#include <PrimitiveConversion.h>

Public Member Functions
void	configure (const GeometryTranslator tp_geom, const SectorProcessorLUT pc_lut, int verbose, int endcap, int sector, int bx, int bxShiftCSC, int bxShiftRPC, int bxShiftGEM, int bxShiftME0, const std::vector< int > &zoneBoundaries, int zoneOverlap, bool duplicateTheta, bool fixZonePhi, bool useNewZones, bool fixME11Edges, bool bugME11Dupes)

void	convert_csc (int pc_sector, int pc_station, int pc_chamber, int pc_segment, const TriggerPrimitive &muon_primitive, EMTFHit &conv_hit) const

void	convert_csc_details (EMTFHit &conv_hit) const

void	convert_dt (int pc_sector, int pc_station, int pc_chamber, int pc_segment, const TriggerPrimitive &muon_primitive, EMTFHit &conv_hit) const

void	convert_gem (int pc_sector, int pc_station, int pc_chamber, int pc_segment, const TriggerPrimitive &muon_primitive, EMTFHit &conv_hit) const

void	convert_me0 (int pc_sector, int pc_station, int pc_chamber, int pc_segment, const TriggerPrimitive &muon_primitive, EMTFHit &conv_hit) const

void	convert_other_details (EMTFHit &conv_hit) const

void	convert_rpc (int pc_sector, int pc_station, int pc_chamber, int pc_segment, const TriggerPrimitive &muon_primitive, EMTFHit &conv_hit) const

void	convert_rpc_details (EMTFHit &conv_hit, bool isCPPF) const

int	get_bt_segment (const EMTFHit &conv_hit, int fw_station, int fw_cscid, int pc_segment) const

int	get_bt_station (const EMTFHit &conv_hit, int fw_station, int fw_cscid, int pc_segment) const

int	get_fs_segment (const EMTFHit &conv_hit, int fw_station, int fw_cscid, int pc_segment) const

int	get_fs_zone_code (const EMTFHit &conv_hit) const

int	get_phzvl (const EMTFHit &conv_hit, int zone_code) const

int	get_zone_code (const EMTFHit &conv_hit, int th) const

bool	is_valid_for_run2 (const EMTFHit &conv_hit) const

const SectorProcessorLUT &	pc_lut () const

void	process (const std::map< int, TriggerPrimitiveCollection > &selected_prim_map, EMTFHitCollection &conv_hits) const

Private Attributes
bool	bugME11Dupes_

int	bx_

int	bxShiftCSC_

int	bxShiftGEM_

int	bxShiftME0_

int	bxShiftRPC_

bool	duplicateTheta_

int	endcap_

bool	fixME11Edges_

bool	fixZonePhi_

const SectorProcessorLUT *	pc_lut_

int	sector_

const GeometryTranslator *	tp_geom_

bool	useNewZones_

int	verbose_

std::vector< int >	zoneBoundaries_

int	zoneOverlap_

Detailed Description

Definition at line 8 of file PrimitiveConversion.h.

Member Function Documentation

◆ configure()

void PrimitiveConversion::configure	(	const GeometryTranslator *	tp_geom,
		const SectorProcessorLUT *	pc_lut,
		int	verbose,
		int	endcap,
		int	sector,
		int	bx,
		int	bxShiftCSC,
		int	bxShiftRPC,
		int	bxShiftGEM,
		int	bxShiftME0,
		const std::vector< int > &	zoneBoundaries,
		int	zoneOverlap,
		bool	duplicateTheta,
		bool	fixZonePhi,
		bool	useNewZones,
		bool	fixME11Edges,
		bool	bugME11Dupes
	)

Definition at line 7 of file PrimitiveConversion.cc.

                                                        {
   emtf_assert(tp_geom != nullptr);
   emtf_assert(pc_lut != nullptr);
  
   tp_geom_ = tp_geom;
   pc_lut_ = pc_lut;
  
   verbose_ = verbose;
   endcap_ = endcap;  // 1 for ME+, 2 for ME-
   sector_ = sector;
   bx_ = bx;
  
   bxShiftCSC_ = bxShiftCSC;
   bxShiftRPC_ = bxShiftRPC;
   bxShiftGEM_ = bxShiftGEM;
   bxShiftME0_ = bxShiftME0;
  
   zoneBoundaries_ = zoneBoundaries;
   zoneOverlap_ = zoneOverlap;
   duplicateTheta_ = duplicateTheta;
   fixZonePhi_ = fixZonePhi;
   useNewZones_ = useNewZones;
   fixME11Edges_ = fixME11Edges;
   bugME11Dupes_ = bugME11Dupes;
 }

References bugME11Dupes_, l1GtPatternGenerator_cfi::bx, bx_, bxShiftCSC_, bxShiftGEM_, bxShiftME0_, bxShiftRPC_, duplicateTheta_, emtf_assert, makeMuonMisalignmentScenario::endcap, endcap_, fixME11Edges_, fixZonePhi_, pc_lut(), pc_lut_, sector_, tp_geom_, useNewZones_, verbose, verbose_, zoneBoundaries_, and zoneOverlap_.

Referenced by SectorProcessor::process_single_bx().

◆ convert_csc()

void PrimitiveConversion::convert_csc	(	int	pc_sector,
		int	pc_station,
		int	pc_chamber,
		int	pc_segment,
		const TriggerPrimitive &	muon_primitive,
		EMTFHit &	conv_hit
	)		const

Definition at line 89 of file PrimitiveConversion.cc.

                                                                {
   const CSCDetId& tp_detId = muon_primitive.detId<CSCDetId>();
   const CSCData& tp_data = muon_primitive.getCSCData();
  
   int tp_endcap = tp_detId.endcap();
   int tp_sector = tp_detId.triggerSector();
   int tp_station = tp_detId.station();
   int tp_ring = tp_detId.ring();
   int tp_chamber = tp_detId.chamber();
  
   int tp_bx = tp_data.bx;
   int tp_csc_ID = tp_data.cscID;
  
   // station 1 --> subsector 1 or 2
   // station 2,3,4 --> subsector 0
   int tp_subsector = (tp_station != 1) ? 0 : ((tp_chamber % 6 > 2) ? 1 : 2);
  
   const bool is_neighbor = (pc_station == 5);
  
   int csc_nID = tp_csc_ID;  // modify csc_ID if coming from neighbor sector
   if (is_neighbor) {
     // station 1 has 3 neighbor chambers: 13,14,15 in rings 1,2,3
     // (where are chambers 10,11,12 in station 1? they were used to label ME1/1a, but not anymore)
     // station 2,3,4 have 2 neighbor chambers: 10,11 in rings 1,2
     csc_nID = (pc_chamber < 3) ? (pc_chamber + 12) : (((pc_chamber - 1) % 2) + 9);
     csc_nID += 1;
  
     if (tp_station == 1) {  // neighbor ME1
       emtf_assert(tp_subsector == 2);
     }
   }
  
   // Set properties
   conv_hit.SetCSCDetId(tp_detId);
  
   conv_hit.set_bx(tp_bx + bxShiftCSC_);
   conv_hit.set_subsystem(L1TMuon::kCSC);
   conv_hit.set_endcap((tp_endcap == 2) ? -1 : tp_endcap);
   conv_hit.set_station(tp_station);
   conv_hit.set_ring(tp_ring);
   //conv_hit.set_roll          ( tp_roll );
   conv_hit.set_chamber(tp_chamber);
   conv_hit.set_sector(tp_sector);
   conv_hit.set_subsector(tp_subsector);
   conv_hit.set_csc_ID(tp_csc_ID);
   conv_hit.set_csc_nID(csc_nID);
   conv_hit.set_track_num(tp_data.trknmb);
   conv_hit.set_sync_err(tp_data.syncErr);
   //conv_hit.set_sector_RPC    ( tp_sector );
   //conv_hit.set_subsector_RPC ( tp_subsector );
  
   conv_hit.set_pc_sector(pc_sector);
   conv_hit.set_pc_station(pc_station);
   conv_hit.set_pc_chamber(pc_chamber);
   conv_hit.set_pc_segment(pc_segment);
  
   conv_hit.set_valid(tp_data.valid);
   conv_hit.set_strip(tp_data.strip);
   //conv_hit.set_strip_low     ( tp_data.strip_low );
   //conv_hit.set_strip_hi      ( tp_data.strip_hi );
   conv_hit.set_wire(tp_data.keywire);
   conv_hit.set_quality(tp_data.quality);
   conv_hit.set_pattern(tp_data.pattern);
   conv_hit.set_bend(tp_data.bend);
   conv_hit.set_time(0.);  // No fine resolution timing
   conv_hit.set_alct_quality(tp_data.alct_quality);
   conv_hit.set_clct_quality(tp_data.clct_quality);
  
   conv_hit.set_neighbor(is_neighbor);
   conv_hit.set_sector_idx((endcap_ == 1) ? sector_ - 1 : sector_ + 5);
  
   convert_csc_details(conv_hit);
  
   // Add coordinates from fullsim
   {
     const GlobalPoint& gp = tp_geom_->getGlobalPoint(muon_primitive);
     double glob_phi = emtf::rad_to_deg(gp.phi().value());
     double glob_theta = emtf::rad_to_deg(gp.theta());
     double glob_eta = gp.eta();
     double glob_rho = gp.perp();
     double glob_z = gp.z();
  
     conv_hit.set_phi_sim(glob_phi);
     conv_hit.set_theta_sim(glob_theta);
     conv_hit.set_eta_sim(glob_eta);
     conv_hit.set_rho_sim(glob_rho);
     conv_hit.set_z_sim(glob_z);
   }
 }

Referenced by process().

