#include <TrackletCalculatorDisplaced.h>

Inheritance diagram for trklet::TrackletCalculatorDisplaced:

Public Member Functions
void	addDiskProj (Tracklet *tracklet, int disk)

void	addInput (MemoryBase *memory, std::string input) override

bool	addLayerProj (Tracklet *tracklet, int layer)

void	addOutput (MemoryBase *memory, std::string output) override

void	addOutputProjection (TrackletProjectionsMemory &outputProj, MemoryBase memory)

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

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

bool	DDLSeeding (const Stub innerFPGAStub, const L1TStub innerStub, const Stub middleFPGAStub, const L1TStub middleStub, const Stub outerFPGAStub, const L1TStub outerStub)

void	exactproj (double rproj, double rinv, double phi0, double d0, double t, double z0, double r0, double &phiproj, double &zproj, double &phider, double &zder)

void	exactprojdisk (double zproj, double rinv, double, double, double t, double z0, double x0, double y0, double &phiproj, double &rproj, double &phider, double &rder)

void	exacttracklet (double r1, double z1, double phi1, double r2, double z2, double phi2, double r3, double z3, double phi3, int take3, double &rinv, double &phi0, double &d0, double &t, double &z0, double phiproj[N_LAYER - 2], double zproj[N_LAYER - 2], double phiprojdisk[N_DISK], double rprojdisk[N_DISK], double phider[N_LAYER - 2], double zder[N_LAYER - 2], double phiderdisk[N_DISK], double rderdisk[N_DISK])

void	execute ()

bool	LLDSeeding (const Stub innerFPGAStub, const L1TStub innerStub, const Stub middleFPGAStub, const L1TStub middleStub, const Stub outerFPGAStub, const L1TStub outerStub)

bool	LLLSeeding (const Stub innerFPGAStub, const L1TStub innerStub, const Stub middleFPGAStub, const L1TStub middleStub, const Stub outerFPGAStub, const L1TStub outerStub)

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

	~TrackletCalculatorDisplaced () override=default

Public Member Functions inherited from trklet::ProcessBase
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

Private Attributes
int	disk_

int	dproj_ [N_DISK - 2]

std::vector< AllStubsMemory * >	innerallstubs_

int	layer_

int	lproj_ [N_LAYER - 2]

std::vector< AllStubsMemory * >	middleallstubs_

std::vector< AllStubsMemory * >	outerallstubs_

double	rproj_ [N_LAYER - 2]

std::vector< StubTripletsMemory * >	stubtriplets_

int	TCIndex_

std::vector< double >	toR_

std::vector< double >	toZ_

TrackletParametersMemory *	trackletpars_

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

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

double	zproj_ [N_DISK - 2]

Additional Inherited Members
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 20 of file TrackletCalculatorDisplaced.h.

Constructor & Destructor Documentation

◆ TrackletCalculatorDisplaced()

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

Definition at line 16 of file TrackletCalculatorDisplaced.cc.

     : ProcessBase(name, settings, global, iSector) {
   for (unsigned int ilayer = 0; ilayer < N_LAYER; ilayer++) {
     vector<TrackletProjectionsMemory*> tmp(settings.nallstubs(ilayer), nullptr);
     trackletprojlayers_.push_back(tmp);
   }
  
   for (unsigned int idisk = 0; idisk < N_DISK; idisk++) {
     vector<TrackletProjectionsMemory*> tmp(settings.nallstubs(idisk + N_LAYER), nullptr);
     trackletprojdisks_.push_back(tmp);
   }
  
   layer_ = 0;
   disk_ = 0;
  
   string name1 = name.substr(1);  //this is to correct for "TCD" having one more letter then "TC"
   if (name1[3] == 'L')
     layer_ = name1[4] - '0';
   if (name1[3] == 'D')
     disk_ = name1[4] - '0';
  
   // set TC index
   int iSeed = -1;
  
   int iTC = name1[9] - 'A';
  
   if (name1.substr(3, 6) == "L3L4L2")
     iSeed = 8;
   else if (name1.substr(3, 6) == "L5L6L4")
     iSeed = 9;
   else if (name1.substr(3, 6) == "L2L3D1")
     iSeed = 10;
   else if (name1.substr(3, 6) == "D1D2L2")
     iSeed = 11;
  
   assert(iSeed != -1);
  
   TCIndex_ = (iSeed << 4) + iTC;
   assert(TCIndex_ >= 128 && TCIndex_ < 191);
  
   assert((layer_ != 0) || (disk_ != 0));
  
   toR_.clear();
   toZ_.clear();
  
   if (iSeed == 8 || iSeed == 9) {
     if (layer_ == 3) {
       rproj_[0] = settings_.rmean(0);
       rproj_[1] = settings_.rmean(4);
       rproj_[2] = settings_.rmean(5);
       lproj_[0] = 1;
       lproj_[1] = 5;
       lproj_[2] = 6;
  
       dproj_[0] = 1;
       dproj_[1] = 2;
       dproj_[2] = 0;
       toZ_.push_back(settings_.zmean(0));
       toZ_.push_back(settings_.zmean(1));
     }
     if (layer_ == 5) {
       rproj_[0] = settings_.rmean(0);
       rproj_[1] = settings_.rmean(1);
       rproj_[2] = settings_.rmean(2);
       lproj_[0] = 1;
       lproj_[1] = 2;
       lproj_[2] = 3;
  
       dproj_[0] = 0;
       dproj_[1] = 0;
       dproj_[2] = 0;
     }
     for (unsigned int i = 0; i < N_LAYER - 3; ++i)
       toR_.push_back(rproj_[i]);
   }
  
   if (iSeed == 10 || iSeed == 11) {
     if (layer_ == 2) {
       rproj_[0] = settings_.rmean(0);
       lproj_[0] = 1;
       lproj_[1] = -1;
       lproj_[2] = -1;
  
       zproj_[0] = settings_.zmean(1);
       zproj_[1] = settings_.zmean(2);
       zproj_[2] = settings_.zmean(3);
       dproj_[0] = 2;
       dproj_[1] = 3;
       dproj_[2] = 4;
     }
     if (disk_ == 1) {
       rproj_[0] = settings_.rmean(0);
       lproj_[0] = 1;
       lproj_[1] = -1;
       lproj_[2] = -1;
  
       zproj_[0] = settings_.zmean(2);
       zproj_[1] = settings_.zmean(3);
       zproj_[2] = settings_.zmean(4);
       dproj_[0] = 3;
       dproj_[1] = 4;
       dproj_[2] = 5;
     }
     toR_.push_back(settings_.rmean(0));
     for (unsigned int i = 0; i < N_DISK - 2; ++i)
       toZ_.push_back(zproj_[i]);
   }
 }

References cms::cuda::assert(), disk_, dproj_, mps_fire::i, layer_, lproj_, trklet::N_DISK, trklet::N_LAYER, trklet::Settings::nallstubs(), Skims_PA_cff::name, trklet::Settings::rmean(), rproj_, trklet::ProcessBase::settings_, TCIndex_, createJobs::tmp, toR_, toZ_, trackletprojdisks_, trackletprojlayers_, trklet::Settings::zmean(), and zproj_.

◆ ~TrackletCalculatorDisplaced()

trklet::TrackletCalculatorDisplaced::~TrackletCalculatorDisplaced ( )

overridedefault

Member Function Documentation

◆ addDiskProj()

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

Definition at line 280 of file TrackletCalculatorDisplaced.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 DDLSeeding(), LLDSeeding(), and LLLSeeding().

◆ addInput()

void TrackletCalculatorDisplaced::addInput	(	MemoryBase *	memory,
		std::string	input
	)

overridevirtual

Implements trklet::ProcessBase.

Definition at line 175 of file TrackletCalculatorDisplaced.cc.

