trklet::TrackletCalculatorBase Class Reference

#include <TrackletCalculatorBase.h>

Inheritance diagram for trklet::TrackletCalculatorBase:

Public Member Functions
void	addDiskProj (Tracklet *tracklet, int disk)
bool	addLayerProj (Tracklet *tracklet, int layer)
void	addProjection (int layer, int iphi, TrackletProjectionsMemory *trackletprojs, Tracklet *tracklet)
void	addProjectionDisk (int disk, int iphi, TrackletProjectionsMemory *trackletprojs, Tracklet *tracklet)
bool	barrelSeeding (const Stub *innerFPGAStub, const L1TStub *innerStub, const Stub *outerFPGAStub, const L1TStub *outerStub)
bool	diskSeeding (const Stub *innerFPGAStub, const L1TStub *innerStub, const Stub *outerFPGAStub, const L1TStub *outerStub)
void	exactproj (double rproj, double rinv, double phi0, double t, double z0, double &phiproj, double &zproj, double &phider, double &zder)
void	exactprojdisk (double zproj, double rinv, double phi0, double t, double z0, double &phiproj, double &rproj, double &phider, double &rder)
void	exacttracklet (double r1, double z1, double phi1, double r2, double z2, double phi2, double, double &rinv, double &phi0, double &t, double &z0, double phiproj[N_LAYER - 2], double zproj[N_LAYER - 2], double phider[N_LAYER - 2], double zder[N_LAYER - 2], double phiprojdisk[N_DISK], double rprojdisk[N_DISK], double phiderdisk[N_DISK], double rderdisk[N_DISK])
void	exacttrackletdisk (double r1, double z1, double phi1, double r2, double z2, double phi2, double, double &rinv, double &phi0, double &t, double &z0, double phiprojLayer[N_PSLAYER], double zprojLayer[N_PSLAYER], double phiderLayer[N_PSLAYER], double zderLayer[N_PSLAYER], double phiproj[N_DISK - 2], double rproj[N_DISK - 2], double phider[N_DISK - 2], double rder[N_DISK - 2])
void	exacttrackletOverlap (double r1, double z1, double phi1, double r2, double z2, double phi2, double, double &rinv, double &phi0, double &t, double &z0, double phiprojLayer[N_PSLAYER], double zprojLayer[N_PSLAYER], double phiderLayer[N_PSLAYER], double zderLayer[N_PSLAYER], double phiproj[N_DISK - 2], double rproj[N_DISK - 2], double phider[N_DISK - 2], double rder[N_DISK - 2])
bool	goodTrackPars (bool goodrinv, bool goodz0)
bool	inSector (int iphi0, int irinv, double phi0approx, double rinvapprox)
bool	overlapSeeding (const Stub *innerFPGAStub, const L1TStub *innerStub, const Stub *outerFPGAStub, const L1TStub *outerStub)
	TrackletCalculatorBase (std::string name, Settings const &settings, Globals *global, unsigned int iSector)
	~TrackletCalculatorBase () override=default
Public Member Functions inherited from trklet::ProcessBase
virtual void	addInput (MemoryBase *memory, std::string input)=0
virtual void	addOutput (MemoryBase *memory, std::string output)=0
unsigned int	getISeed (std::string name)
std::string const &	getName () const
unsigned int	initLayerDisk (unsigned int pos)
void	initLayerDisk (unsigned int pos, int &layer, int &disk)
void	initLayerDisk (unsigned int pos, int &layer, int &disk, int &layerdisk)
void	initLayerDisksandISeed (unsigned int &layerdisk1, unsigned int &layerdisk2, unsigned int &iSeed)
unsigned int	nbits (unsigned int power)
	ProcessBase (std::string name, Settings const &settings, Globals *global, unsigned int iSector)
virtual	~ProcessBase ()=default

Protected Attributes
int	disk_
unsigned int	iSeed_
int	layer_
unsigned int	layerdisk1_
unsigned int	layerdisk2_
double	phioffset_
int	TCIndex_
TrackletParametersMemory *	trackletpars_
std::vector< std::vector< TrackletProjectionsMemory * > >	trackletprojdisks_
std::vector< std::vector< TrackletProjectionsMemory * > >	trackletprojlayers_
Protected Attributes inherited from trklet::ProcessBase
Globals *	globals_
unsigned int	iSector_
std::string	name_
double	phimax_
double	phimin_
Settings const &	settings_

Detailed Description

Definition at line 18 of file TrackletCalculatorBase.h.

Constructor & Destructor Documentation

TrackletCalculatorBase()

TrackletCalculatorBase::TrackletCalculatorBase	(	std::string	name,
		Settings const &	settings,
		Globals *	global,
		unsigned int	iSector
	)

Definition at line 17 of file TrackletCalculatorBase.cc.

    : ProcessBase(name, settings, global, iSector) {}

~TrackletCalculatorBase()

trklet::TrackletCalculatorBase::~TrackletCalculatorBase ( )

overridedefault

Member Function Documentation

addDiskProj()

void TrackletCalculatorBase::addDiskProj	(	Tracklet *	tracklet,
		int	disk
	)

Definition at line 213 of file TrackletCalculatorBase.cc.

                                                                     {
  FPGAWord fpgar = tracklet->fpgarprojdisk(disk);
 
  if (fpgar.value() * settings_.krprojshiftdisk() < settings_.rmindiskvm())
    return;
  if (fpgar.value() * settings_.krprojshiftdisk() > settings_.rmaxdisk())
    return;
 
  FPGAWord fpgaphi = tracklet->fpgaphiprojdisk(disk);
 
  int iphivmRaw = fpgaphi.value() >> (fpgaphi.nbits() - 5);
 
  int iphi = iphivmRaw / (32 / settings_.nallstubs(abs(disk) + N_DISK));
 
  addProjectionDisk(disk, iphi, trackletprojdisks_[abs(disk) - 1][iphi], tracklet);
}

References funct::abs(), addProjectionDisk(), trklet::Tracklet::fpgaphiprojdisk(), trklet::Tracklet::fpgarprojdisk(), LEDCalibrationChannels::iphi, trklet::Settings::krprojshiftdisk(), trklet::N_DISK, trklet::Settings::nallstubs(), trklet::FPGAWord::nbits(), trklet::Settings::rmaxdisk(), trklet::Settings::rmindiskvm(), trklet::ProcessBase::settings_, trackletprojdisks_, and trklet::FPGAWord::value().

Referenced by barrelSeeding(), diskSeeding(), and overlapSeeding().

addLayerProj()

bool TrackletCalculatorBase::addLayerProj	(	Tracklet *	tracklet,
		int	layer
	)

Definition at line 230 of file TrackletCalculatorBase.cc.

                                                                       {
  assert(layer > 0);
 
  FPGAWord fpgaz = tracklet->fpgazproj(layer);
  FPGAWord fpgaphi = tracklet->fpgaphiproj(layer);
 
  if (fpgaphi.atExtreme())
    edm::LogProblem("Tracklet") << "at extreme! " << fpgaphi.value();
 
  assert(!fpgaphi.atExtreme());
 
  if (fpgaz.atExtreme())
    return false;
 
  if (std::abs(fpgaz.value() * settings_.kz()) > settings_.zlength())
    return false;
 
  int iphivmRaw = fpgaphi.value() >> (fpgaphi.nbits() - 5);
  int iphi = iphivmRaw / (32 / settings_.nallstubs(layer - 1));
 
  addProjection(layer, iphi, trackletprojlayers_[layer - 1][iphi], tracklet);
 
  return true;
}

References funct::abs(), addProjection(), cms::cuda::assert(), trklet::FPGAWord::atExtreme(), trklet::Tracklet::fpgaphiproj(), trklet::Tracklet::fpgazproj(), LEDCalibrationChannels::iphi, trklet::Settings::kz(), trklet::Settings::nallstubs(), trklet::FPGAWord::nbits(), trklet::ProcessBase::settings_, trackletprojlayers_, trklet::FPGAWord::value(), and trklet::Settings::zlength().

Referenced by barrelSeeding(), diskSeeding(), and overlapSeeding().

addProjection()

void TrackletCalculatorBase::addProjection	(	int	layer,
		int	iphi,
		TrackletProjectionsMemory *	trackletprojs,
		Tracklet *	tracklet
	)

Definition at line 255 of file TrackletCalculatorBase.cc.

                                                               {
  if (trackletprojs == nullptr) {
    if (settings_.warnNoMem()) {
      edm::LogVerbatim("Tracklet") << "No projection memory exists in " << getName() << " for layer = " << layer
                                   << " iphi = " << iphi + 1;
    }
    return;
  }
  assert(trackletprojs != nullptr);
  trackletprojs->addProj(tracklet);
}

References trklet::TrackletProjectionsMemory::addProj(), cms::cuda::assert(), trklet::ProcessBase::getName(), LEDCalibrationChannels::iphi, trklet::ProcessBase::settings_, and trklet::Settings::warnNoMem().

Referenced by addLayerProj().

addProjectionDisk()

void TrackletCalculatorBase::addProjectionDisk	(	int	disk,
		int	iphi,
		TrackletProjectionsMemory *	trackletprojs,
		Tracklet *	tracklet
	)

Definition at line 270 of file TrackletCalculatorBase.cc.

                                                                   {
  if (iSeed_ == 2 && abs(disk) == 4)
    return;  //L3L4 projections to D3 are not used. Should be in configuration
  if (trackletprojs == nullptr) {
    if (iSeed_ == 2 && abs(disk) == 3)
      return;  //L3L4 projections to D3 are not used.
    if (settings_.warnNoMem()) {
      edm::LogVerbatim("Tracklet") << "No projection memory exists in " << getName() << " for disk = " << abs(disk)
                                   << " iphi = " << iphi + 1;
    }
    return;
  }
  assert(trackletprojs != nullptr);
  trackletprojs->addProj(tracklet);
}

References funct::abs(), trklet::TrackletProjectionsMemory::addProj(), cms::cuda::assert(), trklet::ProcessBase::getName(), LEDCalibrationChannels::iphi, iSeed_, trklet::ProcessBase::settings_, and trklet::Settings::warnNoMem().

Referenced by addDiskProj().

barrelSeeding()

bool TrackletCalculatorBase::barrelSeeding	(	const Stub *	innerFPGAStub,
		const L1TStub *	innerStub,
		const Stub *	outerFPGAStub,
		const L1TStub *	outerStub
	)

Definition at line 331 of file TrackletCalculatorBase.cc.