◆ convert_csc_details()

void PrimitiveConversion::convert_csc_details ( EMTFHit & conv_hit ) const

Definition at line 184 of file PrimitiveConversion.cc.

                                                                      {
   const bool is_neighbor = conv_hit.Neighbor();
  
   // Defined as in firmware
   // endcap : 0-1 for ME+,ME-
   // sector : 0-5
   // station: 0-4 for st1 sub1 or st1 sub2 from neighbor, st1 sub2, st2, st3, st4
   // cscid  : 0-14 (excluding 11), including neighbors
   const int fw_endcap = (endcap_ - 1);
   const int fw_sector = (sector_ - 1);
   const int fw_station =
       (conv_hit.Station() == 1) ? (is_neighbor ? 0 : (conv_hit.Subsector() - 1)) : conv_hit.Station();
   const int fw_cscid = (conv_hit.CSC_nID() - 1);
   const int fw_strip = conv_hit.Strip();  // it is half-strip, despite the name
   const int fw_wire = conv_hit.Wire();    // it is wiregroup, despite the name
  
   // Primitive converter unit
   // station: 0-5 for st1 sub1, st1 sub2, st2, st3, st4, neigh all st*
   // chamber: 0-8
   const int pc_station = conv_hit.PC_station();
   const int pc_chamber = conv_hit.PC_chamber();
   const int pc_segment = conv_hit.PC_segment();
  
   const bool is_me11a = (conv_hit.Station() == 1 && conv_hit.Ring() == 4);
   const bool is_me11b = (conv_hit.Station() == 1 && conv_hit.Ring() == 1);
   const bool is_me13 = (conv_hit.Station() == 1 && conv_hit.Ring() == 3);
  
   // Is this chamber mounted in reverse direction?
   // (i.e., phi vs. strip number is reversed)
   bool ph_reverse = false;
   if ((fw_endcap == 0 && fw_station >= 3) || (fw_endcap == 1 && fw_station < 3))  // ME+3, ME+4, ME-1, ME-2
     ph_reverse = true;
  
   // Chamber coverage if phi_reverse = true
   int ph_coverage = 0;  // Offset for coordinate conversion
   if (ph_reverse) {
     if (fw_station <= 1 && ((fw_cscid >= 6 && fw_cscid <= 8) || fw_cscid == 14))  // ME1/3
       ph_coverage = 15;
     else if (fw_station >= 2 && (fw_cscid <= 2 || fw_cscid == 9))  // ME2,3,4/1
       ph_coverage = 40;
     else  // all others
       ph_coverage = 20;
   }
  
   // Is this 10-deg or 20-deg chamber?
   bool is_10degree = false;
   if ((fw_station <= 1) ||                                                       // ME1
       (fw_station >= 2 && ((fw_cscid >= 3 && fw_cscid <= 8) || fw_cscid == 10))  // ME2,3,4/2
   ) {
     is_10degree = true;
   }
  
   // LUT index
   // There are 54 CSC chambers including the neighbors in a sector, but 61 LUT indices
   // This comes from dividing the 6 chambers + 1 neighbor in ME1/1 into ME1/1a and ME1/1b
   int pc_lut_id = pc_chamber;
   if (pc_station == 0) {  // ME1 sub 1: 0 - 11
     pc_lut_id = is_me11a ? pc_lut_id + 9 : pc_lut_id;
   } else if (pc_station == 1) {  // ME1 sub 2: 16 - 27
     pc_lut_id += 16;
     pc_lut_id = is_me11a ? pc_lut_id + 9 : pc_lut_id;
   } else if (pc_station == 2) {  // ME2: 28 - 36
     pc_lut_id += 28;
   } else if (pc_station == 3) {  // ME3: 39 - 47
     pc_lut_id += 39;
   } else if (pc_station == 4) {  // ME4 : 50 - 58
     pc_lut_id += 50;
   } else if (pc_station == 5 && pc_chamber < 3) {  // neighbor ME1: 12 - 15
     pc_lut_id = is_me11a ? pc_lut_id + 15 : pc_lut_id + 12;
   } else if (pc_station == 5 && pc_chamber < 5) {  // neighbor ME2: 37 - 38
     pc_lut_id += 28 + 9 - 3;
   } else if (pc_station == 5 && pc_chamber < 7) {  // neighbor ME3: 48 - 49
     pc_lut_id += 39 + 9 - 5;
   } else if (pc_station == 5 && pc_chamber < 9) {  // neighbor ME4: 59 - 60
     pc_lut_id += 50 + 9 - 7;
   }
   emtf_assert(pc_lut_id < 61);
  
   if (verbose_ > 1) {  // debug
     std::cout << "pc_station: " << pc_station << " pc_chamber: " << pc_chamber << " fw_station: " << fw_station
               << " fw_cscid: " << fw_cscid << " lut_id: " << pc_lut_id
               << " ph_init: " << pc_lut().get_ph_init(fw_endcap, fw_sector, pc_lut_id)
               << " ph_disp: " << pc_lut().get_ph_disp(fw_endcap, fw_sector, pc_lut_id)
               << " th_init: " << pc_lut().get_th_init(fw_endcap, fw_sector, pc_lut_id)
               << " th_disp: " << pc_lut().get_th_disp(fw_endcap, fw_sector, pc_lut_id)
               << " ph_init_hard: " << pc_lut().get_ph_init_hard(fw_station, fw_cscid) << std::endl;
   }
  
   // ___________________________________________________________________________
   // phi conversion
  
   // Convert half-strip into 1/8-strip
   int eighth_strip = 0;
  
   // Apply phi correction from CLCT pattern number (from src/SectorProcessorLUT.cc)
   int clct_pat_corr = pc_lut().get_ph_patt_corr(conv_hit.Pattern());
   int clct_pat_corr_sign = (pc_lut().get_ph_patt_corr_sign(conv_hit.Pattern()) == 0) ? 1 : -1;
  
   // At strip number 0, protect against negative correction
   bool bugStrip0BeforeFW48200 = false;
   if (bugStrip0BeforeFW48200 == false && fw_strip == 0 && clct_pat_corr_sign == -1)
     clct_pat_corr = 0;
  
   if (is_10degree) {
     eighth_strip = fw_strip << 2;  // full precision, uses only 2 bits of pattern correction
     eighth_strip += clct_pat_corr_sign * (clct_pat_corr >> 1);
   } else {
     eighth_strip = fw_strip << 3;  // multiply by 2, uses all 3 bits of pattern correction
     eighth_strip += clct_pat_corr_sign * (clct_pat_corr >> 0);
   }
   emtf_assert(bugStrip0BeforeFW48200 == true || eighth_strip >= 0);
  
   // Multiplicative factor for eighth_strip
   // +----------------------------+-------------+------------------+
   // | Chamber type               | Strip angle | Mult factor      |
   // |                            | (deg)       |                  |
   // +----------------------------+-------------+------------------+
   // | ME1/2, ME2/2, ME3/2, ME4/2 | 0.1333      | 1/2 (remove LSB) |
   // | ME2/1, ME3/1, ME4/1        | 0.2666      | 1 (no op)        |
   // | ME1/1a                     | 0.2222      | 0.8335           |
   // | ME1/1b                     | 0.1695      | 0.636            |
   // | ME1/3                      | 0.1233      | 0.4625           |
   // +----------------------------+-------------+------------------+
  
   int factor = 1024;
   if (is_me11a)
     factor = 1707;  // ME1/1a
   else if (is_me11b)
     factor = 1301;  // ME1/1b
   else if (is_me13)
     factor = 947;  // ME1/3
  
