                     ta[2][3] = p4Infit(n).e()*p4Infit(n).pz()/(p4Infit(n).rho()*p4Infit(n).rho());

                                                     //             ta[0][0] = 1.0;

                                                     //             ta[1][1] = 1.0;

                                                     //             ta[2][2] = 1.0;

                                                     setA(m_nc, pa, ta);

                                                     setAT(pa, m_nc, ta.T());

                                                     break;

                                                 }

                                        case 2 : {

                                                     HepMatrix tb(kc.nc(), 4, 0);

                                                     tb[0][0] = 1.0;

                                                     tb[1][1] = 1.0;

                                                     tb[2][2] = 1.0;

                                                     setB(m_nc, pb, tb);

                                                     setBT(pb, m_nc, tb.T());

                                                     break;

                                                 }

                                        case 3 : {

                                                     HepMatrix ta(kc.nc(), 1, 0);

                                                     setA(m_nc, pa, ta);

                                                     setAT(pa, m_nc, ta.T());


                                                     HepMatrix tb(kc.nc(), 3, 0);

                                                     tb[0][0] = 1.0;

                                                     tb[1][1] = 1.0;

                                                     tb[2][2] = 1.0;

                                                     setB(m_nc, pb, tb);

                                                     setBT(pb, m_nc, tb.T());


                                                     break;

                                                 }

                                        case 4 : {

                                                     HepMatrix ta(kc.nc(), 2, 0);

                                                     ta[0][0] = -p4Infit(n).py();

                                                     ta[0][1] = -p4Infit(n).px()*(lambda/sqrt(1 + lambda*lambda));

                                                     ta[1][0] =  p4Infit(n).px();

                                                     ta[1][1] = -p4Infit(n).py()*(lambda/sqrt(1 + lambda*lambda));

                                                     ta[2][0] =  0;

                                                     ta[2][1] =  p4Infit(n).pz()*(1/(lambda * (1 + lambda*lambda)));

                                                     setA(m_nc, pa, ta);

                                                     setAT(pa, m_nc, ta.T());


                                                     HepMatrix tb(kc.nc(), 2, 0);

                                                     tb[0][1] = -p4Infit(n).m()*p4Infit(n).px()/(p4Infit(n).rho()*p4Infit(n).rho());

                                                     tb[1][1] = -p4Infit(n).m()*p4Infit(n).py()/(p4Infit(n).rho()*p4Infit(n).rho());

                                                     tb[2][1] = -p4Infit(n).m()*p4Infit(n).pz()/(p4Infit(n).rho()*p4Infit(n).rho());

                                                     setB(m_nc, pb, tb);

                                                     setBT(pb, m_nc, tb.T());

                                                     break;

                                                 }

                                        case 5 : {

                                                     HepMatrix ta(kc.nc(), 3, 0);

                                                     ta[0][0] = -p4Infit(n).py();

                                                     ta[0][1] = -p4Infit(n).px()*(lambda/sqrt(1 + lambda*lambda));

                                                     ta[1][0] =  p4Infit(n).px();

                                                     ta[1][1] = -p4Infit(n).py()*(lambda/sqrt(1 + lambda*lambda));

                                                     ta[2][0] =  0;

                                                     ta[2][1] =  p4Infit(n).pz()*(1/(lambda * (1 + lambda*lambda)));

                                                     setA(m_nc, pa, ta);

                                                     setAT(pa, m_nc, ta.T());


                                                     HepMatrix tb(kc.nc(), 1, 0);

                                                     tb[0][0] = p4Infit(n).px()/p4Infit(n).rho();

                                                     tb[1][0] = p4Infit(n).py()/p4Infit(n).rho();

                                                     tb[2][0] = p4Infit(n).pz()/p4Infit(n).rho();

                                                     setB(m_nc, pb, tb);

                                                     setBT(pb, m_nc, tb.T());

                                                     break;

                                                 }

                                        case 7 : {

                                                     HepMatrix ta(kc.nc(), NTRKPAR, 0);

                                                     ta[0][0] = 1.0;

                                                     ta[1][1] = 1.0;

                                                     ta[2][2] = 1.0;

                                                     setA(m_nc, pa, ta);

                                                     setAT(pa, m_nc, ta.T());

                                                     break;

                                                 }

                                    }

                                }

                                HepVector dc(kc.nc(), 0);

                                dc[0] = pmis.px() - p3.x();

                                dc[1] = pmis.py() - p3.y();

                                dc[2] = pmis.pz() - p3.z();

                                for(int i = 0; i < kc.nc(); i++) {

                                    m_G[m_nc+i] = dc[i];

                                }


                                m_nc += 3;


                                break;

                            }

        case EqualMass: {

                            //

                            //  (E_1 ^2 - Px_1 ^2 - Py_1 ^2 - Pz_1 ^2) - (E_2 ^2 - Px_2 ^2 - Py_2 ^2 - Pz_2 ^2) = 0

                            //


                            int isiz = (kc.numEqual())[0];

                            HepLorentzVector pmis1, pmis2;

                            for(int n = 0; n < isiz; n++) {

                                int n1 = (kc.Ltrk())[n];

                                pmis1 = pmis1 + p4Infit(n1);

                            }


                            int jsiz = (kc.numEqual())[1];

                            for(int n = 0; n < jsiz; n++){

                                int n2 = (kc.Ltrk())[n+isiz];

                                pmis2 = pmis2 + p4Infit(n2);

                            }


                            for(int i = 0; i < isiz; i++) {

                                int n1 = (kc.Ltrk())[i];

                                double lambda = p4Infit(n1).pz()/p4Infit(n1).perp();