                                                                     {
  if (settings_.debugTracklet()) {
    edm::LogVerbatim("Tracklet") << "TrackletCalculator " << getName()
                                 << " trying stub pair in layer (inner outer): " << innerFPGAStub->layer().value()
                                 << " " << outerFPGAStub->layer().value();
  }
 
  assert(outerFPGAStub->isBarrel());
  assert(layerdisk1_ == (unsigned int)innerFPGAStub->layer().value());
  assert(layerdisk1_ < N_LAYER && layerdisk2_ < N_LAYER);
 
  double r1 = innerStub->r();
  double z1 = innerStub->z();
  double phi1 = innerStub->phi();
 
  double r2 = outerStub->r();
  double z2 = outerStub->z();
  double phi2 = outerStub->phi();
 
  double rinv, phi0, t, z0;
 
  double phiproj[N_LAYER - 2], zproj[N_LAYER - 2], phider[N_LAYER - 2], zder[N_LAYER - 2];
  double phiprojdisk[N_DISK], rprojdisk[N_DISK], phiderdisk[N_DISK], rderdisk[N_DISK];
 
  exacttracklet(r1,
                z1,
                phi1,
                r2,
                z2,
                phi2,
                outerStub->sigmaz(),
                rinv,
                phi0,
                t,
                z0,
                phiproj,
                zproj,
                phider,
                zder,
                phiprojdisk,
                rprojdisk,
                phiderdisk,
                rderdisk);
 
  if (settings_.useapprox()) {
    phi1 = innerFPGAStub->phiapprox(phimin_, phimax_);
    z1 = innerFPGAStub->zapprox();
    r1 = innerFPGAStub->rapprox();
 
    phi2 = outerFPGAStub->phiapprox(phimin_, phimax_);
    z2 = outerFPGAStub->zapprox();
    r2 = outerFPGAStub->rapprox();
  }
 
  double rinvapprox, phi0approx, tapprox, z0approx;
  double phiprojapprox[N_LAYER - 2], zprojapprox[N_LAYER - 2];
  double phiprojdiskapprox[N_DISK], rprojdiskapprox[N_DISK];
 
  IMATH_TrackletCalculator* ITC;
  if (iSeed_ == 0)
    ITC = globals_->ITC_L1L2();
  else if (iSeed_ == 1)
    ITC = globals_->ITC_L2L3();
  else if (iSeed_ == 2)
    ITC = globals_->ITC_L3L4();
  else
    ITC = globals_->ITC_L5L6();
 
  ITC->r1.set_fval(r1 - settings_.rmean(layerdisk1_));
  ITC->r2.set_fval(r2 - settings_.rmean(layerdisk2_));
  ITC->z1.set_fval(z1);
  ITC->z2.set_fval(z2);
  double sphi1 = angle0to2pi::make0To2pi(phi1 - phioffset_);
  double sphi2 = angle0to2pi::make0To2pi(phi2 - phioffset_);
 
  ITC->phi1.set_fval(sphi1);
  ITC->phi2.set_fval(sphi2);
 
  ITC->rproj0.set_fval(settings_.rmean(settings_.projlayers(iSeed_, 0) - 1));
  ITC->rproj1.set_fval(settings_.rmean(settings_.projlayers(iSeed_, 1) - 1));
  ITC->rproj2.set_fval(settings_.rmean(settings_.projlayers(iSeed_, 2) - 1));
  ITC->rproj3.set_fval(settings_.rmean(settings_.projlayers(iSeed_, 3) - 1));
 
  ITC->zproj0.set_fval(t > 0 ? settings_.zmean(0) : -settings_.zmean(0));
  ITC->zproj1.set_fval(t > 0 ? settings_.zmean(1) : -settings_.zmean(1));
  ITC->zproj2.set_fval(t > 0 ? settings_.zmean(2) : -settings_.zmean(2));
  ITC->zproj3.set_fval(t > 0 ? settings_.zmean(3) : -settings_.zmean(3));
  ITC->zproj4.set_fval(t > 0 ? settings_.zmean(4) : -settings_.zmean(4));
 
  ITC->rinv_final.calculate();
  ITC->phi0_final.calculate();
  ITC->t_final.calculate();
  ITC->z0_final.calculate();
 
  ITC->phiL_0_final.calculate();
  ITC->phiL_1_final.calculate();
  ITC->phiL_2_final.calculate();
  ITC->phiL_3_final.calculate();
 
  ITC->zL_0_final.calculate();
  ITC->zL_1_final.calculate();
  ITC->zL_2_final.calculate();
  ITC->zL_3_final.calculate();
 
  ITC->phiD_0_final.calculate();
  ITC->phiD_1_final.calculate();
  ITC->phiD_2_final.calculate();
  ITC->phiD_3_final.calculate();
  ITC->phiD_4_final.calculate();
 
  ITC->rD_0_final.calculate();
  ITC->rD_1_final.calculate();
  ITC->rD_2_final.calculate();
  ITC->rD_3_final.calculate();
  ITC->rD_4_final.calculate();
 
  ITC->der_phiL_final.calculate();
  ITC->der_zL_final.calculate();
  ITC->der_phiD_final.calculate();
  ITC->der_rD_final.calculate();
 
  //store the approximate results
  rinvapprox = ITC->rinv_final.fval();
  phi0approx = ITC->phi0_final.fval();
  tapprox = ITC->t_final.fval();
  z0approx = ITC->z0_final.fval();
 
  phiprojapprox[0] = ITC->phiL_0_final.fval();
  phiprojapprox[1] = ITC->phiL_1_final.fval();
  phiprojapprox[2] = ITC->phiL_2_final.fval();
  phiprojapprox[3] = ITC->phiL_3_final.fval();
 
  zprojapprox[0] = ITC->zL_0_final.fval();
  zprojapprox[1] = ITC->zL_1_final.fval();
  zprojapprox[2] = ITC->zL_2_final.fval();
  zprojapprox[3] = ITC->zL_3_final.fval();
 
  phiprojdiskapprox[0] = ITC->phiD_0_final.fval();
  phiprojdiskapprox[1] = ITC->phiD_1_final.fval();
  phiprojdiskapprox[2] = ITC->phiD_2_final.fval();
  phiprojdiskapprox[3] = ITC->phiD_3_final.fval();
  phiprojdiskapprox[4] = ITC->phiD_4_final.fval();
 
  rprojdiskapprox[0] = ITC->rD_0_final.fval();
  rprojdiskapprox[1] = ITC->rD_1_final.fval();
  rprojdiskapprox[2] = ITC->rD_2_final.fval();
  rprojdiskapprox[3] = ITC->rD_3_final.fval();
  rprojdiskapprox[4] = ITC->rD_4_final.fval();
 
  //now binary
 
  int irinv, iphi0, it, iz0;
  LayerProjection layerprojs[N_LAYER - 2];
  DiskProjection diskprojs[N_DISK];
 
  int iphiproj[N_LAYER - 2], izproj[N_LAYER - 2];
  int iphiprojdisk[N_DISK], irprojdisk[N_DISK];
 
  int ir1 = innerFPGAStub->r().value();
  int iphi1 = innerFPGAStub->phi().value();
  int iz1 = innerFPGAStub->z().value();
 
  int ir2 = outerFPGAStub->r().value();
  int iphi2 = outerFPGAStub->phi().value();
  int iz2 = outerFPGAStub->z().value();
 
  iphi1 <<= (settings_.nphibitsstub(5) - settings_.nphibitsstub(layerdisk1_));
  iphi2 <<= (settings_.nphibitsstub(5) - settings_.nphibitsstub(layerdisk2_));
  ir1 <<= (8 - settings_.nrbitsstub(layerdisk1_));
  ir2 <<= (8 - settings_.nrbitsstub(layerdisk2_));
 
  iz1 <<= (settings_.nzbitsstub(0) - settings_.nzbitsstub(layerdisk1_));
  iz2 <<= (settings_.nzbitsstub(0) - settings_.nzbitsstub(layerdisk2_));
 
  ITC->r1.set_ival(ir1);
  ITC->r2.set_ival(ir2);
  ITC->z1.set_ival(iz1);
  ITC->z2.set_ival(iz2);
  ITC->phi1.set_ival(iphi1);
  ITC->phi2.set_ival(iphi2);
 
  ITC->rinv_final.calculate();
  ITC->phi0_final.calculate();
  ITC->t_final.calculate();
  ITC->z0_final.calculate();
 
  ITC->phiL_0_final.calculate();
  ITC->phiL_1_final.calculate();
  ITC->phiL_2_final.calculate();
  ITC->phiL_3_final.calculate();
 
  ITC->zL_0_final.calculate();
  ITC->zL_1_final.calculate();
  ITC->zL_2_final.calculate();
  ITC->zL_3_final.calculate();
 
  ITC->phiD_0_final.calculate();
  ITC->phiD_1_final.calculate();
  ITC->phiD_2_final.calculate();
  ITC->phiD_3_final.calculate();
  ITC->phiD_4_final.calculate();
 
  ITC->rD_0_final.calculate();
  ITC->rD_1_final.calculate();
  ITC->rD_2_final.calculate();
  ITC->rD_3_final.calculate();
  ITC->rD_4_final.calculate();
 
  ITC->der_phiL_final.calculate();
  ITC->der_zL_final.calculate();
  ITC->der_phiD_final.calculate();
  ITC->der_rD_final.calculate();
 
  //store the binary results
  irinv = ITC->rinv_final.ival();
  iphi0 = ITC->phi0_final.ival();
  it = ITC->t_final.ival();
  iz0 = ITC->z0_final.ival();
 
  iphiproj[0] = ITC->phiL_0_final.ival();
  iphiproj[1] = ITC->phiL_1_final.ival();
  iphiproj[2] = ITC->phiL_2_final.ival();
  iphiproj[3] = ITC->phiL_3_final.ival();
 
  izproj[0] = ITC->zL_0_final.ival();
  izproj[1] = ITC->zL_1_final.ival();
  izproj[2] = ITC->zL_2_final.ival();
  izproj[3] = ITC->zL_3_final.ival();
 
  if (!goodTrackPars(ITC->rinv_final.local_passes(), ITC->z0_final.local_passes()))
    return false;
 
  if (!inSector(iphi0, irinv, phi0approx, rinvapprox))
    return false;
 
  for (unsigned int i = 0; i < N_LAYER - 2; ++i) {
    //reject projection if z is out of range
    if (izproj[i] < -(1 << (settings_.nzbitsstub(0) - 1)))
      continue;
    if (izproj[i] >= (1 << (settings_.nzbitsstub(0) - 1)))
      continue;
 
    //reject projection if phi is out of range
    if (iphiproj[i] >= (1 << settings_.nphibitsstub(5)) - 1)
      continue;
    if (iphiproj[i] <= 0)
      continue;
 