                                                                            {
   if (settings_.writetrace()) {
     edm::LogVerbatim("Tracklet") << "In " << name_ << " adding input from " << memory->getName() << " to input "
                                  << input;
   }
   if (input == "thirdallstubin") {
     auto* tmp = dynamic_cast<AllStubsMemory*>(memory);
     assert(tmp != nullptr);
     innerallstubs_.push_back(tmp);
     return;
   }
   if (input == "firstallstubin") {
     auto* tmp = dynamic_cast<AllStubsMemory*>(memory);
     assert(tmp != nullptr);
     middleallstubs_.push_back(tmp);
     return;
   }
   if (input == "secondallstubin") {
     auto* tmp = dynamic_cast<AllStubsMemory*>(memory);
     assert(tmp != nullptr);
     outerallstubs_.push_back(tmp);
     return;
   }
   if (input.find("stubtriplet") == 0) {
     auto* tmp = dynamic_cast<StubTripletsMemory*>(memory);
     assert(tmp != nullptr);
     stubtriplets_.push_back(tmp);
     return;
   }
   throw cms::Exception("BadConfig") << __FILE__ << " " << __LINE__ << " Could not find input : " << input;
 }

References cms::cuda::assert(), Exception, innerallstubs_, input, mps_setup::memory, middleallstubs_, trklet::ProcessBase::name_, outerallstubs_, trklet::ProcessBase::settings_, stubtriplets_, createJobs::tmp, and trklet::Settings::writetrace().

◆ addLayerProj()

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

Definition at line 296 of file TrackletCalculatorDisplaced.cc.

                                                                             {
   assert(layer > 0);
  
   FPGAWord fpgaz = tracklet->fpgazproj(layer);
   FPGAWord fpgaphi = tracklet->fpgaphiproj(layer);
  
   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 DDLSeeding(), LLDSeeding(), and LLLSeeding().

◆ addOutput()

void TrackletCalculatorDisplaced::addOutput	(	MemoryBase *	memory,
		std::string	output
	)

overridevirtual

Implements trklet::ProcessBase.

Definition at line 133 of file TrackletCalculatorDisplaced.cc.

                                                                              {
   if (settings_.writetrace()) {
     edm::LogVerbatim("Tracklet") << "In " << name_ << " adding output to " << memory->getName() << " to output "
                                  << output;
   }
   if (output == "trackpar") {
     auto* tmp = dynamic_cast<TrackletParametersMemory*>(memory);
     assert(tmp != nullptr);
     trackletpars_ = tmp;
     return;
   }
  
   if (output.substr(0, 7) == "projout") {
     //output is on the form 'projoutL2PHIC' or 'projoutD3PHIB'
     auto* tmp = dynamic_cast<TrackletProjectionsMemory*>(memory);
     assert(tmp != nullptr);
  
     unsigned int layerdisk = output[8] - '1';   //layer or disk counting from 0
     unsigned int phiregion = output[12] - 'A';  //phiregion counting from 0
  
     if (output[7] == 'L') {
       assert(layerdisk < N_LAYER);
       assert(phiregion < trackletprojlayers_[layerdisk].size());
       //check that phiregion not already initialized
       assert(trackletprojlayers_[layerdisk][phiregion] == nullptr);
       trackletprojlayers_[layerdisk][phiregion] = tmp;
       return;
     }
  
     if (output[7] == 'D') {
       assert(layerdisk < N_DISK);
       assert(phiregion < trackletprojdisks_[layerdisk].size());
       //check that phiregion not already initialized
       assert(trackletprojdisks_[layerdisk][phiregion] == nullptr);
       trackletprojdisks_[layerdisk][phiregion] = tmp;
       return;
     }
   }
  
   throw cms::Exception("BadConfig") << __FILE__ << " " << __LINE__ << " Could not find output : " << output;
 }

References cms::cuda::assert(), Exception, mps_setup::memory, trklet::N_DISK, trklet::N_LAYER, trklet::ProcessBase::name_, convertSQLitetoXML_cfg::output, trklet::ProcessBase::settings_, findQualityFiles::size, createJobs::tmp, trackletpars_, trackletprojdisks_, trackletprojlayers_, and trklet::Settings::writetrace().

◆ addOutputProjection()

void TrackletCalculatorDisplaced::addOutputProjection	(	TrackletProjectionsMemory *&	outputProj,
		MemoryBase *	memory
	)

Definition at line 128 of file TrackletCalculatorDisplaced.cc.

                                                                                                                 {
   outputProj = dynamic_cast<TrackletProjectionsMemory*>(memory);
   assert(outputProj != nullptr);
 }

References cms::cuda::assert(), and mps_setup::memory.

◆ addProjection()

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

Definition at line 316 of file TrackletCalculatorDisplaced.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 TrackletCalculatorDisplaced::addProjectionDisk	(	int	disk,
		int	iphi,
		TrackletProjectionsMemory *	trackletprojs,
		Tracklet *	tracklet
	)

Definition at line 331 of file TrackletCalculatorDisplaced.cc.

                                                                         {
   if (trackletprojs == nullptr) {
     if (layer_ == 3 && 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);
   if (settings_.debugTracklet()) {
     edm::LogVerbatim("Tracklet") << getName() << " adding projection to " << trackletprojs->getName();
   }
   trackletprojs->addProj(tracklet);
 }

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

Referenced by addDiskProj().

◆ DDLSeeding()

bool TrackletCalculatorDisplaced::DDLSeeding	(	const Stub *	innerFPGAStub,
		const L1TStub *	innerStub,
		const Stub *	middleFPGAStub,
		const L1TStub *	middleStub,
		const Stub *	outerFPGAStub,
		const L1TStub *	outerStub
	)

Definition at line 699 of file TrackletCalculatorDisplaced.cc.

                                                                        {
   if (settings_.debugTracklet()) {
     edm::LogVerbatim("Tracklet") << "TrackletCalculatorDisplaced " << getName() << " " << layer_
                                  << " trying stub triplet in  (L2 D1 D2): " << innerFPGAStub->layer().value() << " "
                                  << middleFPGAStub->disk().value() << " " << outerFPGAStub->disk().value();
   }
  
   int take3 = 1;  //D1D2L2
  
   double r1 = innerStub->r();
   double z1 = innerStub->z();
   double phi1 = innerStub->phi();
  
   double r2 = middleStub->r();
   double z2 = middleStub->z();
   double phi2 = middleStub->phi();
  
   double r3 = outerStub->r();
   double z3 = outerStub->z();
   double phi3 = outerStub->phi();
  
   double rinv, phi0, d0, 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,
                 r3,
                 z3,
                 phi3,
                 take3,
                 rinv,
                 phi0,
                 d0,
                 t,
                 z0,
                 phiproj,
                 zproj,
                 phiprojdisk,
                 rprojdisk,
                 phider,
                 zder,
                 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, d0approx, tapprox, z0approx;
   double phiprojapprox[N_LAYER - 2], zprojapprox[N_LAYER - 2], phiderapprox[N_LAYER - 2], zderapprox[N_LAYER - 2];
   double phiprojdiskapprox[N_DISK], rprojdiskapprox[N_DISK];
   double phiderdiskapprox[N_DISK], rderdiskapprox[N_DISK];
  
   //TODO: implement the actual integer calculation
  
   //store the approcximate results
   rinvapprox = rinv;
   phi0approx = phi0;
   d0approx = d0;
   tapprox = t;
   z0approx = z0;
  
   for (unsigned int i = 0; i < toR_.size(); ++i) {
     phiprojapprox[i] = phiproj[i];
     zprojapprox[i] = zproj[i];
     phiderapprox[i] = phider[i];
     zderapprox[i] = zder[i];
   }
  
   for (unsigned int i = 0; i < toZ_.size(); ++i) {
     phiprojdiskapprox[i] = phiprojdisk[i];
     rprojdiskapprox[i] = rprojdisk[i];
     phiderdiskapprox[i] = phiderdisk[i];
     rderdiskapprox[i] = rderdisk[i];
   }
  