                                int pa = mappositionA()[n1] + 1;

                                int pb = mappositionB()[n1] + 1;

                                int ptype = mapkinematic()[n1];

                                switch(ptype) {

                                    case 0: {

                                                HepMatrix ta(1, NTRKPAR, 0);

                                                ta[0][0] = -2 * pmis1.px() + 2 * pmis1.e() * p4Infit(n1).px() / p4Infit(n1).e();

                                                ta[0][1] = -2 * pmis1.py() + 2 * pmis1.e() * p4Infit(n1).py() / p4Infit(n1).e();

                                                ta[0][2] = -2 * pmis1.pz() + 2 * pmis1.e() * p4Infit(n1).pz() / p4Infit(n1).e();

                                                ta[0][3] = 2 * pmis1.e() *  p4Infit(n1).m() / p4Infit(n1).e();

                                                setA(m_nc,pa,ta);

                                                setAT(pa, m_nc, ta.T());

                                                break;

                                            }

                                    case 1 :  {

                                                  HepMatrix ta(1, NTRKPAR, 0);

                                                  double a1 = lambda * lambda + 1;

                                                  ta[0][0] = 2 * pmis1.px() * p4Infit(n1).py() - 2 * pmis1.py() * p4Infit(n1).px();

                                                  ta[0][1] = 2 * pmis1.px() * p4Infit(n1).px() * lambda/sqrt(a1) + 2 * pmis1.py() * (p4Infit(n1)).py() * lambda/sqrt(a1) - 2 * pmis1.pz() * (p4Infit(n1)).pz() /(sqrt(a1) * lambda);

                                                  ta[0][2] = 2 * pmis1.px() * (p4Infit(n1)).px() * p4Infit(n1).m() /((p4Infit(n1)).rho() * p4Infit(n1).rho()) + 2 * pmis1.py() * (p4Infit(n1)).py() * p4Infit(n1).m()/((p4Infit(n1)).rho() * p4Infit(n1).rho())+ 2 * pmis1.pz() * (p4Infit(n1)).pz() * p4Infit(n1).m()/((p4Infit(n1)).rho() * p4Infit(n1).rho());

                                                  ta[0][3] = 2 * pmis1.e()  - 2 * pmis1.px() * (p4Infit(n1)).px() * p4Infit(n1).e() /((p4Infit(n1)).rho() * p4Infit(n1).rho())- 2 * pmis1.py() * (p4Infit(n1)).py() * p4Infit(n1).e()/((p4Infit(n1)).rho() * p4Infit(n1).rho())- 2 * pmis1.pz() * (p4Infit(n1)).pz() * p4Infit(n1).e()/((p4Infit(n1)).rho() * p4Infit(n1).rho());

                                                  setA(m_nc,pa,ta);

                                                  setAT(pa, m_nc, ta.T());

                                                  break;

                                              }

                                    case 2 :  {

                                                  HepMatrix tb(1, 4, 0);

                                                  tb[0][0] = -2 * pmis1.px();

                                                  tb[0][1] = -2 * pmis1.py();

                                                  tb[0][2] = -2 * pmis1.pz();

                                                  tb[0][3] = 2 * pmis1.e();

                                                  setB(m_nc,pb,tb);

                                                  setBT(pb,m_nc,tb.T());

                                                  break;

                                              }

                                    case 3 :  {

                                                  HepMatrix ta(1, 1, 0);

                                                  ta[0][0] = 2 * pmis1.e() * (p4Infit(n1).m()/p4Infit(n1).e());

                                                  setA(m_nc,pa,ta);

                                                  setAT(pa, m_nc, ta.T());

                                                  HepMatrix tb(1, 3, 0);

                                                  tb[0][0] = -2 * pmis1.px();

                                                  tb[0][1] = -2 * pmis1.py();

                                                  tb[0][2] = -2 * pmis1.pz();

                                                  setB(m_nc,pb,tb);

                                                  setBT(pb,m_nc,tb.T());

                                                  break;

                                              }

                                    case 4 :  {

                                                  HepMatrix ta(1, 2, 0);

                                                  double a1 = lambda * lambda + 1;

                                                  ta[0][0] = 2 * pmis1.px() * p4Infit(n1).py() - 2 * pmis1.py() * p4Infit(n1).px();

                                                  ta[0][1] = 2 * pmis1.px() * p4Infit(n1).px() * lambda/sqrt(a1) + 2 * pmis1.py() * (p4Infit(n1)).py() * lambda/sqrt(a1) - 2 * pmis1.pz() * (p4Infit(n1)).pz() /(sqrt(a1) * lambda);

                                                  setA(m_nc,pa,ta);

                                                  setAT(pa, m_nc, ta.T());


                                                  HepMatrix tb(1, 2, 0);

                                                  tb[0][0] =  2 * pmis1.px() * (p4Infit(n1)).px() * p4Infit(n1).m() /((p4Infit(n1)).rho() * p4Infit(n1).rho()) + 2 * pmis1.py() * (p4Infit(n1)).py() * p4Infit(n1).m()/((p4Infit(n1)).rho() * p4Infit(n1).rho())+ 2 * pmis1.pz() * (p4Infit(n1)).pz() * p4Infit(n1).m()/((p4Infit(n1)).rho() * p4Infit(n1).rho());

                                                  tb[0][1] = 2 * pmis1.e()  - 2 * pmis1.px() * (p4Infit(n1)).px() * p4Infit(n1).e() /((p4Infit(n1)).rho() * p4Infit(n1).rho())- 2 * pmis1.py() * (p4Infit(n1)).py() * p4Infit(n1).e()/((p4Infit(n1)).rho() * p4Infit(n1).rho())- 2 * pmis1.pz() * (p4Infit(n1)).pz() * p4Infit(n1).e()/((p4Infit(n1)).rho() * p4Infit(n1).rho());