   // ph_tmp is full-precision phi, but local to chamber (counted from strip 0)
   // full phi precision: ( 1/60) deg (1/8-strip)
   // zone phi precision: (32/60) deg (4-strip, 32 times coarser than full phi precision)
   int ph_tmp = (eighth_strip * factor) >> 10;
   int ph_tmp_sign = (ph_reverse == 0) ? 1 : -1;
  
   int fph = pc_lut().get_ph_init(fw_endcap, fw_sector, pc_lut_id);
   fph = fph + ph_tmp_sign * ph_tmp;
  
   int ph_hit = pc_lut().get_ph_disp(fw_endcap, fw_sector, pc_lut_id);
   ph_hit = (ph_hit >> 1) + ph_tmp_sign * (ph_tmp >> 5) + ph_coverage;
  
   // Full phi +16 to put the rounded value into the middle of error range
   // Divide full phi by 32, subtract chamber start
   int ph_hit_fixed = -1 * pc_lut().get_ph_init_hard(fw_station, fw_cscid);
   ph_hit_fixed = ph_hit_fixed + ((fph + (1 << 4)) >> 5);
  
   if (fixZonePhi_)
     ph_hit = ph_hit_fixed;
  
   // Zone phi
   int zone_hit = pc_lut().get_ph_zone_offset(pc_station, pc_chamber);
   zone_hit += ph_hit;
  
   int zone_hit_fixed = pc_lut().get_ph_init_hard(fw_station, fw_cscid);
   zone_hit_fixed += ph_hit_fixed;
   // Since ph_hit_fixed = ((fph + (1<<4)) >> 5) - pc_lut().get_ph_init_hard(), the following is equivalent:
   //zone_hit_fixed = ((fph + (1<<4)) >> 5);
  
   if (fixZonePhi_)
     zone_hit = zone_hit_fixed;
  
   emtf_assert(0 <= fph && fph < 5000);
   emtf_assert(0 <= zone_hit && zone_hit < 192);
  
   // ___________________________________________________________________________
   // theta conversion
  
   // th_tmp is theta local to chamber
   int pc_wire_id = (fw_wire & 0x7f);  // 7-bit
   int th_tmp = pc_lut().get_th_lut(fw_endcap, fw_sector, pc_lut_id, pc_wire_id);
  
   // For ME1/1 with tilted wires, add theta correction as a function of (wire,strip) index
   if (!fixME11Edges_ && (is_me11a || is_me11b)) {
     int pc_wire_strip_id =
         (((fw_wire >> 4) & 0x3) << 5) | ((eighth_strip >> 4) & 0x1f);  // 2-bit from wire, 5-bit from 2-strip
  
     // Only affect runs before FW changeset 47114 is applied
     // e.g. Run 281707 and earlier
     if (bugME11Dupes_) {
       bool bugME11DupesBeforeFW47114 = false;
       if (bugME11DupesBeforeFW47114) {
         if (pc_segment == 1) {
           pc_wire_strip_id = (((fw_wire >> 4) & 0x3) << 5) | (0);  // 2-bit from wire, 5-bit from 2-strip
         }
       }
     }
  
     int th_corr = pc_lut().get_th_corr_lut(fw_endcap, fw_sector, pc_lut_id, pc_wire_strip_id);
     int th_corr_sign = (ph_reverse == 0) ? 1 : -1;
  
     th_tmp = th_tmp + th_corr_sign * th_corr;
  
     // Check that correction did not make invalid value outside chamber coverage
     const int th_negative = 50;
     const int th_coverage = 45;
     if (th_tmp > th_negative || th_tmp < 0 || fw_wire == 0)
       th_tmp = 0;  // limit at the bottom
     if (th_tmp > th_coverage)
       th_tmp = th_coverage;  // limit at the top
  
   } else if (fixME11Edges_ && (is_me11a || is_me11b)) {
     int pc_wire_strip_id =
         (((fw_wire >> 4) & 0x3) << 5) | ((eighth_strip >> 4) & 0x1f);  // 2-bit from wire, 5-bit from 2-strip
     if (is_me11a)
       pc_wire_strip_id = (((fw_wire >> 4) & 0x3) << 5) | ((((eighth_strip * 341) >> 8) >> 4) &
                                                           0x1f);  // correct for ME1/1a strip number (341/256 =~ 1.333)
     int th_corr = pc_lut().get_th_corr_lut(fw_endcap, fw_sector, pc_lut_id, pc_wire_strip_id);
  
     th_tmp = th_tmp + th_corr;
  
     // Check that correction did not make invalid value outside chamber coverage
     const int th_coverage = 46;  // max coverage for front chamber is 47, max coverage for rear chamber is 45
     if (fw_wire == 0)
       th_tmp = 0;  // limit at the bottom
     if (th_tmp > th_coverage)
       th_tmp = th_coverage;  // limit at the top
   }
  
   // theta precision: (36.5/128) deg
   // theta starts at 8.5 deg: {1, 127} <--> {8.785, 44.715}
   int th = pc_lut().get_th_init(fw_endcap, fw_sector, pc_lut_id);
   th = th + th_tmp;
  
   emtf_assert(0 <= th && th < 128);
   th = (th == 0) ? 1 : th;  // protect against invalid value
  
   // ___________________________________________________________________________
   // Zone codes and other segment IDs
  
   //int zone_hit     = ((fph + (1<<4)) >> 5);
   int zone_code = get_zone_code(conv_hit, th);
   //int phzvl        = get_phzvl(conv_hit, zone_code);
  
   int fs_zone_code = get_fs_zone_code(conv_hit);
   int fs_segment = get_fs_segment(conv_hit, fw_station, fw_cscid, pc_segment);
  
   int bt_station = get_bt_station(conv_hit, fw_station, fw_cscid, pc_segment);
   int bt_segment = get_bt_segment(conv_hit, fw_station, fw_cscid, pc_segment);
  
   // ___________________________________________________________________________
   // Output
  
   conv_hit.set_phi_fp(fph);   // Full-precision integer phi
   conv_hit.set_theta_fp(th);  // Full-precision integer theta
   //conv_hit.set_phzvl      ( phzvl );      // Local zone word: (1*low) + (2*mid) + (4*low) - used in FW debugging
   //conv_hit.set_ph_hit     ( ph_hit );     // Intermediate quantity in phi calculation - used in FW debugging
   conv_hit.set_zone_hit(zone_hit);    // Phi value for building patterns (0.53333 deg precision)
   conv_hit.set_zone_code(zone_code);  // Full zone word: 1*(zone 0) + 2*(zone 1) + 4*(zone 2) + 8*(zone 3)
  
   conv_hit.set_fs_segment(fs_segment);      // Segment number used in primitive matching
   conv_hit.set_fs_zone_code(fs_zone_code);  // Zone word used in primitive matching
  
   conv_hit.set_bt_station(bt_station);
   conv_hit.set_bt_segment(bt_segment);
  
   conv_hit.set_phi_loc(emtf::calc_phi_loc_deg(fph));
   conv_hit.set_phi_glob(emtf::calc_phi_glob_deg(conv_hit.Phi_loc(), conv_hit.PC_sector()));
   conv_hit.set_theta(emtf::calc_theta_deg_from_int(th));
   conv_hit.set_eta(emtf::calc_eta_from_theta_deg(conv_hit.Theta(), conv_hit.Endcap()));
 }

Referenced by convert_csc().

◆ convert_dt()

void PrimitiveConversion::convert_dt	(	int	pc_sector,
		int	pc_station,
		int	pc_chamber,
		int	pc_segment,
		const TriggerPrimitive &	muon_primitive,
		EMTFHit &	conv_hit
	)		const

Definition at line 998 of file PrimitiveConversion.cc.

                                                               {
   const DTChamberId& tp_detId = muon_primitive.detId<DTChamberId>();
   const DTData& tp_data = muon_primitive.getDTData();
  
   int tp_wheel = tp_detId.wheel();
   int tp_station = tp_detId.station();
   int tp_sector = tp_detId.sector();  // sectors are 1-12, starting at phi=0 and increasing with phi
  
   // In station 4, where the top and bottom setcors are made of two chambers,
   // two additional sector numbers are used, 13 (after sector 4, top)
   // and 14 (after sector 10, bottom).
   if (tp_station == 4) {
     if (tp_sector == 13)
       tp_sector = 4;
     else if (tp_sector == 14)
       tp_sector = 10;
   }
  
   int tp_bx = tp_data.bx;
   int tp_phi = tp_data.radialAngle;
   int tp_phiB = tp_data.bendingAngle;
  