   //now binary
   double krinv = settings_.kphi1() / settings_.kr() * pow(2, settings_.rinv_shift()),
          kphi0 = settings_.kphi1() * pow(2, settings_.phi0_shift()),
          kt = settings_.kz() / settings_.kr() * pow(2, settings_.t_shift()),
          kz0 = settings_.kz() * pow(2, settings_.z0_shift()),
          kphiproj = settings_.kphi1() * pow(2, settings_.SS_phiL_shift()),
          kphider = settings_.kphi1() / settings_.kr() * pow(2, settings_.SS_phiderL_shift()),
          kzproj = settings_.kz() * pow(2, settings_.PS_zL_shift()),
          kzder = settings_.kz() / settings_.kr() * pow(2, settings_.PS_zderL_shift()),
          kphiprojdisk = settings_.kphi1() * pow(2, settings_.SS_phiD_shift()),
          kphiderdisk = settings_.kphi1() / settings_.kr() * pow(2, settings_.SS_phiderD_shift()),
          krprojdisk = settings_.kr() * pow(2, settings_.PS_rD_shift()),
          krderdisk = settings_.kr() / settings_.kz() * pow(2, settings_.PS_rderD_shift());
  
   int irinv, iphi0, id0, it, iz0;
   int iphiproj[N_LAYER - 2], izproj[N_LAYER - 2], iphider[N_LAYER - 2], izder[N_LAYER - 2];
   int iphiprojdisk[N_DISK], irprojdisk[N_DISK], iphiderdisk[N_DISK], irderdisk[N_DISK];
  
   //store the binary results
   irinv = rinvapprox / krinv;
   iphi0 = phi0approx / kphi0;
   id0 = d0approx / settings_.kd0();
   it = tapprox / kt;
   iz0 = z0approx / kz0;
  
   bool success = true;
   if (std::abs(rinvapprox) > settings_.rinvcut()) {
     if (settings_.debugTracklet())
       edm::LogVerbatim("Tracklet") << "TrackletCalculator::DDL Seeding irinv too large: " << rinvapprox << "(" << irinv
                                    << ")";
     success = false;
   }
   if (std::abs(z0approx) > 1.8 * settings_.z0cut()) {
     if (settings_.debugTracklet())
       edm::LogVerbatim("Tracklet") << "Failed tracklet z0 cut " << z0approx;
     success = false;
   }
   if (std::abs(d0approx) > settings_.maxd0()) {
     if (settings_.debugTracklet())
       edm::LogVerbatim("Tracklet") << "Failed tracklet d0 cut " << d0approx;
     success = false;
   }
  
   if (!success)
     return false;
  
   double phicritapprox = phi0approx - asin(0.5 * settings_.rcrit() * rinvapprox);
   int phicrit = iphi0 - 2 * irinv;
  
   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 = (phicrit > iphicritmincut) && (phicrit < iphicritmaxcut);
  
   if (settings_.debugTracklet())
     if (keep && !keepapprox)
       edm::LogVerbatim("Tracklet") << "TrackletCalculatorDisplaced::DDLSeeding tracklet kept with exact phicrit cut "
                                       "but not approximate, phicritapprox: "
                                    << phicritapprox;
   if (settings_.usephicritapprox()) {
     if (!keepapprox)
       return false;
   } else {
     if (!keep)
       return false;
   }
  
   LayerProjection layerprojs[N_LAYER - 2];
   DiskProjection diskprojs[N_DISK];
  
   for (unsigned int i = 0; i < toR_.size(); ++i) {
     iphiproj[i] = phiprojapprox[i] / kphiproj;
     izproj[i] = zprojapprox[i] / kzproj;
  
     iphider[i] = phiderapprox[i] / kphider;
     izder[i] = zderapprox[i] / kzder;
  
     //check that z projection in range
     if (izproj[i] < -(1 << (settings_.nzbitsstub(0) - 1)))
       continue;
     if (izproj[i] >= (1 << (settings_.nzbitsstub(0) - 1)))
       continue;
  
     //check that phi projection in range
     if (iphiproj[i] >= (1 << settings_.nphibitsstub(5)) - 1)
       continue;
     if (iphiproj[i] <= 0)
       continue;
  
     if (rproj_[i] < settings_.rPS2S()) {
       iphiproj[i] >>= (settings_.nphibitsstub(5) - settings_.nphibitsstub(0));
     } else {
       izproj[i] >>= (settings_.nzbitsstub(0) - settings_.nzbitsstub(5));
     }
  
     if (rproj_[i] < settings_.rPS2S()) {
       if (iphider[i] < -(1 << (settings_.nbitsphiprojderL123() - 1)))
         iphider[i] = -(1 << (settings_.nbitsphiprojderL123() - 1));
       if (iphider[i] >= (1 << (settings_.nbitsphiprojderL123() - 1)))
         iphider[i] = (1 << (settings_.nbitsphiprojderL123() - 1)) - 1;
     } else {
       if (iphider[i] < -(1 << (settings_.nbitsphiprojderL456() - 1)))
         iphider[i] = -(1 << (settings_.nbitsphiprojderL456() - 1));
       if (iphider[i] >= (1 << (settings_.nbitsphiprojderL456() - 1)))
         iphider[i] = (1 << (settings_.nbitsphiprojderL456() - 1)) - 1;
     }
  
     layerprojs[i].init(settings_,
                        lproj_[i],
                        rproj_[i],
                        iphiproj[i],
                        izproj[i],
                        iphider[i],
                        izder[i],
                        phiproj[i],
                        zproj[i],
                        phider[i],
                        zder[i],
                        phiprojapprox[i],
                        zprojapprox[i],
                        phiderapprox[i],
                        zderapprox[i]);
   }
  
   if (std::abs(it * kt) > 1.0) {
     for (unsigned int i = 0; i < toZ_.size(); ++i) {
       iphiprojdisk[i] = phiprojdiskapprox[i] / kphiprojdisk;
       irprojdisk[i] = rprojdiskapprox[i] / krprojdisk;
  
       iphiderdisk[i] = phiderdiskapprox[i] / kphiderdisk;
       irderdisk[i] = rderdiskapprox[i] / krderdisk;
  
       if (iphiprojdisk[i] <= 0)
         continue;
       if (iphiprojdisk[i] >= (1 << settings_.nphibitsstub(0)) - 1)
         continue;
  
       if (irprojdisk[i] < settings_.rmindisk() / krprojdisk || irprojdisk[i] > settings_.rmaxdisk() / krprojdisk)
         continue;
  
       diskprojs[i].init(settings_,
                         i + 1,
                         rproj_[i],
                         iphiprojdisk[i],
                         irprojdisk[i],
                         iphiderdisk[i],
                         irderdisk[i],
                         phiprojdisk[i],
                         rprojdisk[i],
                         phiderdisk[i],
                         rderdisk[i],
                         phiprojdiskapprox[i],
                         rprojdiskapprox[i],
                         phiderdisk[i],
                         rderdisk[i]);
     }
   }
  
   if (settings_.writeMonitorData("TrackletPars")) {
     globals_->ofstream("trackletpars.txt")
         << "Trackpars " << layer_ << "   " << rinv << " " << rinvapprox << " " << rinvapprox << "   " << phi0 << " "
         << phi0approx << " " << phi0approx << "   " << t << " " << tapprox << " " << tapprox << "   " << z0 << " "
         << z0approx << " " << z0approx << endl;
   }
  