                                                  setB(m_nc,pb,tb);

                                                  setBT(pb, m_nc, tb.T());

                                                  break;

                                              }

                                    case 5 :  {

                                                  HepMatrix ta(1, 3, 0);

                                                  double a1 = lambda * lambda + 1;

                                                  ta[0][0] = 2 * pmis1.px() * p4Infit(n1).py() - 2 * pmis1.py() * p4Infit(n1).px();

                                                  ta[0][1] = 2 * pmis1.px() * p4Infit(n1).px() * lambda/sqrt(a1)+ 2 * pmis1.py() * (p4Infit(n1)).py() * lambda/sqrt(a1) - 2 * pmis1.pz() * (p4Infit(n1)).pz() /(sqrt(a1) * lambda);

                                                  ta[0][2] = 2 * pmis1.e() * (p4Infit(n1)).m()/(p4Infit(n1)).e();

                                                  setA(m_nc,pa,ta);

                                                  setAT(pa, m_nc, ta.T());

                                                  HepMatrix tb(1, 1, 0);

                                                  tb[0][0] = 2 * pmis1.e() * (p4Infit(n1)).rho()/(p4Infit(n1)).e() - 2 * pmis1.px() * (p4Infit(n1)).px()/(p4Infit(n1)).rho() - 2 * pmis1.py() * (p4Infit(n1)).py()/(p4Infit(n1)).rho() - 2 * pmis1.pz() * (p4Infit(n1)).pz()/(p4Infit(n1)).rho();

                                                  setB(m_nc,pb,tb);

                                                  setBT(pb, m_nc, tb.T());

                                                  break;

                                              }

                                    case 7: {

                                                HepMatrix ta(1, NTRKPAR, 0);

                                                ta[0][0] = -2 * pmis1.px() + 2 * pmis1.e() * p4Infit(n1).px() / p4Infit(n1).e();

                                                ta[0][1] = -2 * pmis1.py() + 2 * pmis1.e() * p4Infit(n1).py() / p4Infit(n1).e();

                                                ta[0][2] = -2 * pmis1.pz() + 2 * pmis1.e() * p4Infit(n1).pz() / p4Infit(n1).e();

                                                ta[0][3] = 2 * pmis1.e() *  p4Infit(n1).m() / p4Infit(n1).e();

                                                setA(m_nc,pa,ta);

                                                setAT(pa, m_nc, ta.T());

                                                break;

                                            }

                                }

                            }


                            for(int i = isiz; i < isiz+jsiz; i++) {

                                int n2 = (kc.Ltrk())[i];

                                double lambda = p4Infit(n2).pz()/p4Infit(n2).perp();

                                int pa = mappositionA()[n2] + 1;

                                int pb = mappositionB()[n2] + 1;

                                int ptype = mapkinematic()[n2];

                                switch(ptype) {

                                    case 0 : {

                                                 HepMatrix ta(1, NTRKPAR, 0);

                                                 ta[0][0] = -2 * pmis2.px() + 2 * pmis2.e() * p4Infit(n2).px() / p4Infit(n2).e();

                                                 ta[0][1] = -2 * pmis2.py() + 2 * pmis2.e() * p4Infit(n2).py() / p4Infit(n2).e();

                                                 ta[0][2] = -2 * pmis2.pz() + 2 * pmis2.e() * p4Infit(n2).pz() / p4Infit(n2).e();

                                                 ta[0][3] = 2 * pmis2.e() * p4Infit(n2).m() / p4Infit(n2).e();

                                                 setA(m_nc,pa,-ta);

                                                 setAT(pa, m_nc, -ta.T());

                                                 break;

                                             }

                                    case 1 :  {

                                                  HepMatrix ta(1, NTRKPAR, 0);

                                                  double a1 = lambda * lambda + 1;

                                                  ta[0][0] = 2 * pmis2.px() * p4Infit(n2).py() - 2 * pmis2.py() * p4Infit(n2).px();

                                                  ta[0][1] = 2 * pmis2.px() * p4Infit(n2).px() * lambda/sqrt(a1) + 2 * pmis2.py() * (p4Infit(n2)).py() * lambda/sqrt(a1) - 2 * pmis2.pz() * (p4Infit(n2)).pz() /(sqrt(a1) * lambda);

                                                  ta[0][2] =  2 * pmis2.px() * (p4Infit(n2)).px() * p4Infit(n2).m() /((p4Infit(n2)).rho() * p4Infit(n2).rho()) + 2 * pmis2.py() * (p4Infit(n2)).py() * p4Infit(n2).m()/((p4Infit(n2)).rho() * p4Infit(n2).rho())+ 2 * pmis2.pz() * (p4Infit(n2)).pz() * p4Infit(n2).m()/((p4Infit(n2)).rho() * p4Infit(n2).rho());

                                                  ta[0][3] = 2 * pmis2.e()  - 2 * pmis2.px() * (p4Infit(n2)).px() * p4Infit(n2).e() /((p4Infit(n2)).rho() * p4Infit(n2).rho())- 2 * pmis2.py() * (p4Infit(n2)).py() * p4Infit(n2).e()/((p4Infit(n2)).rho() * p4Infit(n2).rho())- 2 * pmis2.pz() * (p4Infit(n2)).pz() * p4Infit(n2).e()/((p4Infit(n2)).rho() * p4Infit(n2).rho());