   // Mimic 10 deg CSC chamber. I use tp_station = 2, tp_ring = 2
   // when calling get_trigger_sector() and get_trigger_csc_ID()
   int tp_chamber =
       tp_sector * 3 - 1;  // DT chambers are 30 deg. Multiply sector number by 3 to mimic 10 deg CSC chamber number
   int tp_endcap = (tp_wheel > 0) ? +1 : ((tp_wheel < 0) ? 2 : 0);
   int csc_tp_sector = emtf::get_trigger_sector(2, 2, tp_chamber);
   int tp_csc_ID = emtf::get_trigger_csc_ID(2, 2, tp_chamber);
   int tp_subsector = 0;
  
   const bool is_neighbor = (pc_chamber >= 8);
  
   int csc_nID = tp_csc_ID;  // modify csc_ID if coming from neighbor sector
   if (is_neighbor) {
     // station 1 has 3 neighbor chambers: 13,14,15 in rings 1,2,3
     // (where are chambers 10,11,12 in station 1? they were used to label ME1/1a, but not anymore)
     // station 2,3,4 have 2 neighbor chambers: 10,11 in rings 1,2
     csc_nID = 10;
   }
  
   // Set properties
   conv_hit.SetDTDetId(tp_detId);
  
   conv_hit.set_bx(tp_bx);
   conv_hit.set_subsystem(L1TMuon::kDT);
   conv_hit.set_endcap((tp_endcap == 2) ? -1 : tp_endcap);
   conv_hit.set_station(tp_station);
   conv_hit.set_ring(1);         // set to ring 1?
   conv_hit.set_roll(tp_wheel);  // used as wheel
   conv_hit.set_chamber(tp_chamber);
   conv_hit.set_sector(csc_tp_sector);
   conv_hit.set_subsector(tp_subsector);
   conv_hit.set_csc_ID(tp_csc_ID);
   conv_hit.set_csc_nID(csc_nID);
   conv_hit.set_track_num(tp_data.segment_number);
   conv_hit.set_sync_err(tp_data.RpcBit);  // hacked to store rpc bit
   //conv_hit.set_sector_RPC    ( tp_sector );
   //conv_hit.set_subsector_RPC ( tp_subsector );
  
   conv_hit.set_pc_sector(pc_sector);
   conv_hit.set_pc_station(pc_station);
   conv_hit.set_pc_chamber(pc_chamber);
   conv_hit.set_pc_segment(pc_segment);
  
   conv_hit.set_valid(true);
   conv_hit.set_strip(tp_phi);
   //conv_hit.set_strip_low     ( tp_data.strip_low );
   //conv_hit.set_strip_hi      ( tp_data.strip_hi );
   conv_hit.set_wire(tp_data.theta_bti_group);
   conv_hit.set_quality(tp_data.qualityCode);
   conv_hit.set_pattern(0);  // arbitrary
   conv_hit.set_bend(tp_phiB);
   conv_hit.set_time(0.);  // No fine resolution timing
   //conv_hit.set_alct_quality  ( tp_data.alct_quality );
   //conv_hit.set_clct_quality  ( tp_data.clct_quality );
  
   conv_hit.set_neighbor(is_neighbor);
   conv_hit.set_sector_idx((endcap_ == 1) ? sector_ - 1 : sector_ + 5);
  
   // Get coordinates from fullsim since LUTs do not exist yet
   bool use_fullsim_coords = true;
   if (use_fullsim_coords) {
     const GlobalPoint& gp = tp_geom_->getGlobalPoint(muon_primitive);
     double glob_phi = emtf::rad_to_deg(gp.phi().value());
     double glob_theta = emtf::rad_to_deg(gp.theta());
     double glob_eta = gp.eta();
     double glob_rho = gp.perp();
     double glob_z = gp.z();
  
     // Use the CSC precision (unconfirmed!)
     int fph = emtf::calc_phi_loc_int(glob_phi, conv_hit.PC_sector());
     int th = emtf::calc_theta_int(glob_theta, conv_hit.Endcap());
  
     bool fix_dt_phi_edge = true;
     if (fix_dt_phi_edge) {
       // The DT chamber edges are not always aligned at 0,30,60,etc. The local
       // phi 0 is set to the CSC chamber edge minus 22 deg. But it is possible
       // for the DT neighbor chamber to go as far as the CSC chamber edge minus
       // 32 deg.
       double loc = emtf::calc_phi_loc_deg_from_glob(glob_phi, conv_hit.PC_sector());
       if ((loc + 22.) < 0. && (loc + 32.) > 0.)
         fph = 0;
       else if ((loc + 360. + 22.) < 0. && (loc + 360. + 32.) > 0.)
         fph = 0;
     }
  
     emtf_assert(0 <= fph && fph < 5400);
     emtf_assert(0 <= th && th < 180);  // Note: eta = 0.73 -> theta_int = 150
     th = (th == 0) ? 1 : th;           // protect against invalid value
  
     // _________________________________________________________________________
     // Output
  
     conv_hit.set_phi_sim(glob_phi);
     conv_hit.set_theta_sim(glob_theta);
     conv_hit.set_eta_sim(glob_eta);
     conv_hit.set_rho_sim(glob_rho);
     conv_hit.set_z_sim(glob_z);
  
     conv_hit.set_phi_fp(fph);   // Full-precision integer phi
     conv_hit.set_theta_fp(th);  // Full-precision integer theta
   }
  
   convert_other_details(conv_hit);
 }

Referenced by process().

◆ convert_gem()

void PrimitiveConversion::convert_gem	(	int	pc_sector,
		int	pc_station,
		int	pc_chamber,
		int	pc_segment,
		const TriggerPrimitive &	muon_primitive,
		EMTFHit &	conv_hit
	)		const

Definition at line 701 of file PrimitiveConversion.cc.

                                                                {
   const GEMDetId& tp_detId = muon_primitive.detId<GEMDetId>();
   const GEMData& tp_data = muon_primitive.getGEMData();
  
   int tp_region = tp_detId.region();  // 0 for Barrel, +/-1 for +/- Endcap
   int tp_endcap = (tp_region == -1) ? 2 : tp_region;
   int tp_station = tp_detId.station();
   int tp_ring = tp_detId.ring();
   int tp_roll = tp_detId.roll();
   //int tp_layer     = tp_detId.layer();
   int tp_chamber = tp_detId.chamber();
  
   int tp_bx = tp_data.bx;
   int tp_pad = ((tp_data.pad_low + tp_data.pad_hi) / 2);
  
   int tp_sector = emtf::get_trigger_sector(tp_ring, tp_station, tp_chamber);
   int tp_csc_ID = emtf::get_trigger_csc_ID(tp_ring, tp_station, tp_chamber);
  
   // station 1 --> subsector 1 or 2
   // station 2,3,4 --> subsector 0
   int tp_subsector = (tp_station != 1) ? 0 : ((tp_chamber % 6 > 2) ? 1 : 2);
  
   const bool is_neighbor = (pc_chamber == 12 || pc_chamber == 13);
  
   int csc_nID = tp_csc_ID;  // modify csc_ID if coming from neighbor sector
   if (is_neighbor) {
     // station 1 has 3 neighbor chambers: 13,14,15 in rings 1,2,3
     // (where are chambers 10,11,12 in station 1? they were used to label ME1/1a, but not anymore)
     // station 2,3,4 have 2 neighbor chambers: 10,11 in rings 1,2
     if (tp_station == 1) {
       csc_nID = 13;
     } else {
       csc_nID = 10;
     }
   }
  
   // Use cluster width as 'quality'
   int tp_quality = (tp_data.pad_hi - tp_data.pad_low + 1);
  
   // Set properties
   conv_hit.SetGEMDetId(tp_detId);
  
   conv_hit.set_bx(tp_bx + bxShiftGEM_);
   conv_hit.set_subsystem(L1TMuon::kGEM);
   conv_hit.set_endcap((tp_endcap == 2) ? -1 : tp_endcap);
   conv_hit.set_station(tp_station);
   conv_hit.set_ring(tp_ring);
   conv_hit.set_roll(tp_roll);
   conv_hit.set_chamber(tp_chamber);
   conv_hit.set_sector(tp_sector);
   conv_hit.set_subsector(tp_subsector);
   conv_hit.set_csc_ID(tp_csc_ID);
   conv_hit.set_csc_nID(csc_nID);
   //conv_hit.set_track_num     ( tp_data.trknmb );
   //conv_hit.set_sync_err      ( tp_data.syncErr );
   //conv_hit.set_sector_RPC    ( tp_sector );
   //conv_hit.set_subsector_RPC ( tp_subsector );
  
   conv_hit.set_pc_sector(pc_sector);
   conv_hit.set_pc_station(pc_station);
   conv_hit.set_pc_chamber(pc_chamber);
   conv_hit.set_pc_segment(pc_segment);
  
   conv_hit.set_valid(true);
   conv_hit.set_strip(tp_pad);
   conv_hit.set_strip_low(tp_data.pad_low);
   conv_hit.set_strip_hi(tp_data.pad_hi);
   //conv_hit.set_wire          ( tp_data.keywire );
   conv_hit.set_quality(tp_quality);
   conv_hit.set_pattern(0);  // arbitrary
   //conv_hit.set_bend          ( tp_data.bend );
   conv_hit.set_time(0.);  // No fine resolution timing
   //conv_hit.set_alct_quality  ( tp_data.alct_quality );
   //conv_hit.set_clct_quality  ( tp_data.clct_quality );
  
   conv_hit.set_neighbor(is_neighbor);
   conv_hit.set_sector_idx((endcap_ == 1) ? sector_ - 1 : sector_ + 5);
  
