ConstrainedTreeBuilder.cc

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#include "RecoVertex/KinematicFit/interface/ConstrainedTreeBuilder.h"
#include "DataFormats/CLHEP/interface/Migration.h"
#include "FWCore/MessageLogger/interface/MessageLogger.h"
 
ConstrainedTreeBuilder::ConstrainedTreeBuilder() {
  pFactory = new VirtualKinematicParticleFactory();
  vFactory = new KinematicVertexFactory();
}
 
ConstrainedTreeBuilder::~ConstrainedTreeBuilder() {
  delete pFactory;
  delete vFactory;
}
 
RefCountedKinematicTree ConstrainedTreeBuilder::buildTree(
    const std::vector<RefCountedKinematicParticle>& initialParticles,
    const std::vector<KinematicState>& finalStates,
    const RefCountedKinematicVertex vertex,
    const AlgebraicMatrix& fullCov) const {
  if (!vertex->vertexIsValid()) {
    LogDebug("ConstrainedTreeBuilder") << "Vertex is invalid\n";
    return ReferenceCountingPointer<KinematicTree>(new KinematicTree());
  }
  AlgebraicVector3 vtx;
  vtx(0) = vertex->position().x();
  vtx(1) = vertex->position().y();
  vtx(2) = vertex->position().z();
  AlgebraicMatrix33 vertexCov = asSMatrix<3, 3>(fullCov.sub(1, 3, 1, 3));
 
  // cout << fullCov<<endl;
  //  cout << "RecoVertex/ConstrainedTreeBuilder"<<vtx<<endl;
 
  double ent = 0.;
  int charge = 0;
  AlgebraicVector7 virtualPartPar;
  virtualPartPar(0) = vertex->position().x();
  virtualPartPar(1) = vertex->position().y();
  virtualPartPar(2) = vertex->position().z();
 
  //making refitted particles out of refitted states.
  //none of the operations above violates the order of particles
 
  ROOT::Math::SMatrix<double, 7, 7, ROOT::Math::MatRepStd<double, 7, 7> > aMatrix;
  aMatrix(3, 3) = 1;
  aMatrix(4, 4) = 1;
  aMatrix(5, 5) = 1;
  aMatrix(6, 6) = 1;
  ROOT::Math::SMatrix<double, 7, 3, ROOT::Math::MatRepStd<double, 7, 3> > bMatrix;
  bMatrix(0, 0) = 1;
  bMatrix(1, 1) = 1;
  bMatrix(2, 2) = 1;
  AlgebraicMatrix77 trackParCov;
  ROOT::Math::SMatrix<double, 3, 7, ROOT::Math::MatRepStd<double, 3, 7> > vtxTrackCov;
  AlgebraicMatrix77 nCovariance;
 
  std::vector<RefCountedKinematicParticle>::const_iterator i = initialParticles.begin();
  std::vector<KinematicState>::const_iterator iStates = finalStates.begin();
  std::vector<RefCountedKinematicParticle> rParticles;
  int n = 0;
  for (; i != initialParticles.end() && iStates != finalStates.end(); ++i, ++iStates) {
    AlgebraicVector7 p = iStates->kinematicParameters().vector();
    double a = -iStates->particleCharge() * iStates->magneticField()->inInverseGeV(iStates->globalPosition()).z();
 
    aMatrix(4, 0) = -a;
    aMatrix(3, 1) = a;
    bMatrix(4, 0) = a;
    bMatrix(3, 1) = -a;
 
    AlgebraicVector7 par = aMatrix * p + bMatrix * vtx;
 
    trackParCov = asSMatrix<7, 7>(fullCov.sub(4 + n * 7, 10 + n * 7, 4 + n * 7, 10 + n * 7));
    vtxTrackCov = asSMatrix<3, 7>(fullCov.sub(1, 3, 4 + n * 7, 10 + n * 7));
    ;
    nCovariance = aMatrix * trackParCov * ROOT::Math::Transpose(aMatrix) +
                  aMatrix * ROOT::Math::Transpose(vtxTrackCov) * ROOT::Math::Transpose(bMatrix) +
                  bMatrix * vtxTrackCov * ROOT::Math::Transpose(aMatrix) +
                  bMatrix * vertexCov * ROOT::Math::Transpose(bMatrix);
 
    KinematicState stateAtVertex(KinematicParameters(par),
                                 KinematicParametersError(AlgebraicSymMatrix77(nCovariance.LowerBlock())),
                                 iStates->particleCharge(),
                                 iStates->magneticField());
    rParticles.push_back((*i)->refittedParticle(stateAtVertex, vertex->chiSquared(), vertex->degreesOfFreedom()));
 
    virtualPartPar(3) += par(3);
    virtualPartPar(4) += par(4);
    virtualPartPar(5) += par(5);
    ent += sqrt(par(6) * par(6) + par(3) * par(3) + par(4) * par(4) + par(5) * par(5));
    charge += iStates->particleCharge();
 