                                                  setA(m_nc,pa,-ta);

                                                  setAT(pa, m_nc, -ta.T());

                                                  break;

                                              }

                                    case 2 :  {

                                                  HepMatrix tb(1, 4, 0);

                                                  tb[0][0] = -2 * pmis2.px();

                                                  tb[0][1] = -2 * pmis2.py();

                                                  tb[0][2] = -2 * pmis2.pz();

                                                  tb[0][3] = 2 * pmis2.e();

                                                  setB(m_nc,pb,-tb);

                                                  setBT(pb,m_nc,-tb.T());

                                                  break;

                                              }

                                    case 3 :  {

                                                  HepMatrix ta(1, 1, 0);

                                                  ta[0][0] = 2 * pmis2.e() * (p4Infit(n2).m()/p4Infit(n2).e());

                                                  setA(m_nc,pa,-ta);

                                                  setAT(pa, m_nc, -ta.T());

                                                  HepMatrix tb(1, 3, 0);

                                                  tb[0][0] = -2 * pmis2.px();

                                                  tb[0][1] = -2 * pmis2.py();

                                                  tb[0][2] = -2 * pmis2.pz();

                                                  setB(m_nc,pb,-tb);

                                                  setBT(pb,m_nc,-tb.T());

                                                  break;

                                              }

                                    case 4 :  {

                                                  HepMatrix ta(1, 2, 0);

                                                  double a1 = lambda * lambda + 1;

                                                  ta[0][0] = 2 * pmis2.px() * p4Infit(n2).py() - 2 * pmis2.py() * p4Infit(n2).px();

                                                  ta[0][1] = 2 * pmis2.px() * p4Infit(n2).px() * lambda/sqrt(a1) + 2 * pmis2.py() * (p4Infit(n2)).py() * lambda/sqrt(a1) - 2 * pmis2.pz() * (p4Infit(n2)).pz() /(sqrt(a1) * lambda);

                                                  setA(m_nc,pa,-ta);

                                                  setAT(pa, m_nc, -ta.T());


                                                  HepMatrix tb(1, 2, 0);

                                                  tb[0][0] =  2 * pmis2.px() * (p4Infit(n2)).px() * p4Infit(n2).m() /((p4Infit(n2)).rho() * p4Infit(n2).rho()) + 2 * pmis2.py() * (p4Infit(n2)).py() * p4Infit(n2).m()/((p4Infit(n2)).rho() * p4Infit(n2).rho())+ 2 * pmis2.pz() * (p4Infit(n2)).pz() * p4Infit(n2).m()/((p4Infit(n2)).rho() * p4Infit(n2).rho());

                                                  tb[0][1] = 2 * pmis2.e()  - 2 * pmis2.px() * (p4Infit(n2)).px() * p4Infit(n2).e() /((p4Infit(n2)).rho() * p4Infit(n2).rho())- 2 * pmis2.py() * (p4Infit(n2)).py() * p4Infit(n2).e()/((p4Infit(n2)).rho() * p4Infit(n2).rho())- 2 * pmis2.pz() * (p4Infit(n2)).pz() * p4Infit(n2).e()/((p4Infit(n2)).rho() * p4Infit(n2).rho());

                                                  setB(m_nc,pb,-tb);

                                                  setBT(pb, m_nc, -tb.T());

                                                  break;

                                              }

                                    case 5 :  {

                                                  HepMatrix ta(1, 3, 0);

                                                  double a1 = lambda * lambda + 1;

                                                  ta[0][0] = 2 * pmis2.px() * p4Infit(n2).py() - 2 * pmis2.py() * p4Infit(n2).px();

                                                  ta[0][1] = 2 * pmis2.px() * p4Infit(n2).px() * lambda/sqrt(a1) + 2 * pmis2.py() * (p4Infit(n2)).py() * lambda/sqrt(a1) - 2 * pmis2.pz() * (p4Infit(n2)).pz() /(sqrt(a1) * lambda);

                                                  ta[0][2] = 2 * pmis2.e() * (p4Infit(n2)).m()/(p4Infit(n2)).e();

                                                  setA(m_nc,pa,-ta);

                                                  setAT(pa, m_nc, -ta.T());

                                                  HepMatrix tb(1, 1, 0);

                                                  tb[0][0] = 2 * pmis2.e() * (p4Infit(n2)).rho()/(p4Infit(n2)).e() - 2 * pmis2.px() * (p4Infit(n2)).px()/(p4Infit(n2)).rho() - 2 * pmis2.py() * (p4Infit(n2)).py()/(p4Infit(n2)).rho() - 2 * pmis2.pz() * (p4Infit(n2)).pz()/(p4Infit(n2)).rho();

                                                  setB(m_nc,pb,-tb);

                                                  setBT(pb, m_nc, -tb.T());

                                                  break;

                                              }

                                    case 7 : {

                                                 HepMatrix ta(1, NTRKPAR, 0);

                                                 ta[0][0] = -2 * pmis2.px() + 2 * pmis2.e() * p4Infit(n2).px() / p4Infit(n2).e();

                                                 ta[0][1] = -2 * pmis2.py() + 2 * pmis2.e() * p4Infit(n2).py() / p4Infit(n2).e();

                                                 ta[0][2] = -2 * pmis2.pz() + 2 * pmis2.e() * p4Infit(n2).pz() / p4Infit(n2).e();

                                                 ta[0][3] = 2 * pmis2.e() * p4Infit(n2).m() / p4Infit(n2).e();

                                                 setA(m_nc,pa,-ta);

                                                 setAT(pa, m_nc, -ta.T());