    //Adjust bits for r and z projection depending on layer
    if (settings_.projlayers(iSeed_, i) <= 3) {  //TODO clean up logic
      iphiproj[i] >>= (settings_.nphibitsstub(5) - settings_.nphibitsstub(settings_.projlayers(iSeed_, i) - 1));
    } else {
      izproj[i] >>= (settings_.nzbitsstub(0) - settings_.nzbitsstub(5));
    }
 
    layerprojs[i].init(settings_,
                       settings_.projlayers(iSeed_, i),
                       settings_.rmean(settings_.projlayers(iSeed_, i) - 1),
                       iphiproj[i],
                       izproj[i],
                       ITC->der_phiL_final.ival(),
                       ITC->der_zL_final.ival(),
                       phiproj[i],
                       zproj[i],
                       phider[i],
                       zder[i],
                       phiprojapprox[i],
                       zprojapprox[i],
                       ITC->der_phiL_final.fval(),
                       ITC->der_zL_final.fval());
  }
 
  iphiprojdisk[0] = ITC->phiD_0_final.ival();
  iphiprojdisk[1] = ITC->phiD_1_final.ival();
  iphiprojdisk[2] = ITC->phiD_2_final.ival();
  iphiprojdisk[3] = ITC->phiD_3_final.ival();
  iphiprojdisk[4] = ITC->phiD_4_final.ival();
 
  irprojdisk[0] = ITC->rD_0_final.ival();
  irprojdisk[1] = ITC->rD_1_final.ival();
  irprojdisk[2] = ITC->rD_2_final.ival();
  irprojdisk[3] = ITC->rD_3_final.ival();
  irprojdisk[4] = ITC->rD_4_final.ival();
 
  if (std::abs(it * ITC->t_final.K()) > 1.0) {
    for (unsigned int i = 0; i < N_DISK; ++i) {
      if (iphiprojdisk[i] <= 0)
        continue;
      if (iphiprojdisk[i] >= (1 << settings_.nphibitsstub(0)) - 1)
        continue;
 
      if (irprojdisk[i] < settings_.rmindisk() / ITC->rD_0_final.K() ||
          irprojdisk[i] > settings_.rmaxdisk() / ITC->rD_0_final.K())
        continue;
 
      diskprojs[i].init(settings_,
                        i + 1,
                        settings_.zmean(i),
                        iphiprojdisk[i],
                        irprojdisk[i],
                        ITC->der_phiD_final.ival(),
                        ITC->der_rD_final.ival(),
                        phiprojdisk[i],
                        rprojdisk[i],
                        phiderdisk[i],
                        rderdisk[i],
                        phiprojdiskapprox[i],
                        rprojdiskapprox[i],
                        ITC->der_phiD_final.fval(),
                        ITC->der_rD_final.fval());
    }
  }
 
  if (settings_.writeMonitorData("TPars")) {
    globals_->ofstream("trackletpars.txt")
        << "Trackpars " << layerdisk1_ + 1 << "   " << rinv << " " << rinvapprox << " " << ITC->rinv_final.fval()
        << "   " << phi0 << " " << phi0approx << " " << ITC->phi0_final.fval() << "   " << t << " " << tapprox << " "
        << ITC->t_final.fval() << "   " << z0 << " " << z0approx << " " << ITC->z0_final.fval() << endl;
  }
 
  Tracklet* tracklet = new Tracklet(settings_,
                                    innerStub,
                                    nullptr,
                                    outerStub,
                                    innerFPGAStub,
                                    nullptr,
                                    outerFPGAStub,
                                    rinv,
                                    phi0,
                                    0.0,
                                    z0,
                                    t,
                                    rinvapprox,
                                    phi0approx,
                                    0.0,
                                    z0approx,
                                    tapprox,
                                    irinv,
                                    iphi0,
                                    0,
                                    iz0,
                                    it,
                                    layerprojs,
                                    diskprojs,
                                    false);
 
  if (settings_.debugTracklet()) {
    edm::LogVerbatim("Tracklet") << "TrackletCalculator " << getName() << " Found tracklet for seed = " << iSeed_ << " "
                                 << iSector_ << " phi0 = " << phi0;
  }
 
  tracklet->setTrackletIndex(trackletpars_->nTracklets());
  tracklet->setTCIndex(TCIndex_);
 
  if (settings_.writeMonitorData("Seeds")) {
    ofstream fout("seeds.txt", ofstream::app);
    fout << __FILE__ << ":" << __LINE__ << " " << name_ << "_" << iSector_ << " " << tracklet->getISeed() << endl;
    fout.close();
  }
  trackletpars_->addTracklet(tracklet);
 
  if (settings_.bookHistos()) {
    HistBase* hists = globals_->histograms();
    int tp = tracklet->tpseed();
    hists->fillTrackletParams(settings_,
                              globals_,
                              iSeed_,
                              iSector_,
                              rinvapprox,
                              irinv * ITC->rinv_final.K(),
                              phi0approx,
                              iphi0 * ITC->phi0_final.K(),
                              asinh(tapprox),
                              asinh(it * ITC->t_final.K()),
                              z0approx,
                              iz0 * ITC->z0_final.K(),
                              tp);
  }
 
  bool addL3 = false;
  bool addL4 = false;
  bool addL5 = false;
  bool addL6 = false;
  for (unsigned int j = 0; j < N_LAYER - 2; j++) {
    int lproj = settings_.projlayers(iSeed_, j);
    bool added = false;
    if (tracklet->validProj(lproj)) {
      added = addLayerProj(tracklet, lproj);
      if (added && lproj == 3)
        addL3 = true;
      if (added && lproj == 4)
        addL4 = true;
      if (added && lproj == 5)
        addL5 = true;
      if (added && lproj == 6)
        addL6 = true;
    }
  }
 
  for (unsigned int j = 0; j < N_DISK - 1; j++) {  //no projections to 5th disk!!
    int disk = j + 1;
    if (disk == 4 && addL3)
      continue;
    if (disk == 3 && addL4)
      continue;
    if (disk == 2 && addL5)
      continue;
    if (disk == 1 && addL6)
      continue;
    if (it < 0)
      disk = -disk;
    if (tracklet->validProjDisk(abs(disk))) {
      addDiskProj(tracklet, disk);
    }
  }
 
  return true;
}

References funct::abs(), addDiskProj(), addLayerProj(), trklet::TrackletParametersMemory::addTracklet(), cms::cuda::assert(), trklet::Settings::bookHistos(), trklet::VarBase::calculate(), trklet::Settings::debugTracklet(), trklet::IMATH_TrackletCalculator::der_phiD_final, trklet::IMATH_TrackletCalculator::der_phiL_final, trklet::IMATH_TrackletCalculator::der_rD_final, trklet::IMATH_TrackletCalculator::der_zL_final, exacttracklet(), groupFilesInBlocks::fout, trklet::VarBase::fval(), trklet::Tracklet::getISeed(), trklet::ProcessBase::getName(), trklet::ProcessBase::globals_, goodTrackPars(), trklet::Globals::histograms(), compare::hists, mps_fire::i, trklet::LayerProjection::init(), trklet::DiskProjection::init(), inSector(), trklet::Stub::isBarrel(), trklet::ProcessBase::iSector_, iSeed_, trklet::Globals::ITC_L1L2(), trklet::Globals::ITC_L2L3(), trklet::Globals::ITC_L3L4(), trklet::Globals::ITC_L5L6(), trklet::VarBase::ival(), dqmiolumiharvest::j, trklet::VarBase::K(), trklet::Stub::layer(), layerdisk1_, layerdisk2_, trklet::VarBase::local_passes(), angle0to2pi::make0To2pi(), trklet::N_DISK, trklet::N_LAYER, trklet::ProcessBase::name_, trklet::Settings::nphibitsstub(), trklet::Settings::nrbitsstub(), trklet::TrackletParametersMemory::nTracklets(), trklet::Settings::nzbitsstub(), trklet::Globals::ofstream(), trklet::Stub::phi(), trklet::L1TStub::phi(), trklet::IMATH_TrackletCalculator::phi0_final, trklet::IMATH_TrackletCalculator::phi1, trklet::IMATH_TrackletCalculator::phi2, trklet::Stub::phiapprox(), trklet::IMATH_TrackletCalculator::phiD_0_final, trklet::IMATH_TrackletCalculator::phiD_1_final, trklet::IMATH_TrackletCalculator::phiD_2_final, trklet::IMATH_TrackletCalculator::phiD_3_final, trklet::IMATH_TrackletCalculator::phiD_4_final, trklet::IMATH_TrackletCalculator::phiL_0_final, trklet::IMATH_TrackletCalculator::phiL_1_final, trklet::IMATH_TrackletCalculator::phiL_2_final, trklet::IMATH_TrackletCalculator::phiL_3_final, trklet::ProcessBase::phimax_, trklet::ProcessBase::phimin_, phioffset_, trklet::Settings::projlayers(), trklet::Stub::r(), trklet::L1TStub::r(), diffTwoXMLs::r1, trklet::IMATH_TrackletCalculator::r1, diffTwoXMLs::r2, trklet::IMATH_TrackletCalculator::r2, trklet::Stub::rapprox(), trklet::IMATH_TrackletCalculator::rD_0_final, trklet::IMATH_TrackletCalculator::rD_1_final, trklet::IMATH_TrackletCalculator::rD_2_final, trklet::IMATH_TrackletCalculator::rD_3_final, trklet::IMATH_TrackletCalculator::rD_4_final, trklet::rinv(), trklet::IMATH_TrackletCalculator::rinv_final, trklet::Settings::rmaxdisk(), trklet::Settings::rmean(), trklet::Settings::rmindisk(), trklet::IMATH_TrackletCalculator::rproj0, trklet::IMATH_TrackletCalculator::rproj1, trklet::IMATH_TrackletCalculator::rproj2, trklet::IMATH_TrackletCalculator::rproj3, trklet::VarDef::set_fval(), trklet::VarDef::set_ival(), trklet::Tracklet::setTCIndex(), trklet::ProcessBase::settings_, trklet::Tracklet::setTrackletIndex(), trklet::L1TStub::sigmaz(), OrderedSet::t, trklet::IMATH_TrackletCalculator::t_final, TCIndex_, cmsswSequenceInfo::tp, trklet::Tracklet::tpseed(), trackletpars_, trklet::Settings::useapprox(), trklet::Tracklet::validProj(), trklet::Tracklet::validProjDisk(), trklet::FPGAWord::value(), trklet::Settings::writeMonitorData(), trklet::Stub::z(), trklet::L1TStub::z(), HLTMuonOfflineAnalyzer_cfi::z0, trklet::IMATH_TrackletCalculator::z0_final, trklet::IMATH_TrackletCalculator::z1, testProducerWithPsetDescEmpty_cfi::z2, trklet::IMATH_TrackletCalculator::z2, trklet::Stub::zapprox(), trklet::IMATH_TrackletCalculator::zL_0_final, trklet::IMATH_TrackletCalculator::zL_1_final, trklet::IMATH_TrackletCalculator::zL_2_final, trklet::IMATH_TrackletCalculator::zL_3_final, trklet::Settings::zmean(), trklet::IMATH_TrackletCalculator::zproj0, trklet::IMATH_TrackletCalculator::zproj1, trklet::IMATH_TrackletCalculator::zproj2, trklet::IMATH_TrackletCalculator::zproj3, and trklet::IMATH_TrackletCalculator::zproj4.