   Tracklet* tracklet = new Tracklet(settings_,
                                     innerStub,
                                     middleStub,
                                     outerStub,
                                     innerFPGAStub,
                                     middleFPGAStub,
                                     outerFPGAStub,
                                     rinv,
                                     phi0,
                                     d0,
                                     z0,
                                     t,
                                     rinvapprox,
                                     phi0approx,
                                     d0approx,
                                     z0approx,
                                     tapprox,
                                     irinv,
                                     iphi0,
                                     id0,
                                     iz0,
                                     it,
                                     layerprojs,
                                     diskprojs,
                                     true);
  
   if (settings_.debugTracklet()) {
     edm::LogVerbatim("Tracklet") << "TrackletCalculatorDisplaced " << getName()
                                  << " Found DDL tracklet in sector = " << 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);
  
   for (unsigned int j = 0; j < toR_.size(); j++) {
     if (settings_.debugTracklet())
       edm::LogVerbatim("Tracklet") << "adding layer projection " << j << "/" << toR_.size() << " " << lproj_[j] << " "
                                    << tracklet->validProj(lproj_[j]);
     if (tracklet->validProj(lproj_[j])) {
       addLayerProj(tracklet, lproj_[j]);
     }
   }
  
   for (unsigned int j = 0; j < toZ_.size(); j++) {
     int disk = dproj_[j];
     if (disk == 0)
       continue;
     if (it < 0)
       disk = -disk;
     if (settings_.debugTracklet())
       edm::LogVerbatim("Tracklet") << "adding disk projection " << j << "/" << toZ_.size() << " " << disk << " "
                                    << tracklet->validProjDisk(abs(disk));
     if (tracklet->validProjDisk(abs(disk))) {
       addDiskProj(tracklet, disk);
     }
   }
  
   return true;
 }

Referenced by execute().

◆ exactproj()

void TrackletCalculatorDisplaced::exactproj	(	double	rproj,
		double	rinv,
		double	phi0,
		double	d0,
		double	t,
		double	z0,
		double	r0,
		double &	phiproj,
		double &	zproj,
		double &	phider,
		double &	zder
	)

Definition at line 1350 of file TrackletCalculatorDisplaced.cc.

                                                           {
   double rho = 1 / rinv;
   if (rho < 0) {
     r0 = -r0;
   }
   phiproj = phi0 - asin((rproj * rproj + r0 * r0 - rho * rho) / (2 * rproj * r0));
   double beta = acos((rho * rho + r0 * r0 - rproj * rproj) / (2 * r0 * rho));
   zproj = z0 + t * std::abs(rho * beta);
  
   //not exact, but close
   phider = -0.5 * rinv / sqrt(1 - pow(0.5 * rproj * rinv, 2)) + d0 / (rproj * rproj);
   zder = t / sqrt(1 - pow(0.5 * rproj * rinv, 2));
  
   if (settings_.debugTracklet()) {
     edm::LogVerbatim("Tracklet") << "exact proj layer at " << rproj << " : " << phiproj << " " << zproj;
   }
 }

References funct::abs(), zMuMuMuonUserData::beta, d0, trklet::Settings::debugTracklet(), funct::pow(), trklet::rinv(), trklet::ProcessBase::settings_, mathSSE::sqrt(), submitPVValidationJobs::t, and HLTMuonOfflineAnalyzer_cfi::z0.

Referenced by exacttracklet().

◆ exactprojdisk()

void TrackletCalculatorDisplaced::exactprojdisk	(	double	zproj,
		double	rinv,
		double	,
		double	,
		double	t,
		double	z0,
		double	x0,
		double	y0,
		double &	phiproj,
		double &	rproj,
		double &	phider,
		double &	rder
	)

Definition at line 1378 of file TrackletCalculatorDisplaced.cc.

                                                               {
   //protect against t=0
   if (std::abs(t) < 0.1)
     t = 0.1;
   if (t < 0)
     zproj = -zproj;
   double rho = std::abs(1 / rinv);
   double beta = (zproj - z0) / (t * rho);
   double phiV = atan2(-y0, -x0);
   double c = rinv > 0 ? -1 : 1;
  
   double x = x0 + rho * cos(phiV + c * beta);
   double y = y0 + rho * sin(phiV + c * beta);
  
   phiproj = atan2(y, x);
  
   phiproj = reco::reduceRange(phiproj - phimin_);
  
   rproj = sqrt(x * x + y * y);
  
   phider = c / t / (x * x + y * y) * (rho + x0 * cos(phiV + c * beta) + y0 * sin(phiV + c * beta));
   rder = c / t / rproj * (y0 * cos(phiV + c * beta) - x0 * sin(phiV + c * beta));
  
   if (settings_.debugTracklet()) {
     edm::LogVerbatim("Tracklet") << "exact proj disk at" << zproj << " : " << phiproj << " " << rproj;
   }
 }

References funct::abs(), zMuMuMuonUserData::beta, HltBtagPostValidation_cff::c, funct::cos(), trklet::Settings::debugTracklet(), trklet::ProcessBase::phimin_, reco::reduceRange(), trklet::rinv(), trklet::ProcessBase::settings_, funct::sin(), mathSSE::sqrt(), submitPVValidationJobs::t, and HLTMuonOfflineAnalyzer_cfi::z0.

Referenced by exacttracklet().

◆ exacttracklet()

void TrackletCalculatorDisplaced::exacttracklet	(	double	r1,
		double	z1,
		double	phi1,
		double	r2,
		double	z2,
		double	phi2,
		double	r3,
		double	z3,
		double	phi3,
		int	take3,
		double &	rinv,
		double &	phi0,
		double &	d0,
		double &	t,
		double &	z0,
		double	phiproj[N_LAYER - 2],
		double	zproj[N_LAYER - 2],
		double	phiprojdisk[N_DISK],
		double	rprojdisk[N_DISK],
		double	phider[N_LAYER - 2],
		double	zder[N_LAYER - 2],
		double	phiderdisk[N_DISK],
		double	rderdisk[N_DISK]
	)

Definition at line 1417 of file TrackletCalculatorDisplaced.cc.

                                                                          {
   //two lines perpendicular to the 1->2 and 2->3
   double x1 = r1 * cos(phi1);
   double x2 = r2 * cos(phi2);
   double x3 = r3 * cos(phi3);
  
   double y1 = r1 * sin(phi1);
   double y2 = r2 * sin(phi2);
   double y3 = r3 * sin(phi3);
  
   double k1 = -(x2 - x1) / (y2 - y1);
   double k2 = -(x3 - x2) / (y3 - y2);
   double b1 = 0.5 * (y2 + y1) - 0.5 * (x1 + x2) * k1;
   double b2 = 0.5 * (y3 + y2) - 0.5 * (x2 + x3) * k2;
   //their intersection gives the center of the circle
   double y0 = (b1 * k2 - b2 * k1) / (k2 - k1);
   double x0 = (b1 - b2) / (k2 - k1);
   //get the radius three ways:
   double R1 = sqrt(pow(x1 - x0, 2) + pow(y1 - y0, 2));
   double R2 = sqrt(pow(x2 - x0, 2) + pow(y2 - y0, 2));
   double R3 = sqrt(pow(x3 - x0, 2) + pow(y3 - y0, 2));
   //check if the same
   double eps1 = std::abs(R1 / R2 - 1);
   double eps2 = std::abs(R3 / R2 - 1);
   if (eps1 > 1e-10 || eps2 > 1e-10)
     edm::LogVerbatim("Tracklet") << "&&&&&&&&&&&& bad circle! " << R1 << "\t" << R2 << "\t" << R3;
  
   //results
   rinv = 1. / R1;
   phi0 = 0.5 * M_PI + atan2(y0, x0);
  
   phi0 -= phimin_;
  
   d0 = -R1 + sqrt(x0 * x0 + y0 * y0);
   //sign of rinv:
   double dphi = reco::reduceRange(phi3 - atan2(y0, x0));
   if (dphi < 0) {
     rinv = -rinv;
     d0 = -d0;
     phi0 = phi0 + M_PI;
   }
   phi0 = angle0to2pi::make0To2pi(phi0);
  