   // Get coordinates from fullsim since LUTs do not exist yet
   bool use_fullsim_coords = true;
   if (use_fullsim_coords) {
     const GlobalPoint& gp = tp_geom_->getGlobalPoint(muon_primitive);
     double glob_phi = emtf::rad_to_deg(gp.phi().value());
     double glob_theta = emtf::rad_to_deg(gp.theta());
     double glob_eta = gp.eta();
     double glob_rho = gp.perp();
     double glob_z = gp.z();
  
     // Use the CSC precision (unconfirmed!)
     int fph = emtf::calc_phi_loc_int(glob_phi, conv_hit.PC_sector());
     int th = emtf::calc_theta_int(glob_theta, conv_hit.Endcap());
  
     emtf_assert(0 <= fph && fph < 5000);
     emtf_assert(0 <= th && th < 128);
     th = (th == 0) ? 1 : th;  // protect against invalid value
  
     // _________________________________________________________________________
     // Output
  
     conv_hit.set_phi_sim(glob_phi);
     conv_hit.set_theta_sim(glob_theta);
     conv_hit.set_eta_sim(glob_eta);
     conv_hit.set_rho_sim(glob_rho);
     conv_hit.set_z_sim(glob_z);
  
     conv_hit.set_phi_fp(fph);   // Full-precision integer phi
     conv_hit.set_theta_fp(th);  // Full-precision integer theta
   }
  
   convert_other_details(conv_hit);
 }

Referenced by process().

◆ convert_me0()

void PrimitiveConversion::convert_me0	(	int	pc_sector,
		int	pc_station,
		int	pc_chamber,
		int	pc_segment,
		const TriggerPrimitive &	muon_primitive,
		EMTFHit &	conv_hit
	)		const

Definition at line 878 of file PrimitiveConversion.cc.

                                                                {
   const ME0DetId& tp_detId = muon_primitive.detId<ME0DetId>();
   const ME0Data& tp_data = muon_primitive.getME0Data();
  
   int tp_region = tp_detId.region();  // 0 for Barrel, +/-1 for +/- Endcap
   int tp_endcap = (tp_region == -1) ? 2 : tp_region;
   int tp_station = tp_detId.station();
   int tp_ring = 1;  // tp_detId.ring() does not exist
   //int tp_roll      = tp_detId.roll();
   //int tp_layer     = tp_detId.layer();
   int tp_chamber = tp_detId.chamber();
  
   int tp_bx = tp_data.bx;
   int tp_pad = tp_data.phiposition;
   int tp_partition = tp_data.partition;
  
   // The ME0 geometry is similar to ME2/1, so I use tp_station = 2, tp_ring = 1
   // when calling get_trigger_sector() and get_trigger_csc_ID()
   int tp_sector = emtf::get_trigger_sector(1, 2, tp_chamber);
   int tp_csc_ID = emtf::get_trigger_csc_ID(1, 2, tp_chamber);
   int tp_subsector = 0;
  
   const bool is_neighbor = (pc_chamber == 14);
  
   int csc_nID = tp_csc_ID;  // modify csc_ID if coming from neighbor sector
   if (is_neighbor) {
     // station 1 has 3 neighbor chambers: 13,14,15 in rings 1,2,3
     // (where are chambers 10,11,12 in station 1? they were used to label ME1/1a, but not anymore)
     // station 2,3,4 have 2 neighbor chambers: 10,11 in rings 1,2
     csc_nID = 10;
   }
  
   // Set properties
   conv_hit.SetME0DetId(tp_detId);
  
   conv_hit.set_bx(tp_bx + bxShiftME0_);
   conv_hit.set_subsystem(L1TMuon::kME0);
   conv_hit.set_endcap((tp_endcap == 2) ? -1 : tp_endcap);
   conv_hit.set_station(tp_station);
   conv_hit.set_ring(tp_ring);
   conv_hit.set_roll(tp_partition);
   conv_hit.set_chamber(tp_chamber);
   conv_hit.set_sector(tp_sector);
   conv_hit.set_subsector(tp_subsector);
   conv_hit.set_csc_ID(tp_csc_ID);
   conv_hit.set_csc_nID(csc_nID);
   //conv_hit.set_track_num     ( tp_data.trknmb );
   //conv_hit.set_sync_err      ( tp_data.syncErr );
   //conv_hit.set_sector_RPC    ( tp_sector );
   //conv_hit.set_subsector_RPC ( tp_subsector );
  
   conv_hit.set_pc_sector(pc_sector);
   conv_hit.set_pc_station(pc_station);
   conv_hit.set_pc_chamber(pc_chamber);
   conv_hit.set_pc_segment(pc_segment);
  
   conv_hit.set_valid(true);
   conv_hit.set_strip(tp_pad);
   //conv_hit.set_strip_low     ( tp_strip );
   //conv_hit.set_strip_hi      ( tp_strip );
   //conv_hit.set_wire          ( tp_data.keywire );
   conv_hit.set_quality(tp_data.quality);
   conv_hit.set_pattern(0);  // arbitrary
   conv_hit.set_bend(tp_data.deltaphi * (tp_data.bend == 0 ? 1 : -1));
   conv_hit.set_time(0.);  // No fine resolution timing
   //conv_hit.set_alct_quality  ( tp_data.alct_quality );
   //conv_hit.set_clct_quality  ( tp_data.clct_quality );
  
   conv_hit.set_neighbor(is_neighbor);
   conv_hit.set_sector_idx((endcap_ == 1) ? sector_ - 1 : sector_ + 5);
  
   // Get coordinates from fullsim since LUTs do not exist yet
   bool use_fullsim_coords = true;
   if (use_fullsim_coords) {
     const GlobalPoint& gp = tp_geom_->getGlobalPoint(muon_primitive);
     double glob_phi = emtf::rad_to_deg(gp.phi().value());
     double glob_theta = emtf::rad_to_deg(gp.theta());
     double glob_eta = gp.eta();
     double glob_rho = gp.perp();
     double glob_z = gp.z();
  
     // Use the CSC precision (unconfirmed!)
     int fph = emtf::calc_phi_loc_int(glob_phi, conv_hit.PC_sector());
     int th = emtf::calc_theta_int(glob_theta, conv_hit.Endcap());
  
     bool fix_me0_theta_edge = true;
     if (fix_me0_theta_edge) {
       // The ME0 extends to eta of 2.8 or theta of 7.0 deg. But integer theta
       // only starts at theta of 8.5 deg.
       if (th < 0)
         th = 0;
     }
  
     emtf_assert(0 <= fph && fph < 5000);
     emtf_assert(0 <= th && th < 128);
     th = (th == 0) ? 1 : th;  // protect against invalid value
  
     // _________________________________________________________________________
     // Output
  
     conv_hit.set_phi_sim(glob_phi);
     conv_hit.set_theta_sim(glob_theta);
     conv_hit.set_eta_sim(glob_eta);
     conv_hit.set_rho_sim(glob_rho);
     conv_hit.set_z_sim(glob_z);
  
     conv_hit.set_phi_fp(fph);   // Full-precision integer phi
     conv_hit.set_theta_fp(th);  // Full-precision integer theta
   }
  
   convert_other_details(conv_hit);
 }

Referenced by process().

◆ convert_other_details()

void PrimitiveConversion::convert_other_details ( EMTFHit & conv_hit ) const

Definition at line 818 of file PrimitiveConversion.cc.

