release-08-01-10/doxygen/MassFitKFit_8cc_source.html

 /**************************************************************************

  * basf2 (Belle II Analysis Software Framework)                           *

  * Author: The Belle II Collaboration                                     *

  * External Contributor: J. Tanaka                                        *

  *                                                                        *

  * See git log for contributors and copyright holders.                    *

  * This file is licensed under LGPL-3.0, see LICENSE.md.                  *

  **************************************************************************/


 #include <cstdio>


 #include <analysis/VertexFitting/KFit/MakeMotherKFit.h>

 #include <analysis/VertexFitting/KFit/MassFitKFit.h>

 #include <analysis/utility/CLHEPToROOT.h>

 #include <framework/gearbox/Const.h>


 #include <TMath.h>

 #include <TMatrixFSym.h>


 using namespace std;

 using namespace Belle2;

 using namespace Belle2::analysis;

 using namespace CLHEP;


 MassFitKFit::MassFitKFit()

 {

   m_FlagFitted = false;

   m_FlagTrackVertexError = false;

   m_FlagFitIncludingVertex = false;

   m_FlagAtDecayPoint = true;

   m_NecessaryTrackCount = 2;

   m_d   = HepMatrix(1, 1, 0);

   m_V_D = HepMatrix(1, 1, 0);

   m_lam = HepMatrix(1, 1, 0);

   m_AfterVertexError = HepSymMatrix(3, 0);

   m_InvariantMass = -1.0;

 }


 MassFitKFit::~MassFitKFit() = default;


 enum KFitError::ECode

 MassFitKFit::setVertex(const HepPoint3D& v) {

   m_BeforeVertex = v;


   return m_ErrorCode = KFitError::kNoError;

 }


 enum KFitError::ECode

 MassFitKFit::setVertexError(const HepSymMatrix& e) {

   if (e.num_row() != 3)

   {

     m_ErrorCode = KFitError::kBadMatrixSize;

     KFitError::displayError(__FILE__, __LINE__, __func__, m_ErrorCode);

     return m_ErrorCode;

   }


   m_BeforeVertexError = e;

   m_FlagFitIncludingVertex = true;


   return m_ErrorCode = KFitError::kNoError;

 }


 enum KFitError::ECode

 MassFitKFit::setInvariantMass(const double m) {

   m_InvariantMass = m;


   return m_ErrorCode = KFitError::kNoError;

 }


 enum KFitError::ECode

 MassFitKFit::setFlagAtDecayPoint(const bool flag) {

   m_FlagAtDecayPoint = flag;


   return m_ErrorCode = KFitError::kNoError;

 }


 enum KFitError::ECode

 MassFitKFit::fixMass() {

   m_IsFixMass.push_back(true);


   return m_ErrorCode = KFitError::kNoError;

 }


 enum KFitError::ECode

 MassFitKFit::unfixMass() {

   m_IsFixMass.push_back(false);


   return m_ErrorCode = KFitError::kNoError;

 }


 enum KFitError::ECode

 MassFitKFit::setTrackVertexError(const HepMatrix& e) {

   if (e.num_row() != 3 || e.num_col() != KFitConst::kNumber7)

   {

     m_ErrorCode = KFitError::kBadMatrixSize;

     KFitError::displayError(__FILE__, __LINE__, __func__, m_ErrorCode);

     return m_ErrorCode;

   }


   m_BeforeTrackVertexError.push_back(e);

   m_FlagTrackVertexError = true;

   m_FlagFitIncludingVertex = true;


   return m_ErrorCode = KFitError::kNoError;

 }


 enum KFitError::ECode

 MassFitKFit::setTrackZeroVertexError() {

   HepMatrix zero(3, KFitConst::kNumber7, 0);


   return this->setTrackVertexError(zero);

 }


 enum KFitError::ECode

 MassFitKFit::setCorrelation(const HepMatrix& m) {

   return KFitBase::setCorrelation(m);

 }


 enum KFitError::ECode

 MassFitKFit::setZeroCorrelation() {

   return KFitBase::setZeroCorrelation();

 }


 const HepPoint3D

 MassFitKFit::getVertex(const int flag) const

 {

   if (flag == KFitConst::kAfterFit && !isFitted()) return HepPoint3D();


   switch (flag) {

     case KFitConst::kBeforeFit:

       return m_BeforeVertex;


     case KFitConst::kAfterFit:

       return m_AfterVertex;


     default:

       KFitError::displayError(__FILE__, __LINE__, __func__, KFitError::kOutOfRange);

       return HepPoint3D();