                                                 break;

                                             }

                                }

                            }


                            HepVector dc(1, 0);

                            dc[0] = pmis1.m2() - pmis2.m2();

                            m_G[m_nc] = dc[0];


                            m_nc+=1;


                            break;

                        }


        case FourMomentum:

        default: {

                     //

                     //  px - p4x = 0

                     //  py - p4y = 0

                     //  pz - p4z = 0

                     //  e  - p4e = 0

                     //

                     HepLorentzVector p4 = kc.p4();

                     HepLorentzVector pmis;

                     for(unsigned int j = 0; j< (kc.Ltrk()).size(); j++){

                         int n = (kc.Ltrk())[j];

                         pmis = pmis + p4Infit(n);

                     }

                     for(unsigned int j = 0; j < (kc.Ltrk()).size(); j++) {

                         int n = (kc.Ltrk())[j];

                         double lambda = p4Infit(n).pz()/p4Infit(n).perp();

                         int pa = mappositionA()[n] + 1;

                         int pb = mappositionB()[n] + 1;

                         int ptype = mapkinematic()[n];

                         switch(ptype) {

                             case 0 : {

                                          HepMatrix ta(kc.nc(), NTRKPAR, 0);

                                          ta[0][0] = 1.0;

                                          ta[1][1] = 1.0;

                                          ta[2][2] = 1.0;

                                          ta[3][0] = p4Infit(n).px() / p4Infit(n).e();

                                          ta[3][1] = p4Infit(n).py() / p4Infit(n).e();

                                          ta[3][2] = p4Infit(n).pz() / p4Infit(n).e();

                                          ta[3][3] = p4Infit(n).m() / p4Infit(n).e();

                                          setA(m_nc, pa, ta);

                                          setAT(pa, m_nc, ta.T());

                                          break;

                                      }

                             case 1 : {

                                          HepMatrix ta(kc.nc(), NTRKPAR, 0);

                                          ta[0][0] = -p4Infit(n).py();

                                          ta[0][1] = -p4Infit(n).px()*(lambda/(1 + lambda*lambda));

                                          ta[0][2] = -p4Infit(n).m()*p4Infit(n).px()/(p4Infit(n).rho()*p4Infit(n).rho());

                                          ta[0][3] = p4Infit(n).e()*p4Infit(n).px()/(p4Infit(n).rho()*p4Infit(n).rho());

                                          ta[1][0] = p4Infit(n).px();

                                          ta[1][1] = -p4Infit(n).py()*(lambda/(1 + lambda*lambda));

                                          ta[1][2] = -p4Infit(n).m()*p4Infit(n).py()/(p4Infit(n).rho()*p4Infit(n).rho());

                                          ta[1][3] = p4Infit(n).e()*p4Infit(n).py()/(p4Infit(n).rho()*p4Infit(n).rho());

                                          ta[2][0] = 0;

                                          ta[2][1] = p4Infit(n).pz()*(1/(lambda * (1 + lambda*lambda)));

                                          ta[2][2] = -p4Infit(n).m()*p4Infit(n).pz()/(p4Infit(n).rho()*p4Infit(n).rho());

                                          ta[2][3] = p4Infit(n).e()*p4Infit(n).pz()/(p4Infit(n).rho()*p4Infit(n).rho());

                                          ta[3][0] = 0;

                                          ta[3][1] = 0;

                                          ta[3][2] = 0;

                                          ta[3][3] = 1.0;

                                          setA(m_nc, pa, ta);

                                          setAT(pa, m_nc, ta.T());

                                          break;

                                      }

                             case 2 : {

                                          HepMatrix tb(kc.nc(), 4, 0);

                                          tb[0][0] = 1.0;

                                          tb[1][1] = 1.0;

                                          tb[2][2] = 1.0;

                                          tb[3][3] = 1.0;

                                          setB(m_nc, pb, tb);

                                          setBT(pb, m_nc, tb.T());

                                          break;

                                      }

                             case 3 : {

                                          HepMatrix ta(kc.nc(), 1, 0);

                                          ta[0][0] = -p4Infit(n).m()*p4Infit(n).px()/(p4Infit(n).rho()*p4Infit(n).rho());

                                          ta[1][0] = -p4Infit(n).m()*p4Infit(n).py()/(p4Infit(n).rho()*p4Infit(n).rho());

                                          ta[2][0] = -p4Infit(n).m()*p4Infit(n).pz()/(p4Infit(n).rho()*p4Infit(n).rho());

                                          ta[3][0] = 0;

                                          setA(m_nc, pa, ta);

                                          setAT(pa, m_nc, ta.T());


                                          HepMatrix tb(kc.nc(), 3, 0);

                                          tb[0][0] = -p4Infit(n).py();

                                          tb[0][1] = -p4Infit(n).px()*(lambda/(1 + lambda*lambda));

                                          tb[0][2] = p4Infit(n).e()*p4Infit(n).px()/(p4Infit(n).rho()*p4Infit(n).rho());

                                          tb[1][0] = p4Infit(n).px();

                                          tb[1][1] = -p4Infit(n).py()*(lambda/(1 + lambda*lambda));

                                          tb[1][2] = p4Infit(n).e()*p4Infit(n).py()/(p4Infit(n).rho()*p4Infit(n).rho());

                                          tb[2][0] = 0;

                                          tb[2][1] = p4Infit(n).pz()*(1/(lambda * (1 + lambda*lambda)));

                                          tb[2][2] = p4Infit(n).e()*p4Infit(n).pz()/(p4Infit(n).rho()*p4Infit(n).rho());

                                          tb[3][0] = 0;