                                                                        {
   const bool is_neighbor = conv_hit.Neighbor();
  
   const int pc_station = conv_hit.PC_station();
   const int pc_chamber = conv_hit.PC_chamber();
   const int pc_segment = conv_hit.PC_segment();
  
   //const int fw_endcap  = (endcap_-1);
   //const int fw_sector  = (sector_-1);
   const int fw_station =
       (conv_hit.Station() == 1) ? (is_neighbor ? 0 : (conv_hit.Subsector() - 1)) : conv_hit.Station();
   const int fw_cscid = (conv_hit.CSC_nID() - 1);
  
   int fph = conv_hit.Phi_fp();
   int th = conv_hit.Theta_fp();
  
   if (verbose_ > 1) {  // debug
     std::cout << "GEM hit pc_station: " << pc_station << " pc_chamber: " << pc_chamber << " fw_station: " << fw_station
               << " fw_cscid: " << fw_cscid << " tp_station: " << conv_hit.Station() << " tp_ring: " << conv_hit.Ring()
               << " tp_sector: " << conv_hit.Sector() << " tp_subsector: " << conv_hit.Subsector() << " fph: " << fph
               << " th: " << th << std::endl;
   }
  
   // ___________________________________________________________________________
   // Zone codes and other segment IDs
  
   int zone_hit = ((fph + (1 << 4)) >> 5);
   int zone_code = get_zone_code(conv_hit, th);
   //int phzvl        = get_phzvl(conv_hit, zone_code);
  
   int fs_zone_code = get_fs_zone_code(conv_hit);
   int fs_segment = get_fs_segment(conv_hit, fw_station, fw_cscid, pc_segment);
  
   int bt_station = get_bt_station(conv_hit, fw_station, fw_cscid, pc_segment);
   int bt_segment = get_bt_segment(conv_hit, fw_station, fw_cscid, pc_segment);
  
   // ___________________________________________________________________________
   // Output
  
   conv_hit.set_phi_fp(fph);   // Full-precision integer phi
   conv_hit.set_theta_fp(th);  // Full-precision integer theta
   //conv_hit.set_phzvl      ( phzvl );      // Local zone word: (1*low) + (2*mid) + (4*low) - used in FW debugging
   //conv_hit.set_ph_hit     ( ph_hit );     // Intermediate quantity in phi calculation - used in FW debugging
   conv_hit.set_zone_hit(zone_hit);    // Phi value for building patterns (0.53333 deg precision)
   conv_hit.set_zone_code(zone_code);  // Full zone word: 1*(zone 0) + 2*(zone 1) + 4*(zone 2) + 8*(zone 3)
  
   conv_hit.set_fs_segment(fs_segment);      // Segment number used in primitive matching
   conv_hit.set_fs_zone_code(fs_zone_code);  // Zone word used in primitive matching
  
   conv_hit.set_bt_station(bt_station);
   conv_hit.set_bt_segment(bt_segment);
  
   conv_hit.set_phi_loc(emtf::calc_phi_loc_deg(fph));
   conv_hit.set_phi_glob(emtf::calc_phi_glob_deg(conv_hit.Phi_loc(), conv_hit.PC_sector()));
   conv_hit.set_theta(emtf::calc_theta_deg_from_int(th));
   conv_hit.set_eta(emtf::calc_eta_from_theta_deg(conv_hit.Theta(), conv_hit.Endcap()));
 }

Referenced by convert_dt(), convert_gem(), and convert_me0().

◆ convert_rpc()

void PrimitiveConversion::convert_rpc	(	int	pc_sector,
		int	pc_station,
		int	pc_chamber,
		int	pc_segment,
		const TriggerPrimitive &	muon_primitive,
		EMTFHit &	conv_hit
	)		const

Definition at line 450 of file PrimitiveConversion.cc.

                                                                {
   const RPCDetId& tp_detId = muon_primitive.detId<RPCDetId>();
   const RPCData& tp_data = muon_primitive.getRPCData();
  
   int tp_region = tp_detId.region();  // 0 for Barrel, +/-1 for +/- Endcap
   int tp_endcap = (tp_region == -1) ? 2 : tp_region;
   int tp_sector = tp_detId.sector();        // 1 - 6 (60 degrees in phi, sector 1 begins at -5 deg)
   int tp_subsector = tp_detId.subsector();  // 1 - 6 (10 degrees in phi; staggered in z)
   int tp_station = tp_detId.station();      // 1 - 4
   int tp_ring = tp_detId.ring();            // 2 - 3 (increasing theta)
   int tp_roll = tp_detId.roll();  // 1 - 3 (decreasing theta; aka A - C; space between rolls is 9 - 15 in theta_fp)
   //int tp_layer     = tp_detId.layer();      // Always 1 in the Endcap, 1 or 2 in the Barrel
  
   int tp_bx = tp_data.bx;
   int tp_strip = ((tp_data.strip_low + tp_data.strip_hi) / 2);  // in full-strip unit
  
   const bool is_neighbor = (pc_station == 5);
  
   // CSC-like sector, subsector and chamber numbers
   int csc_tp_chamber = (tp_sector - 1) * 6 + tp_subsector;
   int csc_tp_sector = (tp_subsector > 2) ? tp_sector : ((tp_sector + 4) % 6) + 1;  // Rotate by 20 deg
   int csc_tp_subsector = (tp_station != 1) ? 0 : ((csc_tp_chamber % 6 > 2) ? 1 : 2);
  
   const bool is_irpc = (tp_station == 3 || tp_station == 4) && (tp_ring == 1);
   if (is_irpc) {
     csc_tp_chamber = (tp_sector - 1) * 3 + tp_subsector;
     csc_tp_sector = (tp_subsector > 1) ? tp_sector : ((tp_sector + 4) % 6) + 1;  // Rotate by 20 deg
     csc_tp_subsector = (tp_station != 1) ? 0 : ((csc_tp_chamber % 6 > 2) ? 1 : 2);
   }
   int tp_csc_ID = emtf::get_trigger_csc_ID(tp_ring, tp_station, csc_tp_chamber);
  
   int csc_nID = tp_csc_ID;  // modify csc_ID if coming from neighbor sector
   if (is_neighbor) {
     // station 1 has 3 neighbor chambers: 13,14,15 in rings 1,2,3
     // (where are chambers 10,11,12 in station 1? they were used to label ME1/1a, but not anymore)
     // station 2,3,4 have 2 neighbor chambers: 10,11 in rings 1,2
     csc_nID = (pc_chamber < 3) ? (pc_chamber + 12) : (((pc_chamber - 1) % 2) + 9);
     csc_nID += 1;
   }
  
   // Use cluster width as 'quality'
   int tp_quality = (tp_data.strip_hi - tp_data.strip_low + 1);
   if (!is_irpc) {
     tp_quality *= 3;  // old RPC strip pitch is 1.5 times the new iRPC
     tp_quality /= 2;
   }
  
   // Set properties
   conv_hit.SetRPCDetId(tp_detId);
  
   conv_hit.set_bx(tp_bx + bxShiftRPC_);
   conv_hit.set_subsystem(L1TMuon::kRPC);
   conv_hit.set_endcap((tp_endcap == 2) ? -1 : tp_endcap);
   conv_hit.set_station(tp_station);
   conv_hit.set_ring(tp_ring);
   conv_hit.set_roll(tp_roll);
   conv_hit.set_chamber(csc_tp_chamber);
   conv_hit.set_sector(csc_tp_sector);
   conv_hit.set_subsector(csc_tp_subsector);
   conv_hit.set_csc_ID(tp_csc_ID);
   conv_hit.set_csc_nID(csc_nID);
   //conv_hit.set_track_num     ( tp_data.trknmb );
   //conv_hit.set_sync_err      ( tp_data.syncErr );
   conv_hit.set_sector_RPC(tp_sector);  // In RPC convention in CMSSW (RPCDetId.h), sector 1 starts at -5 deg
   conv_hit.set_subsector_RPC(tp_subsector);
  
   conv_hit.set_pc_sector(pc_sector);
   conv_hit.set_pc_station(pc_station);
   conv_hit.set_pc_chamber(pc_chamber);
   conv_hit.set_pc_segment(pc_segment);
  
   conv_hit.set_valid(tp_data.valid);
   conv_hit.set_strip(tp_strip);
   conv_hit.set_strip_low(tp_data.strip_low);
   conv_hit.set_strip_hi(tp_data.strip_hi);
   //conv_hit.set_wire          ( tp_data.keywire );
   conv_hit.set_quality(tp_quality);
   conv_hit.set_pattern(0);  // In firmware, this marks RPC stub
   //conv_hit.set_bend          ( tp_data.bend );
   conv_hit.set_time(tp_data.time);
   //conv_hit.set_alct_quality  ( tp_data.alct_quality );
   //conv_hit.set_clct_quality  ( tp_data.clct_quality );
  
   conv_hit.set_neighbor(is_neighbor);
   conv_hit.set_sector_idx((endcap_ == 1) ? sector_ - 1 : sector_ + 5);
  
   // Get coordinates from fullsim
   bool use_fullsim_coords = true;
  
   if (tp_data.isCPPF) {                            // CPPF digis from EMTF unpacker or CPPF emulator
     conv_hit.set_phi_fp(tp_data.phi_int * 4);      // Full-precision integer phi
     conv_hit.set_theta_fp(tp_data.theta_int * 4);  // Full-precision integer theta
   } else if (use_fullsim_coords) {
     const GlobalPoint& gp = tp_geom_->getGlobalPoint(muon_primitive);
     double glob_phi = emtf::rad_to_deg(gp.phi().value());
     double glob_theta = emtf::rad_to_deg(gp.theta());
     double glob_eta = gp.eta();
     double glob_rho = gp.perp();
     double glob_z = gp.z();
  