   }

 }


 const HepSymMatrix

 MassFitKFit::getVertexError(const int flag) const

 {

   if (flag == KFitConst::kAfterFit && !isFitted()) return HepSymMatrix(3, 0);


   if (flag == KFitConst::kBeforeFit)

     return m_BeforeVertexError;

   else if (flag == KFitConst::kAfterFit && m_FlagFitIncludingVertex)

     return m_AfterVertexError;

   else {

     KFitError::displayError(__FILE__, __LINE__, __func__, KFitError::kOutOfRange);

     return HepSymMatrix(3, 0);

   }

 }


 double

 MassFitKFit::getInvariantMass() const

 {

   return m_InvariantMass;

 }


 bool

 MassFitKFit::getFlagAtDecayPoint() const

 {

   return m_FlagAtDecayPoint;

 }


 bool

 MassFitKFit::getFlagFitWithVertex() const

 {

   return m_FlagFitIncludingVertex;

 }


 double

 MassFitKFit::getCHIsq() const

 {

   return m_CHIsq;

 }


 const HepMatrix

 MassFitKFit::getTrackVertexError(const int id, const int flag) const

 {

   if (flag == KFitConst::kAfterFit && !isFitted()) return HepMatrix(3, KFitConst::kNumber7, 0);

   if (!isTrackIDInRange(id)) return HepMatrix(3, KFitConst::kNumber7, 0);


   if (flag == KFitConst::kBeforeFit)

     return m_BeforeTrackVertexError[id];

   else if (flag == KFitConst::kAfterFit && m_FlagFitIncludingVertex)

     return m_AfterTrackVertexError[id];

   else {

     KFitError::displayError(__FILE__, __LINE__, __func__, KFitError::kOutOfRange);

     return HepMatrix(3, KFitConst::kNumber7, 0);

   }

 }


 double

 MassFitKFit::getTrackCHIsq(const int id) const

 {

   if (!isFitted()) return -1;

   if (!isTrackIDInRange(id)) return -1;


   if (m_IsFixMass[id]) {


     HepMatrix da(m_Tracks[id].getFitParameter(KFitConst::kBeforeFit) - m_Tracks[id].getFitParameter(KFitConst::kAfterFit));

     int err_inverse = 0;

     const double chisq = (da.T() * (m_Tracks[id].getFitError(KFitConst::kBeforeFit).inverse(err_inverse)) * da)[0][0];


     if (err_inverse) {

       KFitError::displayError(__FILE__, __LINE__, __func__, KFitError::kCannotGetMatrixInverse);

       return -1;

     }


     return chisq;


   } else {


     HepMatrix da(m_Tracks[id].getMomPos(KFitConst::kBeforeFit) - m_Tracks[id].getMomPos(KFitConst::kAfterFit));

     int err_inverse = 0;

     const double chisq = (da.T() * (m_Tracks[id].getError(KFitConst::kBeforeFit).inverse(err_inverse)) * da)[0][0];


     if (err_inverse) {

       KFitError::displayError(__FILE__, __LINE__, __func__, KFitError::kCannotGetMatrixInverse);

       return -1;

     }


     return chisq;


   }

 }


 const HepMatrix

 MassFitKFit::getCorrelation(const int id1, const int id2, const int flag) const

 {

   if (flag == KFitConst::kAfterFit && !isFitted()) return HepMatrix(KFitConst::kNumber7, KFitConst::kNumber7, 0);

   if (!isTrackIDInRange(id1)) return HepMatrix(KFitConst::kNumber7, KFitConst::kNumber7, 0);

   if (!isTrackIDInRange(id2)) return HepMatrix(KFitConst::kNumber7, KFitConst::kNumber7, 0);


   switch (flag) {

     case KFitConst::kBeforeFit:

       return KFitBase::getCorrelation(id1, id2, flag);


     case KFitConst::kAfterFit:

       return makeError3(

                this->getTrackMomentum(id1),

                this->getTrackMomentum(id2),

                m_V_al_1.sub(KFitConst::kNumber7 * id1 + 1, KFitConst::kNumber7 * (id1 + 1), KFitConst::kNumber7 * id2 + 1,

                             KFitConst::kNumber7 * (id2 + 1)),

                m_IsFixMass[id1],

                m_IsFixMass[id2]);


     default:

       KFitError::displayError(__FILE__, __LINE__, __func__, KFitError::kOutOfRange);

       return HepMatrix(KFitConst::kNumber7, KFitConst::kNumber7, 0);