Referenced by trklet::TrackletCalculator::execute(), and trklet::TrackletProcessor::execute().

diskSeeding()

bool TrackletCalculatorBase::diskSeeding	(	const Stub *	innerFPGAStub,
		const L1TStub *	innerStub,
		const Stub *	outerFPGAStub,
		const L1TStub *	outerStub
	)

Definition at line 753 of file TrackletCalculatorBase.cc.

                                                                   {
  if (settings_.debugTracklet()) {
    edm::LogVerbatim("Tracklet") << "TrackletCalculator::execute calculate disk seeds";
  }
 
  int sign = 1;
  if (innerFPGAStub->disk().value() < 0)
    sign = -1;
 
  int disk = innerFPGAStub->disk().value();
  assert(abs(disk) == 1 || abs(disk) == 3);
 
  assert(innerStub->isPSmodule());
  assert(outerStub->isPSmodule());
 
  double r1 = innerStub->r();
  double z1 = innerStub->z();
  double phi1 = innerStub->phi();
 
  double r2 = outerStub->r();
  double z2 = outerStub->z();
  double phi2 = outerStub->phi();
 
  if (r2 < r1 + 2.0) {
    return false;  //Protection... Should be handled cleaner to avoid problem with floating point calculation
  }
 
  double rinv, phi0, t, z0;
 
  double phiproj[N_PSLAYER], zproj[N_PSLAYER], phider[N_PSLAYER], zder[N_PSLAYER];
  double phiprojdisk[N_DISK - 2], rprojdisk[N_DISK - 2], phiderdisk[N_DISK - 2], rderdisk[N_DISK - 2];
 
  exacttrackletdisk(r1,
                    z1,
                    phi1,
                    r2,
                    z2,
                    phi2,
                    outerStub->sigmaz(),
                    rinv,
                    phi0,
                    t,
                    z0,
                    phiproj,
                    zproj,
                    phider,
                    zder,
                    phiprojdisk,
                    rprojdisk,
                    phiderdisk,
                    rderdisk);
 
  //Truncates floating point positions to integer representation precision
  if (settings_.useapprox()) {
    phi1 = innerFPGAStub->phiapprox(phimin_, phimax_);
    z1 = innerFPGAStub->zapprox();
    r1 = innerFPGAStub->rapprox();
 
    phi2 = outerFPGAStub->phiapprox(phimin_, phimax_);
    z2 = outerFPGAStub->zapprox();
    r2 = outerFPGAStub->rapprox();
  }
 
  double rinvapprox, phi0approx, tapprox, z0approx;
  double phiprojapprox[N_PSLAYER], zprojapprox[N_PSLAYER];
  double phiprojdiskapprox[N_DISK - 2], rprojdiskapprox[N_DISK - 2];
 
  IMATH_TrackletCalculatorDisk* ITC;
  if (disk == 1)
    ITC = globals_->ITC_F1F2();
  else if (disk == 3)
    ITC = globals_->ITC_F3F4();
  else if (disk == -1)
    ITC = globals_->ITC_B1B2();
  else
    ITC = globals_->ITC_B3B4();
 
  ITC->r1.set_fval(r1);
  ITC->r2.set_fval(r2);
  int signt = t > 0 ? 1 : -1;
  ITC->z1.set_fval(z1 - signt * settings_.zmean(layerdisk1_ - N_LAYER));
  ITC->z2.set_fval(z2 - signt * settings_.zmean(layerdisk2_ - N_LAYER));
  double sphi1 = angle0to2pi::make0To2pi(phi1 - phioffset_);
  double sphi2 = angle0to2pi::make0To2pi(phi2 - phioffset_);
  ITC->phi1.set_fval(sphi1);
  ITC->phi2.set_fval(sphi2);
 
  ITC->rproj0.set_fval(settings_.rmean(0));
  ITC->rproj1.set_fval(settings_.rmean(1));
  ITC->rproj2.set_fval(settings_.rmean(2));
 
  ITC->zproj0.set_fval(signt * settings_.zmean(settings_.projdisks(iSeed_, 0) - 1));
  ITC->zproj1.set_fval(signt * settings_.zmean(settings_.projdisks(iSeed_, 1) - 1));
  ITC->zproj2.set_fval(signt * settings_.zmean(settings_.projdisks(iSeed_, 2) - 1));
 
  ITC->rinv_final.calculate();
  ITC->phi0_final.calculate();
  ITC->t_final.calculate();
  ITC->z0_final.calculate();
 
  ITC->phiL_0_final.calculate();
  ITC->phiL_1_final.calculate();
  ITC->phiL_2_final.calculate();
 
  ITC->zL_0_final.calculate();
  ITC->zL_1_final.calculate();
  ITC->zL_2_final.calculate();
 
  ITC->phiD_0_final.calculate();
  ITC->phiD_1_final.calculate();
  ITC->phiD_2_final.calculate();
 
  ITC->rD_0_final.calculate();
  ITC->rD_1_final.calculate();
  ITC->rD_2_final.calculate();
 
  ITC->der_phiL_final.calculate();
  ITC->der_zL_final.calculate();
  ITC->der_phiD_final.calculate();
  ITC->der_rD_final.calculate();
 
  //store the approximate results
  rinvapprox = ITC->rinv_final.fval();
  phi0approx = ITC->phi0_final.fval();
  tapprox = ITC->t_final.fval();
  z0approx = ITC->z0_final.fval();
 
  phiprojapprox[0] = ITC->phiL_0_final.fval();
  phiprojapprox[1] = ITC->phiL_1_final.fval();
  phiprojapprox[2] = ITC->phiL_2_final.fval();
 
  zprojapprox[0] = ITC->zL_0_final.fval();
  zprojapprox[1] = ITC->zL_1_final.fval();
  zprojapprox[2] = ITC->zL_2_final.fval();
 
  phiprojdiskapprox[0] = ITC->phiD_0_final.fval();
  phiprojdiskapprox[1] = ITC->phiD_1_final.fval();
  phiprojdiskapprox[2] = ITC->phiD_2_final.fval();
 
  rprojdiskapprox[0] = ITC->rD_0_final.fval();
  rprojdiskapprox[1] = ITC->rD_1_final.fval();
  rprojdiskapprox[2] = ITC->rD_2_final.fval();
 
  //now binary
 
  int irinv, iphi0, it, iz0;
  int iphiproj[N_PSLAYER], izproj[N_PSLAYER];
 
  int iphiprojdisk[N_DISK - 2], irprojdisk[N_DISK - 2];
 
  int ir1 = innerFPGAStub->r().value();
  int iphi1 = innerFPGAStub->phi().value();
  int iz1 = innerFPGAStub->z().value();
 
  int ir2 = outerFPGAStub->r().value();
  int iphi2 = outerFPGAStub->phi().value();
  int iz2 = outerFPGAStub->z().value();
 
  //To get same precission as for layers.
  iphi1 <<= (settings_.nphibitsstub(5) - settings_.nphibitsstub(0));
  iphi2 <<= (settings_.nphibitsstub(5) - settings_.nphibitsstub(0));
 
  ITC->r1.set_ival(ir1);
  ITC->r2.set_ival(ir2);
  ITC->z1.set_ival(iz1);
  ITC->z2.set_ival(iz2);
  ITC->phi1.set_ival(iphi1);
  ITC->phi2.set_ival(iphi2);
 
  ITC->rinv_final.calculate();
  ITC->phi0_final.calculate();
  ITC->t_final.calculate();
  ITC->z0_final.calculate();
 
  ITC->phiL_0_final.calculate();
  ITC->phiL_1_final.calculate();
  ITC->phiL_2_final.calculate();
 
  ITC->zL_0_final.calculate();
  ITC->zL_1_final.calculate();
  ITC->zL_2_final.calculate();
 
  ITC->phiD_0_final.calculate();
  ITC->phiD_1_final.calculate();
  ITC->phiD_2_final.calculate();
 
  ITC->rD_0_final.calculate();
  ITC->rD_1_final.calculate();
  ITC->rD_2_final.calculate();
 
  ITC->der_phiL_final.calculate();
  ITC->der_zL_final.calculate();
  ITC->der_phiD_final.calculate();
  ITC->der_rD_final.calculate();
 
  //store the binary results
  irinv = ITC->rinv_final.ival();
  iphi0 = ITC->phi0_final.ival();
  it = ITC->t_final.ival();
  iz0 = ITC->z0_final.ival();
 
  iphiproj[0] = ITC->phiL_0_final.ival();
  iphiproj[1] = ITC->phiL_1_final.ival();
  iphiproj[2] = ITC->phiL_2_final.ival();
 
  izproj[0] = ITC->zL_0_final.ival();
  izproj[1] = ITC->zL_1_final.ival();
  izproj[2] = ITC->zL_2_final.ival();
 
  if (!goodTrackPars(ITC->rinv_final.local_passes(), ITC->z0_final.local_passes()))
    return false;
 
  if (!inSector(iphi0, irinv, phi0approx, rinvapprox))
    return false;
 
  LayerProjection layerprojs[N_LAYER - 2];
  DiskProjection diskprojs[N_DISK - 2];
 
  for (unsigned int i = 0; i < N_DISK - 2; ++i) {
    //Check is outside z range
    if (izproj[i] < -(1 << (settings_.nzbitsstub(0) - 1)))
      continue;
    if (izproj[i] >= (1 << (settings_.nzbitsstub(0) - 1)))
      continue;
 
    //Check if outside phi range
    if (iphiproj[i] >= (1 << settings_.nphibitsstub(5)) - 1)
      continue;
    if (iphiproj[i] <= 0)
      continue;
 
    //shift bits - allways in PS modules for disk seeding
    iphiproj[i] >>= (settings_.nphibitsstub(5) - settings_.nphibitsstub(0));
 
    layerprojs[i].init(settings_,
                       i + 1,
                       settings_.rmean(i),
                       iphiproj[i],
                       izproj[i],
                       ITC->der_phiL_final.ival(),
                       ITC->der_zL_final.ival(),
                       phiproj[i],
                       zproj[i],
                       phider[i],
                       zder[i],
                       phiprojapprox[i],
                       zprojapprox[i],
                       ITC->der_phiL_final.fval(),
                       ITC->der_zL_final.fval());
  }
 
  iphiprojdisk[0] = ITC->phiD_0_final.ival();
  iphiprojdisk[1] = ITC->phiD_1_final.ival();
  iphiprojdisk[2] = ITC->phiD_2_final.ival();
 
  irprojdisk[0] = ITC->rD_0_final.ival();
  irprojdisk[1] = ITC->rD_1_final.ival();
  irprojdisk[2] = ITC->rD_2_final.ival();
 
  for (unsigned int i = 0; i < N_DISK - 2; ++i) {
    //check that phi projection in range
    if (iphiprojdisk[i] <= 0)
      continue;
    if (iphiprojdisk[i] >= (1 << settings_.nphibitsstub(0)) - 1)
      continue;
 