     // Use RPC-specific convention in docs/CPPF-EMTF-format_2016_11_01.docx
     // Phi precision is 1/15 degrees (11 bits), 4x larger than CSC precision of 1/60 degrees (13 bits)
     // Theta precision is 36.5/32 degrees (5 bits), 4x larger than CSC precision of 36.5/128 degrees (7 bits)
     //
     // NOTE: fph and th are recalculated using CPPF LUTs in the convert_rpc_details() function,
     //       this part is still kept because it is needed for Phase 2 iRPC hits.
     //
     int fph = emtf::calc_phi_loc_int_rpc(glob_phi, conv_hit.PC_sector());
     int th = emtf::calc_theta_int_rpc(glob_theta, conv_hit.Endcap());
  
     //emtf_assert(0 <= fph && fph < 1024);
     emtf_assert(0 <= fph && fph < 1250);
     emtf_assert(0 <= th && th < 32);
     emtf_assert(th != 0b11111);  // RPC hit valid when data is not all ones
     fph <<= 2;                   // upgrade to full CSC precision by adding 2 zeros
     th <<= 2;                    // upgrade to full CSC precision by adding 2 zeros
     th = (th == 0) ? 1 : th;     // protect against invalid value
  
     if (is_irpc) {
       const RPCRoll* roll = dynamic_cast<const RPCRoll*>(tp_geom_->getRPCGeometry().roll(tp_detId));
       emtf_assert(roll != nullptr);  // failed to get RPC roll
       const GlobalPoint& new_gp = roll->surface().toGlobal(LocalPoint(tp_data.x, tp_data.y, 0));
       glob_phi = emtf::rad_to_deg(gp.phi().value());  // using 'gp' instead of 'new_gp' for phi
       glob_theta = emtf::rad_to_deg(new_gp.theta());
       glob_eta = new_gp.eta();
       glob_rho = new_gp.perp();
       glob_z = new_gp.z();
  
       fph = emtf::calc_phi_loc_int(glob_phi, conv_hit.PC_sector());
       th = emtf::calc_theta_int(glob_theta, conv_hit.Endcap());
  
       emtf_assert(0 <= fph && fph < 5000);
       emtf_assert(0 <= th && th < 128);
       th = (th == 0) ? 1 : th;  // protect against invalid value
     }
  
     // _________________________________________________________________________
     // Output
  
     conv_hit.set_phi_sim(glob_phi);
     conv_hit.set_theta_sim(glob_theta);
     conv_hit.set_eta_sim(glob_eta);
     conv_hit.set_rho_sim(glob_rho);
     conv_hit.set_z_sim(glob_z);
  
     conv_hit.set_phi_fp(fph);   // Full-precision integer phi
     conv_hit.set_theta_fp(th);  // Full-precision integer theta
   }
  
   convert_rpc_details(conv_hit, tp_data.isCPPF);
 }

Referenced by process().

◆ convert_rpc_details()

void PrimitiveConversion::convert_rpc_details	(	EMTFHit &	conv_hit,
		bool	isCPPF
	)		const

Definition at line 607 of file PrimitiveConversion.cc.

                                                                                   {
   const bool is_neighbor = conv_hit.Neighbor();
  
   const int pc_station = conv_hit.PC_station();
   const int pc_chamber = conv_hit.PC_chamber();
   const int pc_segment = conv_hit.PC_segment();
  
   //const int fw_endcap  = (endcap_-1);
   //const int fw_sector  = (sector_-1);
   const int fw_station = (conv_hit.Station() == 1) ? (is_neighbor ? 0 : pc_station) : conv_hit.Station();
   const int fw_cscid = (conv_hit.CSC_nID() - 1);
  
   int fph = conv_hit.Phi_fp();
   int th = conv_hit.Theta_fp();
  
   // Do coordinate conversion using the CPPF LUTs. Not needed if the received digis are CPPF digis.
   bool use_cppf_lut = !isCPPF;
  
   if (use_cppf_lut) {
     int halfstrip = (conv_hit.Strip_low() + conv_hit.Strip_hi() - 1);
     emtf_assert(1 <= halfstrip && halfstrip <= 64);
  
     int fph2 = pc_lut().get_cppf_ph_lut(conv_hit.Endcap(),
                                         conv_hit.Sector_RPC(),
                                         conv_hit.Station(),
                                         conv_hit.Ring(),
                                         conv_hit.Subsector_RPC(),
                                         conv_hit.Roll(),
                                         halfstrip,
                                         is_neighbor);
     int th2 = pc_lut().get_cppf_th_lut(conv_hit.Endcap(),
                                        conv_hit.Sector_RPC(),
                                        conv_hit.Station(),
                                        conv_hit.Ring(),
                                        conv_hit.Subsector_RPC(),
                                        conv_hit.Roll());
     //emtf_assert(abs((fph>>2) - fph2) <= 4); // arbitrary tolerance
     //emtf_assert(abs((th>>2) - th2) <= 1);   // arbitrary tolerance
     fph = fph2;
     th = th2;
  
     //emtf_assert(0 <= fph && fph < 1024);
     emtf_assert(0 <= fph && fph < 1250);
     emtf_assert(0 <= th && th < 32);
     emtf_assert(th != 0b11111);  // RPC hit valid when data is not all ones
     fph <<= 2;                   // upgrade to full CSC precision by adding 2 zeros
     th <<= 2;                    // upgrade to full CSC precision by adding 2 zeros
     th = (th == 0) ? 1 : th;     // protect against invalid value
   }
  
   if (verbose_ > 1) {  // debug
     std::cout << "RPC hit pc_station: " << pc_station << " pc_chamber: " << pc_chamber << " fw_station: " << fw_station
               << " fw_cscid: " << fw_cscid << " tp_station: " << conv_hit.Station() << " tp_ring: " << conv_hit.Ring()
               << " tp_sector: " << conv_hit.Sector_RPC() << " tp_subsector: " << conv_hit.Subsector_RPC()
               << " fph: " << fph << " th: " << th << std::endl;
   }
  
   // ___________________________________________________________________________
   // Zone codes and other segment IDs
  
   int zone_hit = ((fph + (1 << 4)) >> 5);
   int zone_code = get_zone_code(conv_hit, th);
   //int phzvl        = get_phzvl(conv_hit, zone_code);
  
   int fs_zone_code = get_fs_zone_code(conv_hit);
   int fs_segment = get_fs_segment(conv_hit, fw_station, fw_cscid, pc_segment);
  
   int bt_station = get_bt_station(conv_hit, fw_station, fw_cscid, pc_segment);
   int bt_segment = get_bt_segment(conv_hit, fw_station, fw_cscid, pc_segment);
  
   // ___________________________________________________________________________
   // Output
  
   conv_hit.set_phi_fp(fph);   // Full-precision integer phi
   conv_hit.set_theta_fp(th);  // Full-precision integer theta
   //conv_hit.set_phzvl      ( phzvl );      // Local zone word: (1*low) + (2*mid) + (4*low) - used in FW debugging
   //conv_hit.set_ph_hit     ( ph_hit );     // Intermediate quantity in phi calculation - used in FW debugging
   conv_hit.set_zone_hit(zone_hit);    // Phi value for building patterns (0.53333 deg precision)
   conv_hit.set_zone_code(zone_code);  // Full zone word: 1*(zone 0) + 2*(zone 1) + 4*(zone 2) + 8*(zone 3)
  
   conv_hit.set_fs_segment(fs_segment);      // Segment number used in primitive matching
   conv_hit.set_fs_zone_code(fs_zone_code);  // Zone word used in primitive matching
  
   conv_hit.set_bt_station(bt_station);
   conv_hit.set_bt_segment(bt_segment);
  
   conv_hit.set_phi_loc(emtf::calc_phi_loc_deg(fph));
   conv_hit.set_phi_glob(emtf::calc_phi_glob_deg(conv_hit.Phi_loc(), conv_hit.PC_sector()));
   conv_hit.set_theta(emtf::calc_theta_deg_from_int(th));
   conv_hit.set_eta(emtf::calc_eta_from_theta_deg(conv_hit.Theta(), conv_hit.Endcap()));
 }

Referenced by convert_rpc().

◆ get_bt_segment()

int PrimitiveConversion::get_bt_segment	(	const EMTFHit &	conv_hit,
		int	fw_station,
		int	fw_cscid,
		int	pc_segment
	)		const

Definition at line 1241 of file PrimitiveConversion.cc.