   }

 }


 enum KFitError::ECode

 MassFitKFit::doFit() {

   return KFitBase::doFit1();

 }


 enum KFitError::ECode

 MassFitKFit::prepareInputMatrix() {

   if (m_TrackCount > KFitConst::kMaxTrackCount)

   {

     m_ErrorCode = KFitError::kBadTrackSize;

     KFitError::displayError(__FILE__, __LINE__, __func__, m_ErrorCode);

     return m_ErrorCode;

   }


   if (m_IsFixMass.size() == 0)

   {

     // If no fix_mass flag at all,

     // all tracks are considered to be fixed at mass.

     for (int i = 0; i < m_TrackCount; i++) this->fixMass();

   } else if (m_IsFixMass.size() != (unsigned int)m_TrackCount)

   {

     m_ErrorCode = KFitError::kBadTrackSize;

     KFitError::displayError(__FILE__, __LINE__, __func__, m_ErrorCode);

     return m_ErrorCode;

   }


   if (!m_FlagFitIncludingVertex)

   {

     int index = 0;

     m_al_0     = HepMatrix(KFitConst::kNumber7 * m_TrackCount, 1, 0);

     m_property = HepMatrix(m_TrackCount, 3, 0);

     m_V_al_0   = HepSymMatrix(KFitConst::kNumber7 * m_TrackCount, 0);


     for (auto& track : m_Tracks) {

       // momentum x,y,z and position x,y,z

       m_al_0[index * KFitConst::kNumber7 + 0][0] = track.getMomentum(KFitConst::kBeforeFit).x();

       m_al_0[index * KFitConst::kNumber7 + 1][0] = track.getMomentum(KFitConst::kBeforeFit).y();

       m_al_0[index * KFitConst::kNumber7 + 2][0] = track.getMomentum(KFitConst::kBeforeFit).z();

       m_al_0[index * KFitConst::kNumber7 + 3][0] = track.getMomentum(KFitConst::kBeforeFit).t();

       m_al_0[index * KFitConst::kNumber7 + 4][0] = track.getPosition(KFitConst::kBeforeFit).x();

       m_al_0[index * KFitConst::kNumber7 + 5][0] = track.getPosition(KFitConst::kBeforeFit).y();

       m_al_0[index * KFitConst::kNumber7 + 6][0] = track.getPosition(KFitConst::kBeforeFit).z();

       // these error

       m_V_al_0.sub(index * KFitConst::kNumber7 + 1, track.getError(KFitConst::kBeforeFit));

       // charge, mass, a

       m_property[index][0] =  track.getCharge();

       m_property[index][1] =  track.getMass();

       const double c = Belle2::Const::speedOfLight * 1e-4;

       m_property[index][2] = -c * m_MagneticField * track.getCharge();

       index++;

     }


     // error between track and track

     if (m_FlagCorrelation) {

       this->prepareCorrelation();

       if (m_ErrorCode != KFitError::kNoError) {

         KFitError::displayError(__FILE__, __LINE__, __func__, m_ErrorCode);

         return m_ErrorCode;

       }

     }


     // set member matrix

     m_al_1   = m_al_0;


     // define size of matrix

     m_V_al_1 = HepMatrix(KFitConst::kNumber7 * m_TrackCount, KFitConst::kNumber7 * m_TrackCount, 0);

     m_D      = m_V_al_1.sub(1, 1, 1, KFitConst::kNumber7 * m_TrackCount);


   } else

   {

     // m_FlagFitIncludingVertex == true

     int index = 0;

     m_al_0     = HepMatrix(KFitConst::kNumber7 * m_TrackCount + 3, 1, 0);

     m_property = HepMatrix(m_TrackCount, 3, 0);

     m_V_al_0   = HepSymMatrix(KFitConst::kNumber7 * m_TrackCount + 3, 0);


     for (auto& track : m_Tracks) {

       // momentum x,y,z and position x,y,z

       m_al_0[index * KFitConst::kNumber7 + 0][0] = track.getMomentum(KFitConst::kBeforeFit).x();

       m_al_0[index * KFitConst::kNumber7 + 1][0] = track.getMomentum(KFitConst::kBeforeFit).y();

       m_al_0[index * KFitConst::kNumber7 + 2][0] = track.getMomentum(KFitConst::kBeforeFit).z();

       m_al_0[index * KFitConst::kNumber7 + 3][0] = track.getMomentum(KFitConst::kBeforeFit).t();

       m_al_0[index * KFitConst::kNumber7 + 4][0] = track.getPosition(KFitConst::kBeforeFit).x();

       m_al_0[index * KFitConst::kNumber7 + 5][0] = track.getPosition(KFitConst::kBeforeFit).y();

       m_al_0[index * KFitConst::kNumber7 + 6][0] = track.getPosition(KFitConst::kBeforeFit).z();