   //now in RZ:
   //turning angle
   double beta1 = reco::reduceRange(atan2(y1 - y0, x1 - x0) - atan2(-y0, -x0));
   double beta2 = reco::reduceRange(atan2(y2 - y0, x2 - x0) - atan2(-y0, -x0));
   double beta3 = reco::reduceRange(atan2(y3 - y0, x3 - x0) - atan2(-y0, -x0));
  
   double t12 = (z2 - z1) / std::abs(beta2 - beta1) / R1;
   double z12 = (z1 * beta2 - z2 * beta1) / (beta2 - beta1);
   double t13 = (z3 - z1) / std::abs(beta3 - beta1) / R1;
   double z13 = (z1 * beta3 - z3 * beta1) / (beta3 - beta1);
  
   if (take3 > 0) {
     //take 13 (large lever arm)
     t = t13;
     z0 = z13;
   } else {
     //take 12 (pixel layers)
     t = t12;
     z0 = z12;
   }
  
   if (settings_.debugTracklet())
     edm::LogVerbatim("Tracklet") << "exact tracklet: " << rinv << " " << phi0 << " " << d0 << " " << t << " " << z0;
  
   for (unsigned int i = 0; i < toR_.size(); i++) {
     exactproj(toR_[i], rinv, phi0, d0, t, z0, sqrt(x0 * x0 + y0 * y0), phiproj[i], zproj[i], phider[i], zder[i]);
   }
  
   for (unsigned int i = 0; i < toZ_.size(); i++) {
     exactprojdisk(toZ_[i], rinv, phi0, d0, t, z0, x0, y0, phiprojdisk[i], rprojdisk[i], phiderdisk[i], rderdisk[i]);
   }
 }

References funct::abs(), b1, b2, funct::cos(), d0, trklet::Settings::debugTracklet(), MillePedeFileConverter_cfg::e, exactproj(), exactprojdisk(), mps_fire::i, M_PI, angle0to2pi::make0To2pi(), trklet::ProcessBase::phimin_, funct::pow(), diffTwoXMLs::r1, diffTwoXMLs::r2, reco::reduceRange(), trklet::rinv(), trklet::ProcessBase::settings_, funct::sin(), mathSSE::sqrt(), submitPVValidationJobs::t, toR_, toZ_, testProducerWithPsetDescEmpty_cfi::x1, testProducerWithPsetDescEmpty_cfi::x2, testProducerWithPsetDescEmpty_cfi::y1, testProducerWithPsetDescEmpty_cfi::y2, HLTMuonOfflineAnalyzer_cfi::z0, and testProducerWithPsetDescEmpty_cfi::z2.

Referenced by DDLSeeding(), LLDSeeding(), and LLLSeeding().

◆ execute()

void TrackletCalculatorDisplaced::execute ( void )

Definition at line 207 of file TrackletCalculatorDisplaced.cc.

                                           {
   unsigned int countall = 0;
   unsigned int countsel = 0;
  
   for (auto& stubtriplet : stubtriplets_) {
     if (trackletpars_->nTracklets() >= settings_.ntrackletmax()) {
       edm::LogVerbatim("Tracklet") << "Will break on too many tracklets in " << getName();
       break;
     }
     for (unsigned int i = 0; i < stubtriplet->nStubTriplets(); i++) {
       countall++;
  
       const Stub* innerFPGAStub = stubtriplet->getFPGAStub1(i);
       const L1TStub* innerStub = innerFPGAStub->l1tstub();
  
       const Stub* middleFPGAStub = stubtriplet->getFPGAStub2(i);
       const L1TStub* middleStub = middleFPGAStub->l1tstub();
  
       const Stub* outerFPGAStub = stubtriplet->getFPGAStub3(i);
       const L1TStub* outerStub = outerFPGAStub->l1tstub();
  
       if (settings_.debugTracklet()) {
         edm::LogVerbatim("Tracklet") << "TrackletCalculatorDisplaced execute " << getName() << "[" << iSector_ << "]";
       }
  
       if (innerFPGAStub->isBarrel() && middleFPGAStub->isBarrel() && outerFPGAStub->isBarrel()) {
         //barrel+barrel seeding
         bool accept = LLLSeeding(innerFPGAStub, innerStub, middleFPGAStub, middleStub, outerFPGAStub, outerStub);
         if (accept)
           countsel++;
       } else if (innerFPGAStub->isDisk() && middleFPGAStub->isDisk() && outerFPGAStub->isDisk()) {
         throw cms::Exception("LogicError") << __FILE__ << " " << __LINE__ << " Invalid seeding!";
       } else {
         //layer+disk seeding
         if (innerFPGAStub->isBarrel() && middleFPGAStub->isDisk() && outerFPGAStub->isDisk()) {  //D1D2L2
           bool accept = DDLSeeding(innerFPGAStub, innerStub, middleFPGAStub, middleStub, outerFPGAStub, outerStub);
           if (accept)
             countsel++;
         } else if (innerFPGAStub->isDisk() && middleFPGAStub->isBarrel() && outerFPGAStub->isBarrel()) {  //L2L3D1
           bool accept = LLDSeeding(innerFPGAStub, innerStub, middleFPGAStub, middleStub, outerFPGAStub, outerStub);
           if (accept)
             countsel++;
         } else {
           throw cms::Exception("LogicError") << __FILE__ << " " << __LINE__ << " Invalid seeding!";
         }
       }
  
       if (trackletpars_->nTracklets() >= settings_.ntrackletmax()) {
         edm::LogVerbatim("Tracklet") << "Will break on number of tracklets in " << getName();
         break;
       }
  
       if (countall >= settings_.maxStep("TC")) {
         if (settings_.debugTracklet())
           edm::LogVerbatim("Tracklet") << "Will break on MAXTC 1";
         break;
       }
       if (settings_.debugTracklet()) {
         edm::LogVerbatim("Tracklet") << "TrackletCalculatorDisplaced execute done";
       }
     }
     if (countall >= settings_.maxStep("TC")) {
       if (settings_.debugTracklet())
         edm::LogVerbatim("Tracklet") << "Will break on MAXTC 2";
       break;
     }
   }
  
   if (settings_.writeMonitorData("TPD")) {
     globals_->ofstream("trackletcalculatordisplaced.txt") << getName() << " " << countall << " " << countsel << endl;
   }
 }

References accept(), DDLSeeding(), trklet::Settings::debugTracklet(), Exception, trklet::ProcessBase::getName(), trklet::ProcessBase::globals_, mps_fire::i, trklet::Stub::isBarrel(), trklet::Stub::isDisk(), trklet::ProcessBase::iSector_, trklet::Stub::l1tstub(), LLDSeeding(), LLLSeeding(), trklet::Settings::maxStep(), trklet::Settings::ntrackletmax(), trklet::TrackletParametersMemory::nTracklets(), trklet::Globals::ofstream(), trklet::ProcessBase::settings_, stubtriplets_, trackletpars_, and trklet::Settings::writeMonitorData().

◆ LLDSeeding()

bool TrackletCalculatorDisplaced::LLDSeeding	(	const Stub *	innerFPGAStub,
		const L1TStub *	innerStub,
		const Stub *	middleFPGAStub,
		const L1TStub *	middleStub,
		const Stub *	outerFPGAStub,
		const L1TStub *	outerStub
	)

Definition at line 1025 of file TrackletCalculatorDisplaced.cc.