    ++n;
  }
 
  //total reconstructed mass
  double differ = ent * ent - (virtualPartPar(3) * virtualPartPar(3) + virtualPartPar(5) * virtualPartPar(5) +
                               virtualPartPar(4) * virtualPartPar(4));
  if (differ > 0.) {
    virtualPartPar(6) = sqrt(differ);
  } else {
    LogDebug("ConstrainedTreeBuilder") << "Fit failed: Current precision does not allow to calculate the mass\n";
    return ReferenceCountingPointer<KinematicTree>(new KinematicTree());
  }
 
  // covariance matrix:
 
  AlgebraicMatrix77 cov = asSMatrix<7, 7>(covarianceMatrix(rParticles, virtualPartPar, fullCov));
 
  KinematicState nState(KinematicParameters(virtualPartPar),
                        KinematicParametersError(AlgebraicSymMatrix77(cov.LowerBlock())),
                        charge,
                        initialParticles[0]->magneticField());
 
  //newborn kinematic particle
  float chi2 = vertex->chiSquared();
  float ndf = vertex->degreesOfFreedom();
  KinematicParticle* zp = nullptr;
  RefCountedKinematicParticle virtualParticle = pFactory->particle(nState, chi2, ndf, zp);
 
  return buildTree(virtualParticle, vertex, rParticles);
}
 
RefCountedKinematicTree ConstrainedTreeBuilder::buildTree(
    const RefCountedKinematicParticle virtualParticle,
    const RefCountedKinematicVertex vtx,
    const std::vector<RefCountedKinematicParticle>& particles) const {
  //making a resulting tree:
  RefCountedKinematicTree resTree = ReferenceCountingPointer<KinematicTree>(new KinematicTree());
 
  //fake production vertex:
  RefCountedKinematicVertex fVertex = vFactory->vertex();
  resTree->addParticle(fVertex, vtx, virtualParticle);
 
  //adding final state
  for (std::vector<RefCountedKinematicParticle>::const_iterator il = particles.begin(); il != particles.end(); il++) {
    if ((*il)->previousParticle()->correspondingTree() != nullptr) {
      KinematicTree* tree = (*il)->previousParticle()->correspondingTree();
      tree->movePointerToTheTop();
      tree->replaceCurrentParticle(*il);
      RefCountedKinematicVertex cdVertex = resTree->currentDecayVertex();
      resTree->addTree(cdVertex, tree);
    } else {
      RefCountedKinematicVertex ffVertex = vFactory->vertex();
      resTree->addParticle(vtx, ffVertex, *il);
    }
  }
  return resTree;
}
 
AlgebraicMatrix ConstrainedTreeBuilder::covarianceMatrix(const std::vector<RefCountedKinematicParticle>& rPart,
                                                         const AlgebraicVector7& newPar,
                                                         const AlgebraicMatrix& fitCov) const {
  //constructing the full matrix using the simple fact
  //that we have never broken the order of tracks
  // during our fit.
 
  int size = rPart.size();
  //global propagation to the vertex position
  //Jacobian is done for all the parameters together
  AlgebraicMatrix jac(3 + 7 * size, 3 + 7 * size, 0);
  jac(1, 1) = 1;
  jac(2, 2) = 1;
  jac(3, 3) = 1;
  int i_int = 0;
  for (std::vector<RefCountedKinematicParticle>::const_iterator i = rPart.begin(); i != rPart.end(); i++) {
    //vertex position related components of the matrix
    double a_i = -(*i)->currentState().particleCharge() *
                 (*i)->magneticField()->inInverseGeV((*i)->currentState().globalPosition()).z();
 
    AlgebraicMatrix upper(3, 7, 0);
    AlgebraicMatrix diagonal(7, 7, 0);
    upper(1, 1) = 1;
    upper(2, 2) = 1;
    upper(3, 3) = 1;
    upper(2, 4) = -a_i;
    upper(1, 5) = a_i;
    jac.sub(1, 4 + i_int * 7, upper);
 
    diagonal(4, 4) = 1;
    diagonal(5, 5) = 1;
    diagonal(6, 6) = 1;
    diagonal(7, 7) = 1;
    diagonal(2, 4) = a_i;
    diagonal(1, 5) = -a_i;
    jac.sub(4 + i_int * 7, 4 + i_int * 7, diagonal);
    i_int++;
  }
 
  // jacobian is constructed in such a way, that
  // right operation for transformation will be
  // fitCov.similarityT(jac)
  // WARNING: normal similarity operation is
  // not valid in this case
  //now making reduced matrix:
  int vSize = rPart.size();
  AlgebraicSymMatrix fit_cov_sym(7 * vSize + 3, 0);
  for (int i = 1; i < 7 * vSize + 4; ++i) {
    for (int j = 1; j < 7 * vSize + 4; ++j) {
      if (i <= j)
        fit_cov_sym(i, j) = fitCov(i, j);
    }
  }
 