       // these error

       m_V_al_0.sub(index * KFitConst::kNumber7 + 1, track.getError(KFitConst::kBeforeFit));

       // charge, mass, a

       m_property[index][0] =  track.getCharge();

       m_property[index][1] =  track.getMass();

       const double c = Belle2::Const::speedOfLight * 1e-4;

       m_property[index][2] = -c * m_MagneticField * track.getCharge();

       index++;

     }


     // vertex

     m_al_0[KFitConst::kNumber7 * m_TrackCount + 0][0] = m_BeforeVertex.x();

     m_al_0[KFitConst::kNumber7 * m_TrackCount + 1][0] = m_BeforeVertex.y();

     m_al_0[KFitConst::kNumber7 * m_TrackCount + 2][0] = m_BeforeVertex.z();

     m_V_al_0.sub(KFitConst::kNumber7 * m_TrackCount + 1, m_BeforeVertexError);


     // error between track and track

     if (m_FlagCorrelation) {

       this->prepareCorrelation();

       if (m_ErrorCode != KFitError::kNoError) {

         KFitError::displayError(__FILE__, __LINE__, __func__, m_ErrorCode);

         return m_ErrorCode;

       }

     }


     // set member matrix

     m_al_1   = m_al_0;


     // define size of matrix

     m_V_al_1 = HepMatrix(KFitConst::kNumber7 * m_TrackCount + 3, KFitConst::kNumber7 * m_TrackCount + 3, 0);

     m_D      = m_V_al_1.sub(1, 1, 1, KFitConst::kNumber7 * m_TrackCount + 3);

   }


   return m_ErrorCode = KFitError::kNoError;

 }


 enum KFitError::ECode

 MassFitKFit::prepareInputSubMatrix() { // unused

   char buf[1024];

   sprintf(buf, "%s:%s(): internal error; this function should never be called", __FILE__, __func__);

   B2FATAL(buf);


   /* NEVER REACHEd HERE */

   return KFitError::kOutOfRange;

 }


 enum KFitError::ECode

 MassFitKFit::prepareCorrelation() {

   if (m_BeforeCorrelation.size() != static_cast<unsigned int>(m_TrackCount * (m_TrackCount - 1) / 2))

   {

     m_ErrorCode = KFitError::kBadCorrelationSize;

     KFitError::displayError(__FILE__, __LINE__, __func__, m_ErrorCode);

     return m_ErrorCode;

   }


   int row = 0, col = 0;


   for (auto& hm : m_BeforeCorrelation)

   {

     // counter

     row++;

     if (row == m_TrackCount) {

       col++;

       row = col + 1;

     }


     int ii = 0, jj = 0;

     for (int i = KFitConst::kNumber7 * row; i < KFitConst::kNumber7 * (row + 1); i++) {

       for (int j = KFitConst::kNumber7 * col; j < KFitConst::kNumber7 * (col + 1); j++) {

         m_V_al_0[i][j] = hm[ii][jj];

         jj++;

       }

       jj = 0;

       ii++;

     }

   }


   if (m_FlagFitIncludingVertex)

   {

     // ...error of vertex

     m_V_al_0.sub(KFitConst::kNumber7 * m_TrackCount + 1, m_BeforeVertexError);


     // ...error matrix between vertex and tracks

     if (m_FlagTrackVertexError) {

       if (m_BeforeTrackVertexError.size() != (unsigned int)m_TrackCount) {

         m_ErrorCode = KFitError::kBadCorrelationSize;

         KFitError::displayError(__FILE__, __LINE__, __func__, m_ErrorCode);

         return m_ErrorCode;

       }


       int i = 0;

       for (auto& hm : m_BeforeTrackVertexError) {

         for (int j = 0; j < 3; j++) for (int k = 0; k < KFitConst::kNumber7; k++) {

             m_V_al_0[j + KFitConst::kNumber7 * m_TrackCount][k + i * KFitConst::kNumber7] = hm[j][k];

           }

         i++;

       }

     }

   }


   return m_ErrorCode = KFitError::kNoError;

 }


 enum KFitError::ECode

 MassFitKFit::prepareOutputMatrix() {

   Hep3Vector h3v;

   int index = 0;

   for (auto& pdata : m_Tracks)