                                          tb[3][1] = 0;

                                          tb[3][2] = 1.0;


                                          setB(m_nc, pb, tb);

                                          setBT(pb, m_nc, tb.T());


                                          break;

                                      }

                             case 4 : {

                                          HepMatrix ta(kc.nc(), 2, 0);

                                          ta[0][0] = -p4Infit(n).py();

                                          ta[0][1] = -p4Infit(n).px()*(lambda/sqrt(1 + lambda*lambda));

                                          ta[1][0] =  p4Infit(n).px();

                                          ta[1][1] = -p4Infit(n).py()*(lambda/sqrt(1 + lambda*lambda));

                                          ta[2][0] =  0;

                                          ta[2][1] =  p4Infit(n).pz()*(1/(lambda * (1 + lambda*lambda)));


                                          setA(m_nc, pa, ta);

                                          setAT(pa, m_nc, ta.T());


                                          HepMatrix tb(kc.nc(), 2, 0);

                                          //  tb[3][0] = p4Infit(n).m()/p4Infit(n).e();

                                          //  tb[0][1] = p4Infit(n).px()/p4Infit(n).rho();

                                          //  tb[1][1] = p4Infit(n).py()/p4Infit(n).rho();

                                          //  tb[2][1] = p4Infit(n).pz()/p4Infit(n).rho();

                                          //  tb[3][1] = p4Infit(n).rho()/p4Infit(n).e();

                                          tb[0][0] = -p4Infit(n).m()*p4Infit(n).px()/(p4Infit(n).rho()*p4Infit(n).rho());

                                          tb[1][0] = -p4Infit(n).m()*p4Infit(n).py()/(p4Infit(n).rho()*p4Infit(n).rho());

                                          tb[2][0] = -p4Infit(n).m()*p4Infit(n).pz()/(p4Infit(n).rho()*p4Infit(n).rho());

                                          tb[0][1] = p4Infit(n).e()*p4Infit(n).px()/(p4Infit(n).rho()*p4Infit(n).rho());

                                          tb[1][1] = p4Infit(n).e()*p4Infit(n).py()/(p4Infit(n).rho()*p4Infit(n).rho());

                                          tb[2][1] = p4Infit(n).e()*p4Infit(n).pz()/(p4Infit(n).rho()*p4Infit(n).rho());

                                          tb[3][1] = 1;

                                          setB(m_nc, pb, tb);

                                          setBT(pb, m_nc, tb.T());

                                          break;

                                      }

                             case 5 : {

                                          HepMatrix ta(kc.nc(), 3, 0);

                                          ta[0][0] = -p4Infit(n).py();

                                          ta[0][1] = -p4Infit(n).px()*(lambda/sqrt(1 + lambda*lambda));

                                          ta[1][0] =  p4Infit(n).px();

                                          ta[1][1] = -p4Infit(n).py()*(lambda/sqrt(1 + lambda*lambda));

                                          ta[2][0] =  0;

                                          ta[2][1] =  p4Infit(n).pz()*(1/(lambda * (1 + lambda*lambda)));

                                          ta[3][2] =  p4Infit(n).m()/p4Infit(n).e();

                                          setA(m_nc, pa, ta);

                                          setAT(pa, m_nc, ta.T());


                                          HepMatrix tb(kc.nc(), 1, 0);

                                          tb[0][0] = p4Infit(n).px()/p4Infit(n).rho();

                                          tb[1][0] = p4Infit(n).py()/p4Infit(n).rho();

                                          tb[2][0] = p4Infit(n).pz()/p4Infit(n).rho();

                                          tb[3][0] = p4Infit(n).rho()/p4Infit(n).e();

                                          setB(m_nc, pb, tb);

                                          setBT(pb, m_nc, tb.T());

                                          break;

                                      }

                             case 6 : {

                                          double ptrk = m_p.sub(pa+3, pa+3)[0];

                                          double x = m_p.sub(pa, pa)[0] - m_q.sub(pb, pb)[0];

                                          double y = m_p.sub(pa+1, pa+1)[0] - m_q.sub(pb+1, pb+1)[0];

                                          double z = m_p.sub(pa+2, pa+2)[0] - m_q.sub(pb+2, pb+2)[0];

                                          double R = sqrt(x*x + y*y + z*z);

                                          HepMatrix ta(kc.nc(), 4, 0);

                                          ta[0][0] = ptrk*(y*y + z*z)/(R*R*R);

                                          ta[0][1] = -ptrk*x*y/(R*R*R);

                                          ta[0][2] = -ptrk*x*z/(R*R*R);

                                          ta[0][3] = x/R;

                                          ta[1][0] = -ptrk*y*x/(R*R*R);

                                          ta[1][1] = ptrk*(x*x + z*z)/(R*R*R);

                                          ta[1][2] = -ptrk*y*z/(R*R*R);

                                          ta[1][3] = y/R;

                                          ta[2][0] = -ptrk*z*x/(R*R*R);

                                          ta[2][1] = -ptrk*z*y/(R*R*R);

                                          ta[2][2] = ptrk*(x*x + y*y)/(R*R*R);

                                          ta[2][3] = z/R;

                                          ta[3][3] = 1;

                                          setA(m_nc, pa, ta);

                                          setAT(pa, m_nc, ta.T());


                                          HepMatrix tb(kc.nc(), 3, 0);

                                          tb[0][0] = -ptrk*(y*y + z*z)/(R*R*R);

                                          tb[0][1] = ptrk*x*y/(R*R*R);

                                          tb[0][2] = ptrk*x*z/(R*R*R);

                                          tb[1][0] = ptrk*y*x/(R*R*R);