    //check that r projection in range
    if (irprojdisk[i] <= 0 || irprojdisk[i] > settings_.rmaxdisk() / ITC->rD_0_final.K())
      continue;
 
    diskprojs[i].init(settings_,
                      i + 1,
                      settings_.zmean(settings_.projdisks(iSeed_, i) - 1),
                      iphiprojdisk[i],
                      irprojdisk[i],
                      ITC->der_phiD_final.ival(),
                      ITC->der_rD_final.ival(),
                      phiprojdisk[i],
                      rprojdisk[i],
                      phiderdisk[i],
                      rderdisk[i],
                      phiprojdiskapprox[i],
                      rprojdiskapprox[i],
                      ITC->der_phiD_final.fval(),
                      ITC->der_rD_final.fval());
  }
 
  if (settings_.writeMonitorData("TPars")) {
    globals_->ofstream("trackletparsdisk.txt")
        << "Trackpars         " << layerdisk1_ - 5 << "   " << rinv << " " << rinvapprox << " "
        << ITC->rinv_final.fval() << "   " << phi0 << " " << phi0approx << " " << ITC->phi0_final.fval() << "   " << t
        << " " << tapprox << " " << ITC->t_final.fval() << "   " << z0 << " " << z0approx << " " << ITC->z0_final.fval()
        << endl;
  }
 
  Tracklet* tracklet = new Tracklet(settings_,
                                    innerStub,
                                    nullptr,
                                    outerStub,
                                    innerFPGAStub,
                                    nullptr,
                                    outerFPGAStub,
                                    rinv,
                                    phi0,
                                    0.0,
                                    z0,
                                    t,
                                    rinvapprox,
                                    phi0approx,
                                    0.0,
                                    z0approx,
                                    tapprox,
                                    irinv,
                                    iphi0,
                                    0,
                                    iz0,
                                    it,
                                    layerprojs,
                                    diskprojs,
                                    true);
 
  if (settings_.debugTracklet()) {
    edm::LogVerbatim("Tracklet") << "Found tracklet for disk seed = " << iSeed_ << " " << tracklet << " " << iSector_;
  }
 
  tracklet->setTrackletIndex(trackletpars_->nTracklets());
  tracklet->setTCIndex(TCIndex_);
 
  if (settings_.writeMonitorData("Seeds")) {
    ofstream fout("seeds.txt", ofstream::app);
    fout << __FILE__ << ":" << __LINE__ << " " << name_ << "_" << iSector_ << " " << tracklet->getISeed() << endl;
    fout.close();
  }
  trackletpars_->addTracklet(tracklet);
 
  if (tracklet->validProj(1)) {
    addLayerProj(tracklet, 1);
  }
 
  if (tracklet->validProj(2)) {
    addLayerProj(tracklet, 2);
  }
 
  for (unsigned int j = 0; j < N_DISK - 2; j++) {
    if (tracklet->validProjDisk(sign * settings_.projdisks(iSeed_, j))) {
      addDiskProj(tracklet, sign * settings_.projdisks(iSeed_, j));
    }
  }
 
  return true;
}

References funct::abs(), addDiskProj(), addLayerProj(), trklet::TrackletParametersMemory::addTracklet(), cms::cuda::assert(), trklet::VarBase::calculate(), trklet::Settings::debugTracklet(), trklet::IMATH_TrackletCalculatorDisk::der_phiD_final, trklet::IMATH_TrackletCalculatorDisk::der_phiL_final, trklet::IMATH_TrackletCalculatorDisk::der_rD_final, trklet::IMATH_TrackletCalculatorDisk::der_zL_final, trklet::Stub::disk(), exacttrackletdisk(), groupFilesInBlocks::fout, trklet::VarBase::fval(), trklet::Tracklet::getISeed(), trklet::ProcessBase::globals_, goodTrackPars(), mps_fire::i, trklet::LayerProjection::init(), trklet::DiskProjection::init(), inSector(), trklet::ProcessBase::iSector_, iSeed_, trklet::L1TStub::isPSmodule(), trklet::Globals::ITC_B1B2(), trklet::Globals::ITC_B3B4(), trklet::Globals::ITC_F1F2(), trklet::Globals::ITC_F3F4(), trklet::VarBase::ival(), dqmiolumiharvest::j, trklet::VarBase::K(), layerdisk1_, layerdisk2_, trklet::VarBase::local_passes(), angle0to2pi::make0To2pi(), trklet::N_DISK, trklet::N_LAYER, trklet::N_PSLAYER, trklet::ProcessBase::name_, trklet::Settings::nphibitsstub(), trklet::TrackletParametersMemory::nTracklets(), trklet::Settings::nzbitsstub(), trklet::Globals::ofstream(), trklet::Stub::phi(), trklet::L1TStub::phi(), trklet::IMATH_TrackletCalculatorDisk::phi0_final, trklet::IMATH_TrackletCalculatorDisk::phi1, trklet::IMATH_TrackletCalculatorDisk::phi2, trklet::Stub::phiapprox(), trklet::IMATH_TrackletCalculatorDisk::phiD_0_final, trklet::IMATH_TrackletCalculatorDisk::phiD_1_final, trklet::IMATH_TrackletCalculatorDisk::phiD_2_final, trklet::IMATH_TrackletCalculatorDisk::phiL_0_final, trklet::IMATH_TrackletCalculatorDisk::phiL_1_final, trklet::IMATH_TrackletCalculatorDisk::phiL_2_final, trklet::ProcessBase::phimax_, trklet::ProcessBase::phimin_, phioffset_, trklet::Settings::projdisks(), trklet::Stub::r(), trklet::L1TStub::r(), diffTwoXMLs::r1, trklet::IMATH_TrackletCalculatorDisk::r1, diffTwoXMLs::r2, trklet::IMATH_TrackletCalculatorDisk::r2, trklet::Stub::rapprox(), trklet::IMATH_TrackletCalculatorDisk::rD_0_final, trklet::IMATH_TrackletCalculatorDisk::rD_1_final, trklet::IMATH_TrackletCalculatorDisk::rD_2_final, trklet::rinv(), trklet::IMATH_TrackletCalculatorDisk::rinv_final, trklet::Settings::rmaxdisk(), trklet::Settings::rmean(), trklet::IMATH_TrackletCalculatorDisk::rproj0, trklet::IMATH_TrackletCalculatorDisk::rproj1, trklet::IMATH_TrackletCalculatorDisk::rproj2, trklet::VarDef::set_fval(), trklet::VarDef::set_ival(), trklet::Tracklet::setTCIndex(), trklet::ProcessBase::settings_, trklet::Tracklet::setTrackletIndex(), trklet::L1TStub::sigmaz(), Validation_hcalonly_cfi::sign, OrderedSet::t, trklet::IMATH_TrackletCalculatorDisk::t_final, TCIndex_, trackletpars_, trklet::Settings::useapprox(), trklet::Tracklet::validProj(), trklet::Tracklet::validProjDisk(), trklet::FPGAWord::value(), trklet::Settings::writeMonitorData(), trklet::Stub::z(), trklet::L1TStub::z(), HLTMuonOfflineAnalyzer_cfi::z0, trklet::IMATH_TrackletCalculatorDisk::z0_final, trklet::IMATH_TrackletCalculatorDisk::z1, testProducerWithPsetDescEmpty_cfi::z2, trklet::IMATH_TrackletCalculatorDisk::z2, trklet::Stub::zapprox(), trklet::IMATH_TrackletCalculatorDisk::zL_0_final, trklet::IMATH_TrackletCalculatorDisk::zL_1_final, trklet::IMATH_TrackletCalculatorDisk::zL_2_final, trklet::Settings::zmean(), trklet::IMATH_TrackletCalculatorDisk::zproj0, trklet::IMATH_TrackletCalculatorDisk::zproj1, and trklet::IMATH_TrackletCalculatorDisk::zproj2.

Referenced by trklet::TrackletCalculator::execute(), and trklet::TrackletProcessor::execute().

exactproj()

void TrackletCalculatorBase::exactproj	(	double	rproj,
		double	rinv,
		double	phi0,
		double	t,
		double	z0,
		double &	phiproj,
		double &	zproj,
		double &	phider,
		double &	zder
	)

Definition at line 177 of file TrackletCalculatorBase.cc.

                                                     {
  phiproj = phi0 - asin(0.5 * rproj * rinv);
  zproj = z0 + (2 * t / rinv) * asin(0.5 * rproj * rinv);
 
  phider = -0.5 * rinv / sqrt(1 - pow(0.5 * rproj * rinv, 2));
  zder = t / sqrt(1 - pow(0.5 * rproj * rinv, 2));
}

References funct::pow(), trklet::rinv(), mathSSE::sqrt(), OrderedSet::t, and HLTMuonOfflineAnalyzer_cfi::z0.

Referenced by exacttracklet(), exacttrackletdisk(), and exacttrackletOverlap().

exactprojdisk()

void TrackletCalculatorBase::exactprojdisk	(	double	zproj,
		double	rinv,
		double	phi0,
		double	t,
		double	z0,
		double &	phiproj,
		double &	rproj,
		double &	phider,
		double &	rder
	)

Definition at line 193 of file TrackletCalculatorBase.cc.

                                                         {
  if (t < 0)
    zproj = -zproj;
 
  double tmp = rinv * (zproj - z0) / (2.0 * t);
  rproj = (2.0 / rinv) * sin(tmp);
  phiproj = phi0 - tmp;
 
  phider = -rinv / (2 * t);
  rder = cos(tmp) / t;
}

References funct::cos(), trklet::rinv(), funct::sin(), OrderedSet::t, createJobs::tmp, and HLTMuonOfflineAnalyzer_cfi::z0.

Referenced by exacttracklet(), exacttrackletdisk(), and exacttrackletOverlap().

exacttracklet()

void TrackletCalculatorBase::exacttracklet	(	double	r1,
		double	z1,
		double	phi1,
		double	r2,
		double	z2,
		double	phi2,
		double	,
		double &	rinv,
		double &	phi0,
		double &	t,
		double &	z0,
		double	phiproj[N_LAYER - 2],
		double	zproj[N_LAYER - 2],
		double	phider[N_LAYER - 2],
		double	zder[N_LAYER - 2],
		double	phiprojdisk[N_DISK],
		double	rprojdisk[N_DISK],
		double	phiderdisk[N_DISK],
		double	rderdisk[N_DISK]
	)

Definition at line 23 of file TrackletCalculatorBase.cc.