   {

     // tracks

     // momentum

     h3v.setX(m_al_1[index * KFitConst::kNumber7 + 0][0]);

     h3v.setY(m_al_1[index * KFitConst::kNumber7 + 1][0]);

     h3v.setZ(m_al_1[index * KFitConst::kNumber7 + 2][0]);

     if (m_IsFixMass[index])

       pdata.setMomentum(HepLorentzVector(h3v, sqrt(h3v.mag2() + pdata.getMass()*pdata.getMass())), KFitConst::kAfterFit);

     else

       pdata.setMomentum(HepLorentzVector(h3v, m_al_1[index * KFitConst::kNumber7 + 3][0]), KFitConst::kAfterFit);

     // position

     pdata.setPosition(HepPoint3D(

                         m_al_1[index * KFitConst::kNumber7 + 4][0],

                         m_al_1[index * KFitConst::kNumber7 + 5][0],

                         m_al_1[index * KFitConst::kNumber7 + 6][0]), KFitConst::kAfterFit);

     // error of the tracks

     pdata.setError(this->makeError3(pdata.getMomentum(),

                                     m_V_al_1.sub(

                                       index    * KFitConst::kNumber7 + 1,

                                       (index + 1)*KFitConst::kNumber7,

                                       index    * KFitConst::kNumber7 + 1,

                                       (index + 1)*KFitConst::kNumber7), m_IsFixMass[index]),

                    KFitConst::kAfterFit);

     if (m_ErrorCode != KFitError::kNoError) break;

     index++;

   }


   if (m_FlagFitIncludingVertex)

   {

     // vertex

     m_AfterVertex.setX(m_al_1[KFitConst::kNumber7 * m_TrackCount + 0][0]);

     m_AfterVertex.setY(m_al_1[KFitConst::kNumber7 * m_TrackCount + 1][0]);

     m_AfterVertex.setZ(m_al_1[KFitConst::kNumber7 * m_TrackCount + 2][0]);

     // error of the vertex

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

         m_AfterVertexError[i][j] = m_V_al_1[KFitConst::kNumber7 * m_TrackCount + i][KFitConst::kNumber7 * m_TrackCount + j];

       }

     // error between vertex and tracks

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

       HepMatrix hm(3, KFitConst::kNumber7, 0);

       for (int j = 0; j < 3; j++) for (int k = 0; k < KFitConst::kNumber7; k++) {

           hm[j][k] = m_V_al_1[KFitConst::kNumber7 * m_TrackCount + j][KFitConst::kNumber7 * i + k];

         }

       if (m_IsFixMass[i])

         m_AfterTrackVertexError.push_back(this->makeError4(m_Tracks[i].getMomentum(), hm));

       else

         m_AfterTrackVertexError.push_back(hm);

     }

   } else

   {

     // not fit

     m_AfterVertex = m_BeforeVertex;

   }


   return m_ErrorCode = KFitError::kNoError;

 }


 enum KFitError::ECode

 MassFitKFit::makeCoreMatrix() {

   if (!m_FlagFitIncludingVertex)

   {


     HepMatrix al_1_prime(m_al_1);

     HepMatrix Sum_al_1(4, 1, 0);

     std::vector<double> energy(m_TrackCount);

     double a;


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

       a = m_property[i][2];

       if (!m_FlagAtDecayPoint) a = 0.;

       al_1_prime[i * KFitConst::kNumber7 + 0][0] -= a * (m_BeforeVertex.y() - al_1_prime[i * KFitConst::kNumber7 + 5][0]);

       al_1_prime[i * KFitConst::kNumber7 + 1][0] += a * (m_BeforeVertex.x() - al_1_prime[i * KFitConst::kNumber7 + 4][0]);

       energy[i] = sqrt(al_1_prime[i * KFitConst::kNumber7 + 0][0] * al_1_prime[i * KFitConst::kNumber7 + 0][0] +

                        al_1_prime[i * KFitConst::kNumber7 + 1][0] * al_1_prime[i * KFitConst::kNumber7 + 1][0] +

                        al_1_prime[i * KFitConst::kNumber7 + 2][0] * al_1_prime[i * KFitConst::kNumber7 + 2][0] +

                        m_property[i][1] * m_property[i][1]);

       if (m_IsFixMass[i])

         Sum_al_1[3][0] += energy[i];

       else

         Sum_al_1[3][0] += al_1_prime[i * KFitConst::kNumber7 + 3][0];