                                                                        {
   if (settings_.debugTracklet()) {
     edm::LogVerbatim("Tracklet") << "TrackletCalculatorDisplaced " << getName() << " " << layer_
                                  << " trying stub triplet in  (L2L3D1): " << middleFPGAStub->layer().value() << " "
                                  << outerFPGAStub->layer().value() << " " << innerFPGAStub->disk().value();
   }
  
   int take3 = 0;  //L2L3D1
  
   double r3 = innerStub->r();
   double z3 = innerStub->z();
   double phi3 = innerStub->phi();
  
   double r1 = middleStub->r();
   double z1 = middleStub->z();
   double phi1 = middleStub->phi();
  
   double r2 = outerStub->r();
   double z2 = outerStub->z();
   double phi2 = outerStub->phi();
  
   double rinv, phi0, d0, 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,
                 r3,
                 z3,
                 phi3,
                 take3,
                 rinv,
                 phi0,
                 d0,
                 t,
                 z0,
                 phiproj,
                 zproj,
                 phiprojdisk,
                 rprojdisk,
                 phider,
                 zder,
                 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, d0approx, tapprox, z0approx;
   double phiprojapprox[N_LAYER - 2], zprojapprox[N_LAYER - 2], phiderapprox[N_LAYER - 2], zderapprox[N_LAYER - 2];
   double phiprojdiskapprox[N_DISK], rprojdiskapprox[N_DISK];
   double phiderdiskapprox[N_DISK], rderdiskapprox[N_DISK];
  
   //TODO: implement the actual integer calculation
  
   //store the approcximate results
   rinvapprox = rinv;
   phi0approx = phi0;
   d0approx = d0;
   tapprox = t;
   z0approx = z0;
  
   for (unsigned int i = 0; i < toR_.size(); ++i) {
     phiprojapprox[i] = phiproj[i];
     zprojapprox[i] = zproj[i];
     phiderapprox[i] = phider[i];
     zderapprox[i] = zder[i];
   }
  
   for (unsigned int i = 0; i < toZ_.size(); ++i) {
     phiprojdiskapprox[i] = phiprojdisk[i];
     rprojdiskapprox[i] = rprojdisk[i];
     phiderdiskapprox[i] = phiderdisk[i];
     rderdiskapprox[i] = rderdisk[i];
   }
  
   //now binary
   double krinv = settings_.kphi1() / settings_.kr() * pow(2, settings_.rinv_shift()),
          kphi0 = settings_.kphi1() * pow(2, settings_.phi0_shift()),
          kt = settings_.kz() / settings_.kr() * pow(2, settings_.t_shift()),
          kz0 = settings_.kz() * pow(2, settings_.z0_shift()),
          kphiproj = settings_.kphi1() * pow(2, settings_.SS_phiL_shift()),
          kphider = settings_.kphi1() / settings_.kr() * pow(2, settings_.SS_phiderL_shift()),
          kzproj = settings_.kz() * pow(2, settings_.PS_zL_shift()),
          kzder = settings_.kz() / settings_.kr() * pow(2, settings_.PS_zderL_shift()),
          kphiprojdisk = settings_.kphi1() * pow(2, settings_.SS_phiD_shift()),
          kphiderdisk = settings_.kphi1() / settings_.kr() * pow(2, settings_.SS_phiderD_shift()),
          krprojdisk = settings_.kr() * pow(2, settings_.PS_rD_shift()),
          krderdisk = settings_.kr() / settings_.kz() * pow(2, settings_.PS_rderD_shift());
  
   int irinv, iphi0, id0, it, iz0;
   int iphiproj[N_LAYER - 2], izproj[N_LAYER - 2], iphider[N_LAYER - 2], izder[N_LAYER - 2];
   int iphiprojdisk[N_DISK], irprojdisk[N_DISK], iphiderdisk[N_DISK], irderdisk[N_DISK];
  
   //store the binary results
   irinv = rinvapprox / krinv;
   iphi0 = phi0approx / kphi0;
   id0 = d0approx / settings_.kd0();
   it = tapprox / kt;
   iz0 = z0approx / kz0;
  
   bool success = true;
   if (std::abs(rinvapprox) > settings_.rinvcut()) {
     if (settings_.debugTracklet())
       edm::LogVerbatim("Tracklet") << "TrackletCalculator:: LLD Seeding irinv too large: " << rinvapprox << "(" << irinv
                                    << ")";
     success = false;
   }
   if (std::abs(z0approx) > 1.8 * settings_.z0cut()) {
     if (settings_.debugTracklet())
       edm::LogVerbatim("Tracklet") << "Failed tracklet z0 cut " << z0approx;
     success = false;
   }
   if (std::abs(d0approx) > settings_.maxd0()) {
     if (settings_.debugTracklet())
       edm::LogVerbatim("Tracklet") << "Failed tracklet d0 cut " << d0approx;
     success = false;
   }
  
   if (!success)
     return false;
  
   double phicritapprox = phi0approx - asin(0.5 * settings_.rcrit() * rinvapprox);
   int phicrit = iphi0 - 2 * irinv;
  
   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 = (phicrit > iphicritmincut) && (phicrit < iphicritmaxcut);
  
   if (settings_.debugTracklet())
     if (keep && !keepapprox)
       edm::LogVerbatim("Tracklet") << "TrackletCalculatorDisplaced::LLDSeeding tracklet kept with exact phicrit cut "
                                       "but not approximate, phicritapprox: "
                                    << phicritapprox;
   if (settings_.usephicritapprox()) {
     if (!keepapprox)
       return false;
   } else {
     if (!keep)
       return false;
   }
  
   LayerProjection layerprojs[N_LAYER - 2];
   DiskProjection diskprojs[N_DISK];
  
   for (unsigned int i = 0; i < toR_.size(); ++i) {
     iphiproj[i] = phiprojapprox[i] / kphiproj;
     izproj[i] = zprojapprox[i] / kzproj;
  
     iphider[i] = phiderapprox[i] / kphider;
     izder[i] = zderapprox[i] / kzder;
  
     if (izproj[i] < -(1 << (settings_.nzbitsstub(0) - 1)))
       continue;
     if (izproj[i] >= (1 << (settings_.nzbitsstub(0) - 1)))
       continue;
  
     //this is left from the original....
     if (iphiproj[i] >= (1 << settings_.nphibitsstub(5)) - 1)
       continue;
     if (iphiproj[i] <= 0)
       continue;
  
     if (rproj_[i] < settings_.rPS2S()) {
       iphiproj[i] >>= (settings_.nphibitsstub(5) - settings_.nphibitsstub(0));
     } else {
       izproj[i] >>= (settings_.nzbitsstub(0) - settings_.nzbitsstub(5));
     }
  
     if (rproj_[i] < settings_.rPS2S()) {
       if (iphider[i] < -(1 << (settings_.nbitsphiprojderL123() - 1)))
         iphider[i] = -(1 << (settings_.nbitsphiprojderL123() - 1));
       if (iphider[i] >= (1 << (settings_.nbitsphiprojderL123() - 1)))
         iphider[i] = (1 << (settings_.nbitsphiprojderL123() - 1)) - 1;
     } else {
       if (iphider[i] < -(1 << (settings_.nbitsphiprojderL456() - 1)))
         iphider[i] = -(1 << (settings_.nbitsphiprojderL456() - 1));
       if (iphider[i] >= (1 << (settings_.nbitsphiprojderL456() - 1)))
         iphider[i] = (1 << (settings_.nbitsphiprojderL456() - 1)) - 1;
     }
  
     layerprojs[i].init(settings_,
                        lproj_[i],
                        rproj_[i],
                        iphiproj[i],
                        izproj[i],
                        iphider[i],
                        izder[i],
                        phiproj[i],
                        zproj[i],
                        phider[i],
                        zder[i],
                        phiprojapprox[i],
                        zprojapprox[i],
                        phiderapprox[i],
                        zderapprox[i]);
   }
  
   if (std::abs(it * kt) > 1.0) {
     for (unsigned int i = 0; i < toZ_.size(); ++i) {
       iphiprojdisk[i] = phiprojdiskapprox[i] / kphiprojdisk;
       irprojdisk[i] = rprojdiskapprox[i] / krprojdisk;
  
       iphiderdisk[i] = phiderdiskapprox[i] / kphiderdisk;
       irderdisk[i] = rderdiskapprox[i] / krderdisk;
  