                                                                    {
  double deltaphi = reco::reduceRange(phi1 - phi2);
 
  double dist = sqrt(r2 * r2 + r1 * r1 - 2 * r1 * r2 * cos(deltaphi));
 
  rinv = 2 * sin(deltaphi) / dist;
 
  double phi1tmp = phi1 - phimin_;
 
  phi0 = reco::reduceRange(phi1tmp + asin(0.5 * r1 * rinv));
 
  double rhopsi1 = 2 * asin(0.5 * r1 * rinv) / rinv;
  double rhopsi2 = 2 * asin(0.5 * r2 * rinv) / rinv;
 
  t = (z1 - z2) / (rhopsi1 - rhopsi2);
 
  z0 = z1 - t * rhopsi1;
 
  for (unsigned int i = 0; i < N_LAYER - 2; i++) {
    exactproj(settings_.rmean(settings_.projlayers(iSeed_, i) - 1),
              rinv,
              phi0,
              t,
              z0,
              phiproj[i],
              zproj[i],
              phider[i],
              zder[i]);
  }
 
  for (unsigned int i = 0; i < N_DISK; i++) {
    exactprojdisk(settings_.zmean(i), rinv, phi0, t, z0, phiprojdisk[i], rprojdisk[i], phiderdisk[i], rderdisk[i]);
  }
}

References funct::cos(), exactproj(), exactprojdisk(), mps_fire::i, iSeed_, trklet::N_DISK, trklet::N_LAYER, trklet::ProcessBase::phimin_, trklet::Settings::projlayers(), diffTwoXMLs::r1, diffTwoXMLs::r2, reco::reduceRange(), trklet::rinv(), trklet::Settings::rmean(), trklet::ProcessBase::settings_, funct::sin(), mathSSE::sqrt(), OrderedSet::t, HLTMuonOfflineAnalyzer_cfi::z0, testProducerWithPsetDescEmpty_cfi::z2, and trklet::Settings::zmean().

Referenced by barrelSeeding().

exacttrackletdisk()

void TrackletCalculatorBase::exacttrackletdisk	(	double	r1,
		double	z1,
		double	phi1,
		double	r2,
		double	z2,
		double	phi2,
		double	,
		double &	rinv,
		double &	phi0,
		double &	t,
		double &	z0,
		double	phiprojLayer[N_PSLAYER],
		double	zprojLayer[N_PSLAYER],
		double	phiderLayer[N_PSLAYER],
		double	zderLayer[N_PSLAYER],
		double	phiproj[N_DISK - 2],
		double	rproj[N_DISK - 2],
		double	phider[N_DISK - 2],
		double	rder[N_DISK - 2]
	)

Definition at line 76 of file TrackletCalculatorBase.cc.

                                                                        {
  double deltaphi = reco::reduceRange(phi1 - phi2);
 
  double dist = sqrt(r2 * r2 + r1 * r1 - 2 * r1 * r2 * cos(deltaphi));
 
  rinv = 2 * sin(deltaphi) / dist;
 
  double phi1tmp = phi1 - phimin_;
 
  phi0 = reco::reduceRange(phi1tmp + asin(0.5 * r1 * rinv));
 
  double rhopsi1 = 2 * asin(0.5 * r1 * rinv) / rinv;
  double rhopsi2 = 2 * asin(0.5 * r2 * rinv) / rinv;
 
  t = (z1 - z2) / (rhopsi1 - rhopsi2);
 
  z0 = z1 - t * rhopsi1;
 
  for (unsigned int i = 0; i < N_DISK - 2; i++) {
    exactprojdisk(settings_.zmean(settings_.projdisks(iSeed_, i) - 1),
                  rinv,
                  phi0,
                  t,
                  z0,
                  phiproj[i],
                  rproj[i],
                  phider[i],
                  rder[i]);
  }
 
  for (unsigned int i = 0; i < N_DISK - 2; i++) {
    exactproj(settings_.rmean(i), rinv, phi0, t, z0, phiprojLayer[i], zprojLayer[i], phiderLayer[i], zderLayer[i]);
  }
}

References funct::cos(), exactproj(), exactprojdisk(), mps_fire::i, iSeed_, trklet::N_DISK, trklet::ProcessBase::phimin_, trklet::Settings::projdisks(), diffTwoXMLs::r1, diffTwoXMLs::r2, reco::reduceRange(), trklet::rinv(), trklet::Settings::rmean(), trklet::ProcessBase::settings_, funct::sin(), mathSSE::sqrt(), OrderedSet::t, HLTMuonOfflineAnalyzer_cfi::z0, testProducerWithPsetDescEmpty_cfi::z2, and trklet::Settings::zmean().

Referenced by diskSeeding().

exacttrackletOverlap()

void TrackletCalculatorBase::exacttrackletOverlap	(	double	r1,
		double	z1,
		double	phi1,
		double	r2,
		double	z2,
		double	phi2,
		double	,
		double &	rinv,
		double &	phi0,
		double &	t,
		double &	z0,
		double	phiprojLayer[N_PSLAYER],
		double	zprojLayer[N_PSLAYER],
		double	phiderLayer[N_PSLAYER],
		double	zderLayer[N_PSLAYER],
		double	phiproj[N_DISK - 2],
		double	rproj[N_DISK - 2],
		double	phider[N_DISK - 2],
		double	rder[N_DISK - 2]
	)

Definition at line 129 of file TrackletCalculatorBase.cc.

                                                                           {
  double deltaphi = reco::reduceRange(phi1 - phi2);
 
  double dist = sqrt(r2 * r2 + r1 * r1 - 2 * r1 * r2 * cos(deltaphi));
 
  rinv = 2 * sin(deltaphi) / dist;
 
  if (r1 > r2)
    rinv = -rinv;
 
  double phi1tmp = phi1 - phimin_;
 
  phi0 = reco::reduceRange(phi1tmp + asin(0.5 * r1 * rinv));
 
  double rhopsi1 = 2 * asin(0.5 * r1 * rinv) / rinv;
  double rhopsi2 = 2 * asin(0.5 * r2 * rinv) / rinv;
 
  t = (z1 - z2) / (rhopsi1 - rhopsi2);
 
  z0 = z1 - t * rhopsi1;
 
  for (int i = 0; i < 4; i++) {
    exactprojdisk(settings_.zmean(i + 1), rinv, phi0, t, z0, phiproj[i], rproj[i], phider[i], rder[i]);
  }
 
  for (int i = 0; i < 1; i++) {
    exactproj(settings_.rmean(i), rinv, phi0, t, z0, phiprojLayer[i], zprojLayer[i], phiderLayer[i], zderLayer[i]);
  }
}

References funct::cos(), exactproj(), exactprojdisk(), mps_fire::i, trklet::ProcessBase::phimin_, diffTwoXMLs::r1, diffTwoXMLs::r2, reco::reduceRange(), trklet::rinv(), trklet::Settings::rmean(), trklet::ProcessBase::settings_, funct::sin(), mathSSE::sqrt(), OrderedSet::t, HLTMuonOfflineAnalyzer_cfi::z0, testProducerWithPsetDescEmpty_cfi::z2, and trklet::Settings::zmean().

Referenced by overlapSeeding().

goodTrackPars()

bool TrackletCalculatorBase::goodTrackPars	(	bool	goodrinv,
		bool	goodz0
	)

Definition at line 289 of file TrackletCalculatorBase.cc.

                                                                     {
  bool success = true;
  if (!goodrinv) {
    if (settings_.debugTracklet()) {
      edm::LogVerbatim("Tracklet") << getName() << " TrackletCalculatorBase irinv too large";
    }
    success = false;
  }
  if (!goodz0) {
    if (settings_.debugTracklet()) {
      edm::LogVerbatim("Tracklet") << getName() << " TrackletCalculatorBase z0 cut to large";
    }
    success = false;
  }
  return success;
}

References trklet::Settings::debugTracklet(), trklet::ProcessBase::getName(), trklet::ProcessBase::settings_, and summarizeEdmComparisonLogfiles::success.

Referenced by barrelSeeding(), diskSeeding(), and overlapSeeding().

inSector()

bool TrackletCalculatorBase::inSector	(	int	iphi0,
		int	irinv,
		double	phi0approx,
		double	rinvapprox
	)

Definition at line 306 of file TrackletCalculatorBase.cc.

                                                                                                {
  double phicritapprox = phi0approx - asin(0.5 * settings_.rcrit() * rinvapprox);
 
  int ifactor = 0.5 * settings_.rcrit() * settings_.krinvpars() / settings_.kphi0pars() * (1 << 8);
  int iphicrit = iphi0 - (irinv >> 8) * ifactor;
 
  int iphicritmincut = settings_.phicritminmc() / globals_->ITC_L1L2()->phi0_final.K();
  int iphicritmaxcut = settings_.phicritmaxmc() / globals_->ITC_L1L2()->phi0_final.K();
 
  bool keepapprox = (phicritapprox > settings_.phicritminmc()) && (phicritapprox < settings_.phicritmaxmc()),
       keep = (iphicrit > iphicritmincut) && (iphicrit < iphicritmaxcut);
  if (settings_.debugTracklet())
    if (keepapprox && !keep)
      edm::LogVerbatim("Tracklet") << getName()
                                   << " Tracklet kept with exact phicrit cut but not approximate, phicritapprox: "
                                   << phicritapprox;
  if (settings_.usephicritapprox()) {
    return keepapprox;
  } else {
    return keep;
  }
 
  return true;
}

References trklet::Settings::debugTracklet(), trklet::ProcessBase::getName(), trklet::ProcessBase::globals_, trklet::Globals::ITC_L1L2(), trklet::VarBase::K(), keep, trklet::Settings::kphi0pars(), trklet::Settings::krinvpars(), trklet::IMATH_TrackletCalculator::phi0_final, trklet::Settings::phicritmaxmc(), trklet::Settings::phicritminmc(), trklet::Settings::rcrit(), trklet::ProcessBase::settings_, and trklet::Settings::usephicritapprox().

Referenced by barrelSeeding(), diskSeeding(), and overlapSeeding().

overlapSeeding()

bool TrackletCalculatorBase::overlapSeeding	(	const Stub *	innerFPGAStub,
		const L1TStub *	innerStub,
		const Stub *	outerFPGAStub,
		const L1TStub *	outerStub
	)

Definition at line 1108 of file TrackletCalculatorBase.cc.