                                          tb[1][1] = -ptrk*(x*x + z*z)/(R*R*R);

                                          tb[1][2] = ptrk*y*z/(R*R*R);

                                          tb[2][0] = ptrk*z*x/(R*R*R);

                                          tb[2][1] = ptrk*z*y/(R*R*R);

                                          tb[2][2] = -ptrk*(x*x + y*y)/(R*R*R);

                                          HepMatrix tbp = m_B.sub(1, 4, 1, 3);

                                          tb = tbp + tb;

                                          setB(m_nc, pb, tb);

                                          setBT(pb, m_nc, tb.T());

                                          break;

                                      }

                             case 7 : {

                                          HepMatrix ta(kc.nc(), NTRKPAR, 0);

                                          ta[0][0] = 1.0;

                                          ta[1][1] = 1.0;

                                          ta[2][2] = 1.0;

                                          ta[3][0] = p4Infit(n).px() / p4Infit(n).e();

                                          ta[3][1] = p4Infit(n).py() / p4Infit(n).e();

                                          ta[3][2] = p4Infit(n).pz() / p4Infit(n).e();

                                          ta[3][3] = p4Infit(n).m() / p4Infit(n).e();

                                          setA(m_nc, pa, ta);

                                          setAT(pa, m_nc, ta.T());

                                          break;

                                      }

                         }

                     }


                     HepVector dc(kc.nc(), 0);

                     dc[0] = pmis.px()  - p4.px();

                     dc[1] = pmis.py()  - p4.py();

                     dc[2] = pmis.pz()  - p4.pz();

                     dc[3] = pmis.e()  - p4.e();

                     for(int i = 0; i < kc.nc(); i++) {

                         m_G[m_nc+i] = dc[i];

                     }


                     m_nc += 4;


                     break;

                 }

    }

}


sin
double sin(const BesAngle a)
Definition: BesAngle.h:210

cos
double cos(const BesAngle a)
Definition: BesAngle.h:213

num1
const int num1
Definition: BesTofDigitizerEcV3.hh:35

mass
double mass
Definition: CosmicGenerator.cxx:138

n
const Int_t n
Definition: DataBase/tau_mode.c:65

etot
Double_t etot
Definition: DataBase/tau_mode.c:7

x
Double_t x[10]
Definition: DataBase/tau_mode.c:57

I
const DifComplex I

abs
double abs(const EvtComplex &c)
Definition: EvtComplex.hh:212

ptype
string::const_iterator ptype
Definition: EvtMTree.hh:19

dc
int dc[18]
Definition: EvtPycont.cc:41

HepPoint3D
HepGeom::Point3D< double > HepPoint3D
Definition: Gam4pikp.cxx:37

HTrackParameter.h

KalmanKinematicFit.h

KinematicConstraints.h

n2
int n2
Definition: SD0Tag.cxx:55

n1
int n1
Definition: SD0Tag.cxx:54

HTrackParameter
Definition: HTrackParameter.h:28

HTrackParameter::hel
HepVector hel() const
Definition: HTrackParameter.h:49

HTrackParameter::eHel
HepSymMatrix eHel() const
Definition: HTrackParameter.h:51

KalmanKinematicFit
Definition: KalmanKinematicFit.h:11

KalmanKinematicFit::pull
HepVector pull(int n)
Definition: KalmanKinematicFit.cxx:1061

KalmanKinematicFit::AddTotalEnergy
void AddTotalEnergy(int number, double etot, std::vector< int > lis)
Definition: KalmanKinematicFit.cxx:310

KalmanKinematicFit::Fit
bool Fit()
Definition: KalmanKinematicFit.cxx:515

KalmanKinematicFit::~KalmanKinematicFit
~KalmanKinematicFit()
Definition: KalmanKinematicFit.cxx:28

KalmanKinematicFit::AddFourMomentum
void AddFourMomentum(int number, HepLorentzVector p4)
Definition: KalmanKinematicFit.cxx:353

KalmanKinematicFit::chisq
double chisq() const
Definition: KalmanKinematicFit.h:150

KalmanKinematicFit::AddThreeMomentum
void AddThreeMomentum(int number, Hep3Vector p3)
Definition: KalmanKinematicFit.cxx:334

KalmanKinematicFit::BuildVirtualParticle
void BuildVirtualParticle(int number)
Definition: KalmanKinematicFit.cxx:943

KalmanKinematicFit::getCInfit
HepSymMatrix getCInfit(int i) const
Definition: KalmanKinematicFit.cxx:1415

KalmanKinematicFit::AddResonance
void AddResonance(int number, double mres, std::vector< int > tlis)
Definition: KalmanKinematicFit.cxx:142

KalmanKinematicFit::AddTotalMomentum
void AddTotalMomentum(int number, double ptot, std::vector< int > lis)
Definition: KalmanKinematicFit.cxx:227

KalmanKinematicFit::init
void init()
Definition: KalmanKinematicFit.cxx:34

KalmanKinematicFit::getCOrigin
HepSymMatrix getCOrigin(int i) const
Definition: KalmanKinematicFit.cxx:1381

KalmanKinematicFit::instance
static KalmanKinematicFit * instance()
Definition: KalmanKinematicFit.cxx:20

KalmanKinematicFit::AddEqualMass
void AddEqualMass(int number, std::vector< int > tlis1, std::vector< int > tlis2)
Definition: KalmanKinematicFit.cxx:321

KinematicConstraints
Definition: KinematicConstraints.h:20

KinematicConstraints::FourMomentumConstraints
void FourMomentumConstraints(const HepLorentzVector p4, std::vector< int > tlis, HepSymMatrix Vme)
Definition: KinematicConstraints.cxx:74