       //Check phi range of projection
       if (iphiprojdisk[i] <= 0)
         continue;
       if (iphiprojdisk[i] >= (1 << settings_.nphibitsstub(0)) - 1)
         continue;
  
       //Check r range of projection
       if (irprojdisk[i] < settings_.rmindisk() / krprojdisk || irprojdisk[i] > settings_.rmaxdisk() / krprojdisk)
         continue;
  
       diskprojs[i].init(settings_,
                         i + 1,
                         rproj_[i],
                         iphiprojdisk[i],
                         irprojdisk[i],
                         iphiderdisk[i],
                         irderdisk[i],
                         phiprojdisk[i],
                         rprojdisk[i],
                         phiderdisk[i],
                         rderdisk[i],
                         phiprojdiskapprox[i],
                         rprojdiskapprox[i],
                         phiderdisk[i],
                         rderdisk[i]);
     }
   }
  
   if (settings_.writeMonitorData("TrackletPars")) {
     globals_->ofstream("trackletpars.txt")
         << "Trackpars " << layer_ << "   " << rinv << " " << rinvapprox << " " << rinvapprox << "   " << phi0 << " "
         << phi0approx << " " << phi0approx << "   " << t << " " << tapprox << " " << tapprox << "   " << z0 << " "
         << z0approx << " " << z0approx << endl;
   }
  
   Tracklet* tracklet = new Tracklet(settings_,
                                     innerStub,
                                     middleStub,
                                     outerStub,
                                     innerFPGAStub,
                                     middleFPGAStub,
                                     outerFPGAStub,
                                     rinv,
                                     phi0,
                                     d0,
                                     z0,
                                     t,
                                     rinvapprox,
                                     phi0approx,
                                     d0approx,
                                     z0approx,
                                     tapprox,
                                     irinv,
                                     iphi0,
                                     id0,
                                     iz0,
                                     it,
                                     layerprojs,
                                     diskprojs,
                                     false);
  
   if (settings_.debugTracklet()) {
     edm::LogVerbatim("Tracklet") << "TrackletCalculatorDisplaced " << getName()
                                  << " Found LLD tracklet in sector = " << 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);
  
   for (unsigned int j = 0; j < toR_.size(); j++) {
     if (settings_.debugTracklet())
       edm::LogVerbatim("Tracklet") << "adding layer projection " << j << "/" << toR_.size() << " " << lproj_[j];
     if (tracklet->validProj(lproj_[j])) {
       addLayerProj(tracklet, lproj_[j]);
     }
   }
  
   for (unsigned int j = 0; j < toZ_.size(); j++) {
     int disk = dproj_[j];
     if (disk == 0)
       continue;
     if (it < 0)
       disk = -disk;
     if (settings_.debugTracklet())
       edm::LogVerbatim("Tracklet") << "adding disk projection " << j << "/" << toZ_.size() << " " << disk;
     if (tracklet->validProjDisk(abs(disk))) {
       addDiskProj(tracklet, disk);
     }
   }
  
   return true;
 }

Referenced by execute().

◆ LLLSeeding()

bool TrackletCalculatorDisplaced::LLLSeeding	(	const Stub *	innerFPGAStub,
		const L1TStub *	innerStub,
		const Stub *	middleFPGAStub,
		const L1TStub *	middleStub,
		const Stub *	outerFPGAStub,
		const L1TStub *	outerStub
	)

Definition at line 351 of file TrackletCalculatorDisplaced.cc.

                                                                        {
   if (settings_.debugTracklet()) {
     edm::LogVerbatim("Tracklet") << "TrackletCalculatorDisplaced " << getName() << " " << layer_
                                  << " trying stub triplet in layer (L L L): " << innerFPGAStub->layer().value() << " "
                                  << middleFPGAStub->layer().value() << " " << outerFPGAStub->layer().value();
   }
  
   assert(outerFPGAStub->isBarrel());
  
   double r1 = innerStub->r();
   double z1 = innerStub->z();
   double phi1 = innerStub->phi();
  
   double r2 = middleStub->r();
   double z2 = middleStub->z();
   double phi2 = middleStub->phi();
  
   double r3 = outerStub->r();
   double z3 = outerStub->z();
   double phi3 = outerStub->phi();
  
   int take3 = 0;
   if (layer_ == 5)
     take3 = 1;
  
   double rinv, phi0, d0, t, z0;
  
   LayerProjection layerprojs[N_LAYER - 2];
   DiskProjection diskprojs[N_DISK];
  
   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,
                 r3,
                 z3,
                 phi3,
                 take3,
                 rinv,
                 phi0,
                 d0,
                 t,
                 z0,
                 phiproj,
                 zproj,
                 phiprojdisk,
                 rprojdisk,
                 phider,
                 zder,
                 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, d0approx, tapprox, z0approx;
   double phiprojapprox[N_LAYER - 2], zprojapprox[N_LAYER - 2], phiderapprox[N_LAYER - 2], zderapprox[N_LAYER - 2];
   double phiprojdiskapprox[N_DISK], rprojdiskapprox[N_DISK];
   double phiderdiskapprox[N_DISK], rderdiskapprox[N_DISK];
  
   //TODO: implement the actual integer calculation
  
   //store the approcximate results
   rinvapprox = rinv;
   phi0approx = phi0;
   d0approx = d0;
   tapprox = t;
   z0approx = z0;
  
   for (unsigned int i = 0; i < toR_.size(); ++i) {
     phiprojapprox[i] = phiproj[i];
     zprojapprox[i] = zproj[i];
     phiderapprox[i] = phider[i];
     zderapprox[i] = zder[i];
   }
  
   for (unsigned int i = 0; i < toZ_.size(); ++i) {
     phiprojdiskapprox[i] = phiprojdisk[i];
     rprojdiskapprox[i] = rprojdisk[i];
     phiderdiskapprox[i] = phiderdisk[i];
     rderdiskapprox[i] = rderdisk[i];
   }
  
   //now binary
   double krinv = settings_.kphi1() / settings_.kr() * pow(2, settings_.rinv_shift()),
          kphi0 = settings_.kphi1() * pow(2, settings_.phi0_shift()),
          kt = settings_.kz() / settings_.kr() * pow(2, settings_.t_shift()),
          kz0 = settings_.kz() * pow(2, settings_.z0_shift()),
          kphiproj = settings_.kphi1() * pow(2, settings_.SS_phiL_shift()),
          kphider = settings_.kphi1() / settings_.kr() * pow(2, settings_.SS_phiderL_shift()),
          kzproj = settings_.kz() * pow(2, settings_.PS_zL_shift()),
          kzder = settings_.kz() / settings_.kr() * pow(2, settings_.PS_zderL_shift()),
          kphiprojdisk = settings_.kphi1() * pow(2, settings_.SS_phiD_shift()),
          kphiderdisk = settings_.kphi1() / settings_.kr() * pow(2, settings_.SS_phiderD_shift()),
          krprojdisk = settings_.kr() * pow(2, settings_.PS_rD_shift()),
          krderdisk = settings_.kr() / settings_.kz() * pow(2, settings_.PS_rderD_shift());
  
   int irinv, iphi0, id0, it, iz0;
   int iphiproj[N_LAYER - 2], izproj[N_LAYER - 2], iphider[N_LAYER - 2], izder[N_LAYER - 2];
   int iphiprojdisk[N_DISK], irprojdisk[N_DISK], iphiderdisk[N_DISK], irderdisk[N_DISK];
  