                                                                      {
  //Deal with overlap stubs here
  assert(outerFPGAStub->isBarrel());
 
  assert(innerFPGAStub->isDisk());
 
  int disk = innerFPGAStub->disk().value();
 
  if (settings_.debugTracklet()) {
    edm::LogVerbatim("Tracklet") << "trying to make overlap tracklet for seed = " << iSeed_ << " " << getName();
  }
 
  double r1 = innerStub->r();
  double z1 = innerStub->z();
  double phi1 = innerStub->phi();
 
  double r2 = outerStub->r();
  double z2 = outerStub->z();
  double phi2 = outerStub->phi();
 
  //Protection for wrong radii. Could be handled cleaner to avoid problem with floating point calculation and with overflows in the integer calculation.
  if (r1 < r2 + 1.5) {
    return false;
  }
 
  double rinv, phi0, t, z0;
 
  double phiproj[N_PSLAYER], zproj[N_PSLAYER], phider[N_PSLAYER], zder[N_PSLAYER];
  double phiprojdisk[N_DISK - 1], rprojdisk[N_DISK - 1], phiderdisk[N_DISK - 1], rderdisk[N_DISK - 1];
 
  exacttrackletOverlap(r1,
                       z1,
                       phi1,
                       r2,
                       z2,
                       phi2,
                       outerStub->sigmaz(),
                       rinv,
                       phi0,
                       t,
                       z0,
                       phiproj,
                       zproj,
                       phider,
                       zder,
                       phiprojdisk,
                       rprojdisk,
                       phiderdisk,
                       rderdisk);
 
  //Truncates floating point positions to integer representation precision
  if (settings_.useapprox()) {
    phi1 = innerFPGAStub->phiapprox(phimin_, phimax_);
    z1 = innerFPGAStub->zapprox();
    r1 = innerFPGAStub->rapprox();
 
    phi2 = outerFPGAStub->phiapprox(phimin_, phimax_);
    z2 = outerFPGAStub->zapprox();
    r2 = outerFPGAStub->rapprox();
  }
 
  double rinvapprox, phi0approx, tapprox, z0approx;
  double phiprojapprox[N_PSLAYER], zprojapprox[N_PSLAYER];
  double phiprojdiskapprox[N_DISK - 1], rprojdiskapprox[N_DISK - 1];
 
  IMATH_TrackletCalculatorOverlap* ITC;
  int ll = outerFPGAStub->layer().value() + 1;
  if (ll == 1 && disk == 1)
    ITC = globals_->ITC_L1F1();
  else if (ll == 2 && disk == 1)
    ITC = globals_->ITC_L2F1();
  else if (ll == 1 && disk == -1)
    ITC = globals_->ITC_L1B1();
  else if (ll == 2 && disk == -1)
    ITC = globals_->ITC_L2B1();
  else
    throw cms::Exception("LogicError") << __FILE__ << " " << __LINE__ << " Invalid seeding!";
 
  ITC->r1.set_fval(r2 - settings_.rmean(ll - 1));
  ITC->r2.set_fval(r1);
  int signt = t > 0 ? 1 : -1;
  ITC->z1.set_fval(z2);
  ITC->z2.set_fval(z1 - signt * settings_.zmean(layerdisk2_ - N_LAYER));
  double sphi1 = angle0to2pi::make0To2pi(phi1 - phioffset_);
  double sphi2 = angle0to2pi::make0To2pi(phi2 - phioffset_);
  ITC->phi1.set_fval(sphi2);
  ITC->phi2.set_fval(sphi1);
 
  ITC->rproj0.set_fval(settings_.rmean(0));
  ITC->rproj1.set_fval(settings_.rmean(1));
  ITC->rproj2.set_fval(settings_.rmean(2));
 
  ITC->zproj0.set_fval(signt * settings_.zmean(1));
  ITC->zproj1.set_fval(signt * settings_.zmean(2));
  ITC->zproj2.set_fval(signt * settings_.zmean(3));
  ITC->zproj3.set_fval(signt * settings_.zmean(4));
 
  ITC->rinv_final.calculate();
  ITC->phi0_final.calculate();
  ITC->t_final.calculate();
  ITC->z0_final.calculate();
 
  ITC->phiL_0_final.calculate();
  ITC->phiL_1_final.calculate();
  ITC->phiL_2_final.calculate();
 
  ITC->zL_0_final.calculate();
  ITC->zL_1_final.calculate();
  ITC->zL_2_final.calculate();
 
  ITC->phiD_0_final.calculate();
  ITC->phiD_1_final.calculate();
  ITC->phiD_2_final.calculate();
  ITC->phiD_3_final.calculate();
 
  ITC->rD_0_final.calculate();
  ITC->rD_1_final.calculate();
  ITC->rD_2_final.calculate();
  ITC->rD_3_final.calculate();
 
  ITC->der_phiL_final.calculate();
  ITC->der_zL_final.calculate();
  ITC->der_phiD_final.calculate();
  ITC->der_rD_final.calculate();
 
  //store the approximate results
  rinvapprox = ITC->rinv_final.fval();
  phi0approx = ITC->phi0_final.fval();
  tapprox = ITC->t_final.fval();
  z0approx = ITC->z0_final.fval();
 
  phiprojapprox[0] = ITC->phiL_0_final.fval();
  phiprojapprox[1] = ITC->phiL_1_final.fval();
  phiprojapprox[2] = ITC->phiL_2_final.fval();
 
  zprojapprox[0] = ITC->zL_0_final.fval();
  zprojapprox[1] = ITC->zL_1_final.fval();
  zprojapprox[2] = ITC->zL_2_final.fval();
 
  phiprojdiskapprox[0] = ITC->phiD_0_final.fval();
  phiprojdiskapprox[1] = ITC->phiD_1_final.fval();
  phiprojdiskapprox[2] = ITC->phiD_2_final.fval();
  phiprojdiskapprox[3] = ITC->phiD_3_final.fval();
 
  rprojdiskapprox[0] = ITC->rD_0_final.fval();
  rprojdiskapprox[1] = ITC->rD_1_final.fval();
  rprojdiskapprox[2] = ITC->rD_2_final.fval();
  rprojdiskapprox[3] = ITC->rD_3_final.fval();
 
  //now binary
 
  int irinv, iphi0, it, iz0;
  int iphiproj[N_LAYER - 2], izproj[N_LAYER - 2];
  int iphiprojdisk[N_DISK], irprojdisk[N_DISK];
 
  int ir2 = innerFPGAStub->r().value();
  int iphi2 = innerFPGAStub->phi().value();
  int iz2 = innerFPGAStub->z().value();
 
  int ir1 = outerFPGAStub->r().value();
  int iphi1 = outerFPGAStub->phi().value();
  int iz1 = outerFPGAStub->z().value();
 
  //To get global precission
  ir1 <<= (8 - settings_.nrbitsstub(ll - 1));
  iphi1 <<= (settings_.nphibitsstub(5) - settings_.nphibitsstub(0));
  iphi2 <<= (settings_.nphibitsstub(5) - settings_.nphibitsstub(0));
 
  ITC->r1.set_ival(ir1);
  ITC->r2.set_ival(ir2);
  ITC->z1.set_ival(iz1);
  ITC->z2.set_ival(iz2);
  ITC->phi1.set_ival(iphi1);
  ITC->phi2.set_ival(iphi2);
 
  ITC->rinv_final.calculate();
  ITC->phi0_final.calculate();
  ITC->t_final.calculate();
  ITC->z0_final.calculate();
 
  ITC->phiL_0_final.calculate();
  ITC->phiL_1_final.calculate();
  ITC->phiL_2_final.calculate();
 
  ITC->zL_0_final.calculate();
  ITC->zL_1_final.calculate();
  ITC->zL_2_final.calculate();
 
  ITC->phiD_0_final.calculate();
  ITC->phiD_1_final.calculate();
  ITC->phiD_2_final.calculate();
  ITC->phiD_3_final.calculate();
 
  ITC->rD_0_final.calculate();
  ITC->rD_1_final.calculate();
  ITC->rD_2_final.calculate();
  ITC->rD_3_final.calculate();
 
  ITC->der_phiL_final.calculate();
  ITC->der_zL_final.calculate();
  ITC->der_phiD_final.calculate();
  ITC->der_rD_final.calculate();
 
  //store the binary results
  irinv = ITC->rinv_final.ival();
  iphi0 = ITC->phi0_final.ival();
  it = ITC->t_final.ival();
  iz0 = ITC->z0_final.ival();
 
  iphiproj[0] = ITC->phiL_0_final.ival();
  iphiproj[1] = ITC->phiL_1_final.ival();
  iphiproj[2] = ITC->phiL_2_final.ival();
 
  izproj[0] = ITC->zL_0_final.ival();
  izproj[1] = ITC->zL_1_final.ival();
  izproj[2] = ITC->zL_2_final.ival();
 
  iphiprojdisk[0] = ITC->phiD_0_final.ival();
  iphiprojdisk[1] = ITC->phiD_1_final.ival();
  iphiprojdisk[2] = ITC->phiD_2_final.ival();
  iphiprojdisk[3] = ITC->phiD_3_final.ival();
 
  irprojdisk[0] = ITC->rD_0_final.ival();
  irprojdisk[1] = ITC->rD_1_final.ival();
  irprojdisk[2] = ITC->rD_2_final.ival();
  irprojdisk[3] = ITC->rD_3_final.ival();
 
  if (!goodTrackPars(ITC->rinv_final.local_passes(), ITC->z0_final.local_passes()))
    return false;
 
  if (!inSector(iphi0, irinv, phi0approx, rinvapprox))
    return false;
 
  LayerProjection layerprojs[N_LAYER - 2];
  DiskProjection diskprojs[N_DISK];
 
  for (unsigned int i = 0; i < N_DISK - 2; ++i) {
    //check that zproj is in range
    if (izproj[i] < -(1 << (settings_.nzbitsstub(0) - 1)))
      continue;
    if (izproj[i] >= (1 << (settings_.nzbitsstub(0) - 1)))
      continue;
 
    //check that phiproj is in range
    if (iphiproj[i] >= (1 << settings_.nphibitsstub(5)) - 1)
      continue;
    if (iphiproj[i] <= 0)
      continue;
 
    //adjust bits for PS modules (no 2S modules in overlap seeds)
    iphiproj[i] >>= (settings_.nphibitsstub(5) - settings_.nphibitsstub(0));
 
    layerprojs[i].init(settings_,
                       i + 1,
                       settings_.rmean(i),
                       iphiproj[i],
                       izproj[i],
                       ITC->der_phiL_final.ival(),
                       ITC->der_zL_final.ival(),
                       phiproj[i],
                       zproj[i],
                       phider[i],
                       zder[i],
                       phiprojapprox[i],
                       zprojapprox[i],
                       ITC->der_phiL_final.fval(),
                       ITC->der_zL_final.fval());
  }
 
  for (int i = 0; i < 4; ++i) {
    //check that phi projection in range
    if (iphiprojdisk[i] <= 0)
      continue;
    if (iphiprojdisk[i] >= (1 << settings_.nphibitsstub(0)) - 1)
      continue;
 
    //check that r projection in range
    if (irprojdisk[i] <= 0 || irprojdisk[i] > settings_.rmaxdisk() / ITC->rD_0_final.K())
      continue;
 
    diskprojs[i].init(settings_,
                      i + 1,
                      settings_.zmean(i),
                      iphiprojdisk[i],
                      irprojdisk[i],
                      ITC->der_phiD_final.ival(),
                      ITC->der_rD_final.ival(),
                      phiprojdisk[i],
                      rprojdisk[i],
                      phiderdisk[i],
                      rderdisk[i],
                      phiprojdiskapprox[i],
                      rprojdiskapprox[i],
                      ITC->der_phiD_final.fval(),
                      ITC->der_rD_final.fval());
  }
 
  if (settings_.writeMonitorData("TPars")) {
    globals_->ofstream("trackletparsoverlap.txt")
        << "Trackpars " << layerdisk1_ - 5 << "   " << rinv << " " << irinv << " " << ITC->rinv_final.fval() << "   "
        << phi0 << " " << iphi0 << " " << ITC->phi0_final.fval() << "   " << t << " " << it << " "
        << ITC->t_final.fval() << "   " << z0 << " " << iz0 << " " << ITC->z0_final.fval() << endl;
  }
 