  AlgebraicMatrix reduced(3 + 4 * size, 3 + 4 * size, 0);
  AlgebraicMatrix transform = fit_cov_sym.similarityT(jac);
 
  //jacobian to add matrix components
  AlgebraicMatrix jac_t(7, 7 + 4 * (size - 1));
  jac_t(1, 1) = 1.;
  jac_t(2, 2) = 1.;
  jac_t(3, 3) = 1.;
 
  //debug code:
  //CLHEP bugs: avoiding the
  // HepMatrix::sub method use
  AlgebraicMatrix reduced_tm(7, 7, 0);
  for (int i = 1; i < 8; ++i) {
    for (int j = 1; j < 8; ++j) {
      reduced_tm(i, j) = transform(i + 3, j + 3);
    }
  }
 
  //left top corner
  // reduced.sub(1,1,transform.sub(4,10,4,10));
 
  //debug code:
  //CLHEP bugs: avoiding the
  // HepMatrix::sub method use
  reduced.sub(1, 1, reduced_tm);
 
  // cout<<"reduced matrix"<<reduced<<endl;
  int il_int = 0;
  double energy_global =
      sqrt(newPar(3) * newPar(3) + newPar(4) * newPar(4) + newPar(5) * newPar(5) + newPar(6) * newPar(6));
  for (std::vector<RefCountedKinematicParticle>::const_iterator rs = rPart.begin(); rs != rPart.end(); rs++) {
    //jacobian components:
    AlgebraicMatrix jc_el(4, 4, 0);
    jc_el(1, 1) = 1.;
    jc_el(2, 2) = 1.;
    jc_el(3, 3) = 1.;
 
    //non-trival elements: mass correlations:
    AlgebraicVector7 l_Par = (*rs)->currentState().kinematicParameters().vector();
    double energy_local = sqrt(l_Par(6) * l_Par(6) + l_Par(3) * l_Par(3) + l_Par(4) * l_Par(4) + l_Par(5) * l_Par(5));
    jc_el(4, 4) = energy_global * l_Par(6) / (newPar(6) * energy_local);
    jc_el(4, 1) = ((energy_global * l_Par(3) / energy_local) - newPar(3)) / newPar(6);
    jc_el(4, 2) = ((energy_global * l_Par(4) / energy_local) - newPar(4)) / newPar(6);
    jc_el(4, 3) = ((energy_global * l_Par(5) / energy_local) - newPar(5)) / newPar(6);
    jac_t.sub(4, il_int * 4 + 4, jc_el);
    il_int++;
  }
  // cout<<"jac_t"<<jac_t<<endl;
  //debug code
  //CLHEP bugs workaround
  // cout<<"Transform matrix"<< transform<<endl;
 
  for (int i = 1; i < size; i++) {
    //non-trival elements: mass correlations:
    //upper row and right column
    AlgebraicMatrix transform_sub1(3, 4, 0);
    AlgebraicMatrix transform_sub2(4, 3, 0);
    for (int l1 = 1; l1 < 4; ++l1) {
      for (int l2 = 1; l2 < 5; ++l2) {
        transform_sub1(l1, l2) = transform(3 + l1, 6 + 7 * i + l2);
      }
    }
 
    for (int l1 = 1; l1 < 5; ++l1) {
      for (int l2 = 1; l2 < 4; ++l2) {
        transform_sub2(l1, l2) = transform(6 + 7 * i + l1, 3 + l2);
      }
    }
 
    AlgebraicMatrix transform_sub3(4, 4, 0);
    for (int l1 = 1; l1 < 5; ++l1) {
      for (int l2 = 1; l2 < 5; ++l2) {
        transform_sub3(l1, l2) = transform(6 + 7 * i + l1, 6 + 7 * i + l2);
      }
    }
 
    reduced.sub(1, 4 + 4 * i, transform_sub1);
    reduced.sub(4 + 4 * i, 1, transform_sub2);
 
    //diagonal elements
    reduced.sub(4 + 4 * i, 4 + 4 * i, transform_sub3);
 
    //off diagonal elements
    for (int j = 1; j < size; j++) {
      AlgebraicMatrix transform_sub4(4, 4, 0);
      AlgebraicMatrix transform_sub5(4, 4, 0);
      for (int l1 = 1; l1 < 5; ++l1) {
        for (int l2 = 1; l2 < 5; ++l2) {
          transform_sub4(l1, l2) = transform(6 + 7 * (i - 1) + l1, 6 + 7 * j + l2);
          transform_sub5(l1, l2) = transform(6 + 7 * j + l1, 6 + 7 * (i - 1) + l2);
        }
      }
      reduced.sub(4 + 4 * (i - 1), 4 + 4 * j, transform_sub4);
      reduced.sub(4 + 4 * j, 4 + 4 * (i - 1), transform_sub5);
    }
  }
 
  return jac_t * reduced * jac_t.T();
}