     }


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

       for (int j = 0; j < 3; j++) Sum_al_1[j][0] += al_1_prime[i * KFitConst::kNumber7 + j][0];

     }


     m_d[0][0] =

       + Sum_al_1[3][0] * Sum_al_1[3][0] - Sum_al_1[0][0] * Sum_al_1[0][0]

       - Sum_al_1[1][0] * Sum_al_1[1][0] - Sum_al_1[2][0] * Sum_al_1[2][0]

       - m_InvariantMass * m_InvariantMass;


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

       if (energy[i] == 0) {

         m_ErrorCode = KFitError::kDivisionByZero;

         KFitError::displayError(__FILE__, __LINE__, __func__, m_ErrorCode);

         break;

       }


       a = m_property[i][2];

       if (!m_FlagAtDecayPoint) a = 0.;


       if (m_IsFixMass[i]) {

         double invE = 1. / energy[i];

         m_D[0][i * KFitConst::kNumber7 + 0] = 2.*(Sum_al_1[3][0] * al_1_prime[i * KFitConst::kNumber7 + 0][0] * invE - Sum_al_1[0][0]);

         m_D[0][i * KFitConst::kNumber7 + 1] = 2.*(Sum_al_1[3][0] * al_1_prime[i * KFitConst::kNumber7 + 1][0] * invE - Sum_al_1[1][0]);

         m_D[0][i * KFitConst::kNumber7 + 2] = 2.*(Sum_al_1[3][0] * al_1_prime[i * KFitConst::kNumber7 + 2][0] * invE - Sum_al_1[2][0]);

         m_D[0][i * KFitConst::kNumber7 + 3] = 0.;

         m_D[0][i * KFitConst::kNumber7 + 4] = -2.*(Sum_al_1[3][0] * al_1_prime[i * KFitConst::kNumber7 + 1][0] * invE - Sum_al_1[1][0]) * a;

         m_D[0][i * KFitConst::kNumber7 + 5] = 2.*(Sum_al_1[3][0] * al_1_prime[i * KFitConst::kNumber7 + 0][0] * invE - Sum_al_1[0][0]) * a;

         m_D[0][i * KFitConst::kNumber7 + 6] = 0.;

       } else {

         m_D[0][i * KFitConst::kNumber7 + 0] = -2.*Sum_al_1[0][0];

         m_D[0][i * KFitConst::kNumber7 + 1] = -2.*Sum_al_1[1][0];

         m_D[0][i * KFitConst::kNumber7 + 2] = -2.*Sum_al_1[2][0];

         m_D[0][i * KFitConst::kNumber7 + 3] =  2.*Sum_al_1[3][0];

         m_D[0][i * KFitConst::kNumber7 + 4] =  2.*Sum_al_1[1][0] * a;

         m_D[0][i * KFitConst::kNumber7 + 5] = -2.*Sum_al_1[0][0] * a;

         m_D[0][i * KFitConst::kNumber7 + 6] =  0.;

       }

     }


   } else

   {


     // m_FlagFitIncludingVertex == true

     HepMatrix al_1_prime(m_al_1);

     HepMatrix Sum_al_1(7, 1, 0);

     std::vector<double> energy(m_TrackCount);

     double a;


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

       a = m_property[i][2];

       al_1_prime[i * KFitConst::kNumber7 + 0][0] -= a * (al_1_prime[KFitConst::kNumber7 * m_TrackCount + 1][0] - al_1_prime[i *

                                                          KFitConst::kNumber7 + 5][0]);

       al_1_prime[i * KFitConst::kNumber7 + 1][0] += a * (al_1_prime[KFitConst::kNumber7 * m_TrackCount + 0][0] - al_1_prime[i *

                                                          KFitConst::kNumber7 + 4][0]);

       energy[i] = sqrt(al_1_prime[i * KFitConst::kNumber7 + 0][0] * al_1_prime[i * KFitConst::kNumber7 + 0][0] +

                        al_1_prime[i * KFitConst::kNumber7 + 1][0] * al_1_prime[i * KFitConst::kNumber7 + 1][0] +

                        al_1_prime[i * KFitConst::kNumber7 + 2][0] * al_1_prime[i * KFitConst::kNumber7 + 2][0] +

                        m_property[i][1] * m_property[i][1]);

       Sum_al_1[6][0] = + a;

     }


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

       if (energy[i] == 0) {

         m_ErrorCode = KFitError::kDivisionByZero;

         KFitError::displayError(__FILE__, __LINE__, __func__, m_ErrorCode);

         break;