  Tracklet* tracklet = new Tracklet(settings_,
                                    innerStub,
                                    nullptr,
                                    outerStub,
                                    innerFPGAStub,
                                    nullptr,
                                    outerFPGAStub,
                                    rinv,
                                    phi0,
                                    0.0,
                                    z0,
                                    t,
                                    rinvapprox,
                                    phi0approx,
                                    0.0,
                                    z0approx,
                                    tapprox,
                                    irinv,
                                    iphi0,
                                    0,
                                    iz0,
                                    it,
                                    layerprojs,
                                    diskprojs,
                                    false,
                                    true);
 
  if (settings_.debugTracklet()) {
    edm::LogVerbatim("Tracklet") << "Found tracklet in overlap seed = " << iSeed_ << " " << tracklet << " " << iSector_;
  }
 
  tracklet->setTrackletIndex(trackletpars_->nTracklets());
  tracklet->setTCIndex(TCIndex_);
 
  if (settings_.writeMonitorData("Seeds")) {
    ofstream fout("seeds.txt", ofstream::app);
    fout << __FILE__ << ":" << __LINE__ << " " << name_ << "_" << iSector_ << " " << tracklet->getISeed() << endl;
    fout.close();
  }
  trackletpars_->addTracklet(tracklet);
 
  int layer = outerFPGAStub->layer().value() + 1;
 
  if (layer == 2) {
    if (tracklet->validProj(1)) {
      addLayerProj(tracklet, 1);
    }
  }
 
  for (unsigned int disk = 2; disk < 6; disk++) {
    if (layer == 2 && disk == 5)
      continue;
    if (tracklet->validProjDisk(disk)) {
      addDiskProj(tracklet, disk);
    }
  }
 
  return true;
}

References addDiskProj(), addLayerProj(), trklet::TrackletParametersMemory::addTracklet(), cms::cuda::assert(), trklet::VarBase::calculate(), trklet::Settings::debugTracklet(), trklet::IMATH_TrackletCalculatorOverlap::der_phiD_final, trklet::IMATH_TrackletCalculatorOverlap::der_phiL_final, trklet::IMATH_TrackletCalculatorOverlap::der_rD_final, trklet::IMATH_TrackletCalculatorOverlap::der_zL_final, trklet::Stub::disk(), exacttrackletOverlap(), Exception, groupFilesInBlocks::fout, trklet::VarBase::fval(), trklet::Tracklet::getISeed(), trklet::ProcessBase::getName(), trklet::ProcessBase::globals_, goodTrackPars(), mps_fire::i, trklet::LayerProjection::init(), trklet::DiskProjection::init(), inSector(), trklet::Stub::isBarrel(), trklet::Stub::isDisk(), trklet::ProcessBase::iSector_, iSeed_, trklet::Globals::ITC_L1B1(), trklet::Globals::ITC_L1F1(), trklet::Globals::ITC_L2B1(), trklet::Globals::ITC_L2F1(), trklet::VarBase::ival(), trklet::VarBase::K(), trklet::Stub::layer(), layerdisk1_, layerdisk2_, trklet::VarBase::local_passes(), angle0to2pi::make0To2pi(), trklet::N_DISK, trklet::N_LAYER, trklet::N_PSLAYER, trklet::ProcessBase::name_, trklet::Settings::nphibitsstub(), trklet::Settings::nrbitsstub(), trklet::TrackletParametersMemory::nTracklets(), trklet::Settings::nzbitsstub(), trklet::Globals::ofstream(), trklet::Stub::phi(), trklet::L1TStub::phi(), trklet::IMATH_TrackletCalculatorOverlap::phi0_final, trklet::IMATH_TrackletCalculatorOverlap::phi1, trklet::IMATH_TrackletCalculatorOverlap::phi2, trklet::Stub::phiapprox(), trklet::IMATH_TrackletCalculatorOverlap::phiD_0_final, trklet::IMATH_TrackletCalculatorOverlap::phiD_1_final, trklet::IMATH_TrackletCalculatorOverlap::phiD_2_final, trklet::IMATH_TrackletCalculatorOverlap::phiD_3_final, trklet::IMATH_TrackletCalculatorOverlap::phiL_0_final, trklet::IMATH_TrackletCalculatorOverlap::phiL_1_final, trklet::IMATH_TrackletCalculatorOverlap::phiL_2_final, trklet::ProcessBase::phimax_, trklet::ProcessBase::phimin_, phioffset_, trklet::Stub::r(), trklet::L1TStub::r(), diffTwoXMLs::r1, trklet::IMATH_TrackletCalculatorOverlap::r1, diffTwoXMLs::r2, trklet::IMATH_TrackletCalculatorOverlap::r2, trklet::Stub::rapprox(), trklet::IMATH_TrackletCalculatorOverlap::rD_0_final, trklet::IMATH_TrackletCalculatorOverlap::rD_1_final, trklet::IMATH_TrackletCalculatorOverlap::rD_2_final, trklet::IMATH_TrackletCalculatorOverlap::rD_3_final, trklet::rinv(), trklet::IMATH_TrackletCalculatorOverlap::rinv_final, trklet::Settings::rmaxdisk(), trklet::Settings::rmean(), trklet::IMATH_TrackletCalculatorOverlap::rproj0, trklet::IMATH_TrackletCalculatorOverlap::rproj1, trklet::IMATH_TrackletCalculatorOverlap::rproj2, trklet::VarDef::set_fval(), trklet::VarDef::set_ival(), trklet::Tracklet::setTCIndex(), trklet::ProcessBase::settings_, trklet::Tracklet::setTrackletIndex(), trklet::L1TStub::sigmaz(), OrderedSet::t, trklet::IMATH_TrackletCalculatorOverlap::t_final, TCIndex_, trackletpars_, trklet::Settings::useapprox(), trklet::Tracklet::validProj(), trklet::Tracklet::validProjDisk(), trklet::FPGAWord::value(), trklet::Settings::writeMonitorData(), trklet::Stub::z(), trklet::L1TStub::z(), HLTMuonOfflineAnalyzer_cfi::z0, trklet::IMATH_TrackletCalculatorOverlap::z0_final, trklet::IMATH_TrackletCalculatorOverlap::z1, testProducerWithPsetDescEmpty_cfi::z2, trklet::IMATH_TrackletCalculatorOverlap::z2, trklet::Stub::zapprox(), trklet::IMATH_TrackletCalculatorOverlap::zL_0_final, trklet::IMATH_TrackletCalculatorOverlap::zL_1_final, trklet::IMATH_TrackletCalculatorOverlap::zL_2_final, trklet::Settings::zmean(), trklet::IMATH_TrackletCalculatorOverlap::zproj0, trklet::IMATH_TrackletCalculatorOverlap::zproj1, trklet::IMATH_TrackletCalculatorOverlap::zproj2, and trklet::IMATH_TrackletCalculatorOverlap::zproj3.

Referenced by trklet::TrackletCalculator::execute(), and trklet::TrackletProcessor::execute().

Member Data Documentation

disk_

int trklet::TrackletCalculatorBase::disk_

protected

Definition at line 137 of file TrackletCalculatorBase.h.

Referenced by trklet::TrackletProcessor::execute(), trklet::TrackletProcessor::setVMPhiBin(), and trklet::TrackletProcessor::TrackletProcessor().

iSeed_

unsigned int trklet::TrackletCalculatorBase::iSeed_

protected

Definition at line 128 of file TrackletCalculatorBase.h.

Referenced by addProjectionDisk(), barrelSeeding(), diskSeeding(), exacttracklet(), exacttrackletdisk(), trklet::TrackletProcessor::execute(), overlapSeeding(), trklet::TrackletProcessor::setVMPhiBin(), trklet::TrackletCalculator::TrackletCalculator(), and trklet::TrackletProcessor::TrackletProcessor().

layer_

int trklet::TrackletCalculatorBase::layer_

protected

Definition at line 136 of file TrackletCalculatorBase.h.

Referenced by trklet::TrackletProcessor::execute(), trklet::TrackletProcessor::setVMPhiBin(), and trklet::TrackletProcessor::TrackletProcessor().

layerdisk1_

unsigned int trklet::TrackletCalculatorBase::layerdisk1_

protected

Definition at line 129 of file TrackletCalculatorBase.h.

Referenced by barrelSeeding(), diskSeeding(), overlapSeeding(), trklet::TrackletCalculator::TrackletCalculator(), and trklet::TrackletProcessor::TrackletProcessor().

layerdisk2_

unsigned int trklet::TrackletCalculatorBase::layerdisk2_

protected

Definition at line 130 of file TrackletCalculatorBase.h.

Referenced by barrelSeeding(), diskSeeding(), overlapSeeding(), trklet::TrackletCalculator::TrackletCalculator(), and trklet::TrackletProcessor::TrackletProcessor().

phioffset_

double trklet::TrackletCalculatorBase::phioffset_

protected

Definition at line 134 of file TrackletCalculatorBase.h.

Referenced by barrelSeeding(), diskSeeding(), overlapSeeding(), trklet::TrackletCalculator::TrackletCalculator(), and trklet::TrackletProcessor::TrackletProcessor().

TCIndex_

int trklet::TrackletCalculatorBase::TCIndex_

protected

Definition at line 132 of file TrackletCalculatorBase.h.

Referenced by barrelSeeding(), diskSeeding(), overlapSeeding(), trklet::TrackletCalculator::TrackletCalculator(), and trklet::TrackletProcessor::TrackletProcessor().

trackletpars_

TrackletParametersMemory* trklet::TrackletCalculatorBase::trackletpars_

protected

Definition at line 139 of file TrackletCalculatorBase.h.

Referenced by trklet::TrackletCalculator::addOutput(), trklet::TrackletProcessor::addOutput(), barrelSeeding(), diskSeeding(), trklet::TrackletCalculator::execute(), trklet::TrackletProcessor::execute(), and overlapSeeding().

trackletprojdisks_

std::vector<std::vector<TrackletProjectionsMemory*> > trklet::TrackletCalculatorBase::trackletprojdisks_

protected

Definition at line 143 of file TrackletCalculatorBase.h.

Referenced by addDiskProj(), trklet::TrackletCalculator::addOutput(), trklet::TrackletProcessor::addOutput(), trklet::TrackletCalculator::TrackletCalculator(), and trklet::TrackletProcessor::TrackletProcessor().

trackletprojlayers_

std::vector<std::vector<TrackletProjectionsMemory*> > trklet::TrackletCalculatorBase::trackletprojlayers_

protected

Definition at line 142 of file TrackletCalculatorBase.h.

Referenced by addLayerProj(), trklet::TrackletCalculator::addOutput(), trklet::TrackletProcessor::addOutput(), trklet::TrackletCalculator::TrackletCalculator(), and trklet::TrackletProcessor::TrackletProcessor().