KinematicConstraints::Ltrk
std::vector< int > Ltrk()
Definition: KinematicConstraints.h:45

KinematicConstraints::ResonanceConstraints
void ResonanceConstraints(const double mres, std::vector< int > tlis, HepSymMatrix Vre)
Definition: KinematicConstraints.cxx:34

KinematicConstraints::mres
double mres() const
Definition: KinematicConstraints.h:61

KinematicConstraints::Vmeasure
HepSymMatrix Vmeasure() const
Definition: KinematicConstraints.h:73

KinematicConstraints::ThreeMomentumConstraints
void ThreeMomentumConstraints(const Hep3Vector p3, std::vector< int > tlis)
Definition: KinematicConstraints.cxx:64

KinematicConstraints::p3
Hep3Vector p3() const
Definition: KinematicConstraints.h:65

KinematicConstraints::TotalEnergyConstraints
void TotalEnergyConstraints(const double etot, std::vector< int > tlis)
Definition: KinematicConstraints.cxx:44

KinematicConstraints::nc
int nc()
Definition: KinematicConstraints.h:46

KinematicConstraints::numEqual
std::vector< int > numEqual()
Definition: KinematicConstraints.h:74

KinematicConstraints::etot
double etot() const
Definition: KinematicConstraints.h:62

KinematicConstraints::ptot
double ptot() const
Definition: KinematicConstraints.h:63

KinematicConstraints::p4
HepLorentzVector p4() const
Definition: KinematicConstraints.h:66

KinematicConstraints::TotalMomentumConstraints
void TotalMomentumConstraints(const double ptot, std::vector< int > tlis)
Definition: KinematicConstraints.cxx:54

KinematicConstraints::Type
int Type() const
Definition: KinematicConstraints.h:26

KinematicConstraints::EqualMassConstraints
void EqualMassConstraints(std::vector< int > tlis1, std::vector< int > tlis2, HepSymMatrix Vne)
Definition: KinematicConstraints.cxx:85

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std::vector< int > AddList(int n1)
Definition: TrackPool.cxx:483

TrackPool::numberone
int numberone() const
Definition: TrackPool.h:117

TrackPool::wTrackInfit
std::vector< WTrackParameter > wTrackInfit() const
Definition: TrackPool.h:73

TrackPool::setVBeamPosition
void setVBeamPosition(const HepSymMatrix VBeamPosition)
Definition: TrackPool.h:144

TrackPool::numberWTrack
int numberWTrack() const
Definition: TrackPool.h:79

TrackPool::clearMapkinematic
void clearMapkinematic()
Definition: TrackPool.h:124

TrackPool::clearGammaShapeList
void clearGammaShapeList()
Definition: TrackPool.h:140

TrackPool::clearWTrackOrigin
void clearWTrackOrigin()
Definition: TrackPool.h:111

TrackPool::clearone
void clearone()
Definition: TrackPool.h:115

TrackPool::clearMappositionB
void clearMappositionB()
Definition: TrackPool.h:126

TrackPool::numberGammaShape
int numberGammaShape() const
Definition: TrackPool.h:99

TrackPool::mappositionA
vector< int > mappositionA() const
Definition: TrackPool.h:120

TrackPool::clearWTrackList
void clearWTrackList()
Definition: TrackPool.h:113

TrackPool::getVBeamPosition
HepSymMatrix getVBeamPosition() const
Definition: TrackPool.h:148

TrackPool::clearMappositionA
void clearMappositionA()
Definition: TrackPool.h:125

TrackPool::getBeamPosition
HepPoint3D getBeamPosition() const
Definition: TrackPool.h:147

TrackPool::GammaShapeValue
std::vector< GammaShape > GammaShapeValue() const
Definition: TrackPool.h:95

TrackPool::wTrackOrigin
std::vector< WTrackParameter > wTrackOrigin() const
Definition: TrackPool.h:72

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int numbertwo() const
Definition: TrackPool.h:118

TrackPool::GammaShapeList
std::vector< int > GammaShapeList() const
Definition: TrackPool.h:96

TrackPool::mappositionB
vector< int > mappositionB() const
Definition: TrackPool.h:121

TrackPool::cleartwo
void cleartwo()
Definition: TrackPool.h:116

TrackPool::clearGammaShape
void clearGammaShape()
Definition: TrackPool.h:139

TrackPool::mapkinematic
vector< int > mapkinematic() const
Definition: TrackPool.h:122

TrackPool::clearWTrackInfit
void clearWTrackInfit()
Definition: TrackPool.h:112

TrackPool::setBeamPosition
void setBeamPosition(const HepPoint3D BeamPosition)
Definition: TrackPool.h:143

TrackPool::setWTrackInfit
void setWTrackInfit(const int n, const WTrackParameter wtrk)
Definition: TrackPool.h:106

WTrackParameter
Definition: WTrackParameter.h:32

WTrackParameter::setEw
void setEw(const HepSymMatrix &Ew)
Definition: WTrackParameter.h:53

WTrackParameter::setMass
void setMass(const double mass)
Definition: WTrackParameter.h:55

WTrackParameter::setCharge
void setCharge(const int charge)
Definition: WTrackParameter.h:54

WTrackParameter::setW
void setW(const HepVector &w)
Definition: WTrackParameter.h:51

EvtCyclic3::AC
@ AC
Definition: EvtCyclic3.hh:21

rb::R
complex_t R(double Q2, double M2, double G, double Mp2, double Mm2)
Definition: TUtil.h:27