       }


       if (m_IsFixMass[i]) {

         double invE = 1. / energy[i];

         Sum_al_1[3][0] += energy[i];

         Sum_al_1[4][0] += al_1_prime[i * KFitConst::kNumber7 + 1][0] * m_property[i][2] * invE;

         Sum_al_1[5][0] += al_1_prime[i * KFitConst::kNumber7 + 0][0] * m_property[i][2] * invE;

       } else {

         Sum_al_1[3][0] += al_1_prime[i * KFitConst::kNumber7 + 3][0];

       }


       for (int j = 0; j < 3; j++) Sum_al_1[j][0] += al_1_prime[i * KFitConst::kNumber7 + j][0];

     }


     m_d[0][0] =

       + Sum_al_1[3][0] * Sum_al_1[3][0] - Sum_al_1[0][0] * Sum_al_1[0][0]

       - Sum_al_1[1][0] * Sum_al_1[1][0] - Sum_al_1[2][0] * Sum_al_1[2][0]

       - m_InvariantMass * m_InvariantMass;


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

       if (energy[i] == 0) {

         m_ErrorCode = KFitError::kDivisionByZero;

         KFitError::displayError(__FILE__, __LINE__, __func__, m_ErrorCode);

         break;

       }


       a = m_property[i][2];


       if (m_IsFixMass[i]) {

         double invE = 1. / energy[i];

         m_D[0][i * KFitConst::kNumber7 + 0] = 2.*(Sum_al_1[3][0] * al_1_prime[i * KFitConst::kNumber7 + 0][0] * invE - Sum_al_1[0][0]);

         m_D[0][i * KFitConst::kNumber7 + 1] = 2.*(Sum_al_1[3][0] * al_1_prime[i * KFitConst::kNumber7 + 1][0] * invE - Sum_al_1[1][0]);

         m_D[0][i * KFitConst::kNumber7 + 2] = 2.*(Sum_al_1[3][0] * al_1_prime[i * KFitConst::kNumber7 + 2][0] * invE - Sum_al_1[2][0]);

         m_D[0][i * KFitConst::kNumber7 + 3] = 0.;

         m_D[0][i * KFitConst::kNumber7 + 4] = -2.*(Sum_al_1[3][0] * al_1_prime[i * KFitConst::kNumber7 + 1][0] * invE - Sum_al_1[1][0]) * a;

         m_D[0][i * KFitConst::kNumber7 + 5] = 2.*(Sum_al_1[3][0] * al_1_prime[i * KFitConst::kNumber7 + 0][0] * invE - Sum_al_1[0][0]) * a;

         m_D[0][i * KFitConst::kNumber7 + 6] = 0.;

       } else {

         m_D[0][i * KFitConst::kNumber7 + 0] = -2.*Sum_al_1[0][0];

         m_D[0][i * KFitConst::kNumber7 + 1] = -2.*Sum_al_1[1][0];

         m_D[0][i * KFitConst::kNumber7 + 2] = -2.*Sum_al_1[2][0];

         m_D[0][i * KFitConst::kNumber7 + 3] =  2.*Sum_al_1[3][0];

         m_D[0][i * KFitConst::kNumber7 + 4] =  2.*Sum_al_1[1][0] * a;

         m_D[0][i * KFitConst::kNumber7 + 5] = -2.*Sum_al_1[0][0] * a;

         m_D[0][i * KFitConst::kNumber7 + 6] =  0.;

       }

     }


     m_D[0][KFitConst::kNumber7 * m_TrackCount + 0] = 2.*(Sum_al_1[3][0] * Sum_al_1[4][0] - Sum_al_1[1][0] * Sum_al_1[6][0]);

     m_D[0][KFitConst::kNumber7 * m_TrackCount + 1] = -2.*(Sum_al_1[3][0] * Sum_al_1[5][0] - Sum_al_1[0][0] * Sum_al_1[6][0]);

     m_D[0][KFitConst::kNumber7 * m_TrackCount + 2] = 0.;

   }


   return m_ErrorCode = KFitError::kNoError;

 }


 enum KFitError::ECode

 MassFitKFit::calculateNDF() {

   m_NDF = 1;


   return m_ErrorCode = KFitError::kNoError;

 }


 enum KFitError::ECode MassFitKFit::updateMother(Particle* mother)