   //store the binary results
   irinv = rinvapprox / krinv;
   iphi0 = phi0approx / kphi0;
   id0 = d0approx / settings_.kd0();
   it = tapprox / kt;
   iz0 = z0approx / kz0;
  
   bool success = true;
   if (std::abs(rinvapprox) > settings_.rinvcut()) {
     if (settings_.debugTracklet())
       edm::LogVerbatim("Tracklet") << "TrackletCalculator::LLL Seeding irinv too large: " << rinvapprox << "(" << irinv
                                    << ")";
     success = false;
   }
   if (std::abs(z0approx) > 1.8 * settings_.z0cut()) {
     if (settings_.debugTracklet())
       edm::LogVerbatim("Tracklet") << "Failed tracklet z0 cut " << z0approx << " in layer " << layer_;
     success = false;
   }
   if (std::abs(d0approx) > settings_.maxd0()) {
     if (settings_.debugTracklet())
       edm::LogVerbatim("Tracklet") << "Failed tracklet d0 cut " << d0approx;
     success = false;
   }
  
   if (!success)
     return false;
  
   double phicritapprox = phi0approx - asin(0.5 * settings_.rcrit() * rinvapprox);
   int phicrit = iphi0 - 2 * irinv;
  
   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 = (phicrit > iphicritmincut) && (phicrit < iphicritmaxcut);
  
   if (settings_.debugTracklet())
     if (keep && !keepapprox)
       edm::LogVerbatim("Tracklet") << "TrackletCalculatorDisplaced::LLLSeeding tracklet kept with exact phicrit cut "
                                       "but not approximate, phicritapprox: "
                                    << phicritapprox;
   if (settings_.usephicritapprox()) {
     if (!keepapprox)
       return false;
   } else {
     if (!keep)
       return false;
   }
  
   for (unsigned int i = 0; i < toR_.size(); ++i) {
     iphiproj[i] = phiprojapprox[i] / kphiproj;
     izproj[i] = zprojapprox[i] / kzproj;
  
     iphider[i] = phiderapprox[i] / kphider;
     izder[i] = zderapprox[i] / kzder;
  
     //check that z projection is in range
     if (izproj[i] < -(1 << (settings_.nzbitsstub(0) - 1)))
       continue;
     if (izproj[i] >= (1 << (settings_.nzbitsstub(0) - 1)))
       continue;
  
     //check that phi projection is in range
     if (iphiproj[i] >= (1 << settings_.nphibitsstub(N_LAYER - 1)) - 1)
       continue;
     if (iphiproj[i] <= 0)
       continue;
  
     //adjust number of bits for phi and z projection
     if (rproj_[i] < settings_.rPS2S()) {
       iphiproj[i] >>= (settings_.nphibitsstub(N_LAYER - 1) - settings_.nphibitsstub(0));
       if (iphiproj[i] >= (1 << settings_.nphibitsstub(0)) - 1)
         iphiproj[i] = (1 << settings_.nphibitsstub(0)) - 2;  //-2 not to hit atExtreme
     } else {
       izproj[i] >>= (settings_.nzbitsstub(0) - settings_.nzbitsstub(N_LAYER - 1));
     }
  
     if (rproj_[i] < settings_.rPS2S()) {
       if (iphider[i] < -(1 << (settings_.nbitsphiprojderL123() - 1))) {
         iphider[i] = -(1 << (settings_.nbitsphiprojderL123() - 1));
       }
       if (iphider[i] >= (1 << (settings_.nbitsphiprojderL123() - 1))) {
         iphider[i] = (1 << (settings_.nbitsphiprojderL123() - 1)) - 1;
       }
     } else {
       if (iphider[i] < -(1 << (settings_.nbitsphiprojderL456() - 1))) {
         iphider[i] = -(1 << (settings_.nbitsphiprojderL456() - 1));
       }
       if (iphider[i] >= (1 << (settings_.nbitsphiprojderL456() - 1))) {
         iphider[i] = (1 << (settings_.nbitsphiprojderL456() - 1)) - 1;
       }
     }
  
     layerprojs[i].init(settings_,
                        lproj_[i],
                        rproj_[i],
                        iphiproj[i],
                        izproj[i],
                        iphider[i],
                        izder[i],
                        phiproj[i],
                        zproj[i],
                        phider[i],
                        zder[i],
                        phiprojapprox[i],
                        zprojapprox[i],
                        phiderapprox[i],
                        zderapprox[i]);
   }
  
   if (std::abs(it * kt) > 1.0) {
     for (unsigned int i = 0; i < toZ_.size(); ++i) {
       iphiprojdisk[i] = phiprojdiskapprox[i] / kphiprojdisk;
       irprojdisk[i] = rprojdiskapprox[i] / krprojdisk;
  
       iphiderdisk[i] = phiderdiskapprox[i] / kphiderdisk;
       irderdisk[i] = rderdiskapprox[i] / krderdisk;
  
       //check phi projection in range
       if (iphiprojdisk[i] <= 0)
         continue;
       if (iphiprojdisk[i] >= (1 << settings_.nphibitsstub(0)) - 1)
         continue;
  
       //check r projection in range
       if (rprojdiskapprox[i] < settings_.rmindisk() || rprojdiskapprox[i] > settings_.rmaxdisk())
         continue;
  
       diskprojs[i].init(settings_,
                         i + 1,
                         rproj_[i],
                         iphiprojdisk[i],
                         irprojdisk[i],
                         iphiderdisk[i],
                         irderdisk[i],
                         phiprojdisk[i],
                         rprojdisk[i],
                         phiderdisk[i],
                         rderdisk[i],
                         phiprojdiskapprox[i],
                         rprojdiskapprox[i],
                         phiderdisk[i],
                         rderdisk[i]);
     }
   }
  
   if (settings_.writeMonitorData("TrackletPars")) {
     globals_->ofstream("trackletpars.txt")
         << "Trackpars " << layer_ << "   " << rinv << " " << rinvapprox << " " << rinvapprox << "   " << phi0 << " "
         << phi0approx << " " << phi0approx << "   " << t << " " << tapprox << " " << tapprox << "   " << z0 << " "
         << z0approx << " " << z0approx << endl;
   }
  
   Tracklet* tracklet = new Tracklet(settings_,
                                     innerStub,
                                     middleStub,
                                     outerStub,
                                     innerFPGAStub,
                                     middleFPGAStub,
                                     outerFPGAStub,
                                     rinv,
                                     phi0,
                                     d0,
                                     z0,
                                     t,
                                     rinvapprox,
                                     phi0approx,
                                     d0approx,
                                     z0approx,
                                     tapprox,
                                     irinv,
                                     iphi0,
                                     id0,
                                     iz0,
                                     it,
                                     layerprojs,
                                     diskprojs,
                                     false);
  
   if (settings_.debugTracklet()) {
     edm::LogVerbatim("Tracklet") << "TrackletCalculatorDisplaced " << getName()
                                  << " Found LLL tracklet in sector = " << 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);
  
   bool addL5 = false;
   bool addL6 = false;
   for (unsigned int j = 0; j < toR_.size(); j++) {
     bool added = false;
     if (settings_.debugTracklet())
       edm::LogVerbatim("Tracklet") << "adding layer projection " << j << "/" << toR_.size() << " " << lproj_[j];
     if (tracklet->validProj(lproj_[j])) {
       added = addLayerProj(tracklet, lproj_[j]);
       if (added && lproj_[j] == 5)
         addL5 = true;
       if (added && lproj_[j] == 6)
         addL6 = true;
     }
   }
  
   for (unsigned int j = 0; j < toZ_.size(); j++) {
     int disk = dproj_[j];
     if (disk == 0)
       continue;
     if (disk == 2 && addL5)
       continue;
     if (disk == 1 && addL6)
       continue;
     if (it < 0)
       disk = -disk;
     if (settings_.debugTracklet())
       edm::LogVerbatim("Tracklet") << "adding disk projection " << j << "/" << toZ_.size() << " " << disk;
     if (tracklet->validProjDisk(abs(disk))) {
       addDiskProj(tracklet, disk);
     }
   }
  
   return true;
 }