 {

   MakeMotherKFit kmm;

   kmm.setMagneticField(m_MagneticField);

   unsigned n = getTrackCount();

   for (unsigned i = 0; i < n; ++i) {

     kmm.addTrack(getTrackMomentum(i), getTrackPosition(i), getTrackError(i),

                  getTrack(i).getCharge());

     if (getFlagFitWithVertex())

       kmm.setTrackVertexError(getTrackVertexError(i));

     for (unsigned j = i + 1; j < n; ++j) {

       kmm.setCorrelation(getCorrelation(i, j));

     }

   }

   kmm.setVertex(getVertex());

   if (getFlagFitWithVertex())

     kmm.setVertexError(getVertexError());

   m_ErrorCode = kmm.doMake();

   if (m_ErrorCode != KFitError::kNoError)

     return m_ErrorCode;

   double chi2 = getCHIsq();

   int ndf = getNDF();

   double prob = TMath::Prob(chi2, ndf);

   //

   bool haschi2 = mother->hasExtraInfo("chiSquared");

   if (haschi2) {

     mother->setExtraInfo("chiSquared", chi2);

     mother->setExtraInfo("ndf", ndf);

   } else {

     mother->addExtraInfo("chiSquared", chi2);

     mother->addExtraInfo("ndf", ndf);

   }


   mother->updateMomentum(

     CLHEPToROOT::getLorentzVector(kmm.getMotherMomentum()),

     CLHEPToROOT::getXYZVector(kmm.getMotherPosition()),

     CLHEPToROOT::getTMatrixFSym(kmm.getMotherError()),

     prob);

   m_ErrorCode = KFitError::kNoError;

   return m_ErrorCode;

 }

Belle2::Const::speedOfLight
static const double speedOfLight
[cm/ns]
Definition: Const.h:686

Belle2::Particle
Class to store reconstructed particles.
Definition: Particle.h:75

Belle2::analysis::KFitError::ECode
ECode
ECode is a error code enumerate.
Definition: KFitError.h:34

Belle2::analysis::MakeMotherKFit
MakeMotherKFit is a class to build mother particle from kinematically fitted daughters.
Definition: MakeMotherKFit.h:40

Belle2::analysis::MakeMotherKFit::setVertex
enum KFitError::ECode setVertex(const HepPoint3D &v)
Set a vertex position of the mother particle.
Definition: MakeMotherKFit.cc:70

Belle2::analysis::MakeMotherKFit::addTrack
enum KFitError::ECode addTrack(const KFitTrack &kp)
Add a track to the make-mother object.
Definition: MakeMotherKFit.cc:39

Belle2::analysis::MakeMotherKFit::doMake
enum KFitError::ECode doMake(void)
Perform a reconstruction of mother particle.
Definition: MakeMotherKFit.cc:191

Belle2::analysis::MakeMotherKFit::getMotherError
const CLHEP::HepSymMatrix getMotherError(void) const
Get an error matrix of the mother particle.
Definition: MakeMotherKFit.cc:184

Belle2::analysis::MakeMotherKFit::setCorrelation
enum KFitError::ECode setCorrelation(const CLHEP::HepMatrix &e)
Set a correlation matrix.
Definition: MakeMotherKFit.cc:118

Belle2::analysis::MakeMotherKFit::getMotherPosition
const HepPoint3D getMotherPosition(void) const
Get a position of the mother particle.
Definition: MakeMotherKFit.cc:177

Belle2::analysis::MakeMotherKFit::setVertexError
enum KFitError::ECode setVertexError(const CLHEP::HepSymMatrix &e)
Set a vertex error matrix of the mother particle.
Definition: MakeMotherKFit.cc:78

Belle2::analysis::MakeMotherKFit::setTrackVertexError
enum KFitError::ECode setTrackVertexError(const CLHEP::HepMatrix &e)
Set a vertex error matrix of the child particle in the addTrack'ed order.
Definition: MakeMotherKFit.cc:94

Belle2::analysis::MakeMotherKFit::getMotherMomentum
const CLHEP::HepLorentzVector getMotherMomentum(void) const
Get a Lorentz vector of the mother particle.
Definition: MakeMotherKFit.cc:170

Belle2::analysis::MakeMotherKFit::setMagneticField
enum KFitError::ECode setMagneticField(const double mf)
Change a magnetic field from the default value KFitConst::kDefaultMagneticField.
Definition: MakeMotherKFit.cc:62

HepGeom::Point3D< double >

Belle2::sqrt
double sqrt(double a)
sqrt for double
Definition: beamHelpers.h:28

Belle2
Abstract base class for different kinds of events.
Definition: MillepedeAlgorithm.h:17