                                                                                                                    {
   // For later use in angle calculation and best track selection
   // (in the firmware, this happens in the best_tracks module)
   int bt_history = 0;               // history id: not set here, to be set in primitive matching
   int bt_chamber = -1;              // chamber id
   int bt_segment = pc_segment % 2;  // segment id
  
   // For ME1
   //   j = 0 is No valid LCT
   //   j = 1 .. 9 are native sector chambers
   //   j = 10 .. 12 are neighbor sector chambers
   // For ME2,3,4
   //   j = 0 is No valid LCT
   //   j = 1 .. 9 are native sector chambers
   //   j = 10 .. 11 are neighbor sector chambers
   bt_chamber = fw_cscid + 1;
   if (fw_station == 0 && bt_chamber >= 13)  // ME1 neighbor chambers 13,14,15 -> 10,11,12
     bt_chamber -= 3;
  
   emtf_assert(bt_history == 0 && (0 <= bt_chamber && bt_chamber < 13) && (0 <= bt_segment && bt_segment < 2));
   // bt_segment is a 7-bit word, HHCCCCS, encoding the segment number S in the chamber (1 or 2),
   // the chamber number CCCC ("j" above: uniquely identifies chamber within station and ring),
   // and the history HH (0 for current BX, 1 for previous BX, 2 for BX before that)
   bt_segment = ((bt_history & 0x3) << 5) | ((bt_chamber & 0xf) << 1) | (bt_segment & 0x1);
   return bt_segment;
 }

References emtf_assert.

Referenced by convert_csc_details(), convert_other_details(), and convert_rpc_details().

◆ get_bt_station()

int PrimitiveConversion::get_bt_station	(	const EMTFHit &	conv_hit,
		int	fw_station,
		int	fw_cscid,
		int	pc_segment
	)		const

Definition at line 1236 of file PrimitiveConversion.cc.

                                                                                                                    {
   int bt_station = fw_station;
   return bt_station;
 }

Referenced by convert_csc_details(), convert_other_details(), and convert_rpc_details().

◆ get_fs_segment()

int PrimitiveConversion::get_fs_segment	(	const EMTFHit &	conv_hit,
		int	fw_station,
		int	fw_cscid,
		int	pc_segment
	)		const

Definition at line 1205 of file PrimitiveConversion.cc.

                                                                                                                    {
   // For later use in primitive matching
   // (in the firmware, this happens in the find_segment module)
   int fs_history = 0;               // history id: not set here, to be set in primitive matching
   int fs_chamber = -1;              // chamber id
   int fs_segment = pc_segment % 2;  // segment id
  
   // For ME1
   //   j = 0 is neighbor sector chamber
   //   j = 1,2,3 are native subsector 1 chambers
   //   j = 4,5,6 are native subsector 2 chambers
   // For ME2,3,4:
   //   j = 0 is neighbor sector chamber
   //   j = 1,2,3,4,5,6 are native sector chambers
   const bool is_neighbor = conv_hit.Neighbor();
   if (fw_station <= 1) {  // ME1
     int n = fw_cscid % 3;
     fs_chamber = is_neighbor ? 0 : ((fw_station == 0) ? 1 + n : 4 + n);
   } else {  // ME2,3,4
     int n = (conv_hit.Ring() == 1) ? fw_cscid : (fw_cscid - 3);
     fs_chamber = is_neighbor ? 0 : 1 + n;
   }
  
   emtf_assert(fs_history == 0 && (0 <= fs_chamber && fs_chamber < 7) && (0 <= fs_segment && fs_segment < 2));
   // fs_segment is a 6-bit word, HHCCCS, encoding the segment number S in the chamber (1 or 2),
   // the chamber number CCC ("j" above: uniquely identifies chamber within station and ring),
   // and the history HH (0 for current BX, 1 for previous BX, 2 for BX before that)
   fs_segment = ((fs_history & 0x3) << 4) | ((fs_chamber & 0x7) << 1) | (fs_segment & 0x1);
   return fs_segment;
 }

References emtf_assert, dqmiodumpmetadata::n, l1t::EMTFHit::Neighbor(), and l1t::EMTFHit::Ring().

Referenced by convert_csc_details(), convert_other_details(), and convert_rpc_details().

◆ get_fs_zone_code()

int PrimitiveConversion::get_fs_zone_code ( const EMTFHit & conv_hit ) const

Definition at line 1181 of file PrimitiveConversion.cc.

                                                                        {
   static const unsigned int zone_code_table[4][3] = {
       // map (station,ring) to zone_code
       {0b0011, 0b0100, 0b1000},  // st1 r1: [z0,z1], r2: [z2],       r3: [z3]
       {0b0011, 0b1100, 0b1100},  // st2 r1: [z0,z1], r2: [z2,z3],    r3 = r2
       {0b0001, 0b1110, 0b1110},  // st3 r1: [z0],    r2: [z1,z2,z3], r3 = r2
       {0b0001, 0b0110, 0b0110}   // st4 r1: [z0],    r2: [z1,z2],    r3 = r2
   };
  
   static const unsigned int zone_code_table_new[4][3] = {
       // map (station,ring) to zone_code
       {0b0011, 0b0110, 0b1000},  // st1 r1: [z0,z1], r2: [z1,z2],    r3: [z3]
       {0b0011, 0b1110, 0b1110},  // st2 r1: [z0,z1], r2: [z1,z2,z3], r3 = r2
       {0b0011, 0b1110, 0b1110},  // st3 r1: [z0,z1], r2: [z1,z2,z3], r3 = r2
       {0b0001, 0b0110, 0b0110}   // st4 r1: [z0],    r2: [z1,z2],    r3 = r2
   };
  
   unsigned int istation = (conv_hit.Station() - 1);
   unsigned int iring = (conv_hit.Ring() == 4) ? 0 : (conv_hit.Ring() - 1);
   emtf_assert(istation < 4 && iring < 3);
   unsigned int zone_code = useNewZones_ ? zone_code_table_new[istation][iring] : zone_code_table[istation][iring];
   return zone_code;
 }

References emtf_assert, l1t::EMTFHit::Ring(), l1t::EMTFHit::Station(), and useNewZones_.

Referenced by convert_csc_details(), convert_other_details(), convert_rpc_details(), and get_zone_code().

◆ get_phzvl()

int PrimitiveConversion::get_phzvl	(	const EMTFHit &	conv_hit,
		int	zone_code
	)		const

Definition at line 1162 of file PrimitiveConversion.cc.

                                                                                {
   // For backward compatibility, no longer needed (only explicitly used in FW)
   // phzvl: each chamber overlaps with at most 3 zones, so this "local" zone word says
   // which of the possible zones contain the hit: 1 for lower, 2 for middle, 4 for upper
   int phzvl = 0;
   if (conv_hit.Ring() == 1 || conv_hit.Ring() == 4) {
     phzvl = (zone_code >> 0);
   } else if (conv_hit.Ring() == 2) {
     if (conv_hit.Station() == 3 || conv_hit.Station() == 4) {
       phzvl = (zone_code >> 1);
     } else if (conv_hit.Station() == 1 || conv_hit.Station() == 2) {
       phzvl = (zone_code >> 2);
     }
   } else if (conv_hit.Ring() == 3) {
     phzvl = (zone_code >> 3);
   }
   return phzvl;
 }

References l1t::EMTFHit::Ring(), and l1t::EMTFHit::Station().

◆ get_zone_code()

int PrimitiveConversion::get_zone_code	(	const EMTFHit &	conv_hit,
		int	th
	)		const

Definition at line 1132 of file PrimitiveConversion.cc.

                                                                             {
   // ph zone boundaries for chambers that cover more than one zone
   // bnd1 is the lower boundary, bnd2 the upper boundary
   int zone_code = 0;
  
   bool is_csc = (conv_hit.Subsystem() == L1TMuon::kCSC);
   bool is_me13 = (is_csc && conv_hit.Station() == 1 && conv_hit.Ring() == 3);
  
   if (th >= 127)
     th = 127;
  
   for (int izone = 0; izone < emtf::NUM_ZONES; ++izone) {
     int zone_code_tmp = get_fs_zone_code(conv_hit);
     if (zone_code_tmp & (1 << izone)) {
       bool no_use_bnd1 =
           ((izone == 0) || ((zone_code_tmp & (1 << (izone - 1))) == 0) || is_me13);  // first possible zone for this hit
       bool no_use_bnd2 = (((zone_code_tmp & (1 << (izone + 1))) == 0) || is_me13);   // last possible zone for this hit
  
       int ph_zone_bnd1 = no_use_bnd1 ? zoneBoundaries_.at(0) : zoneBoundaries_.at(izone);
       int ph_zone_bnd2 = no_use_bnd2 ? zoneBoundaries_.at(emtf::NUM_ZONES) : zoneBoundaries_.at(izone + 1);
  
       if ((th > (ph_zone_bnd1 - zoneOverlap_)) && (th <= (ph_zone_bnd2 + zoneOverlap_))) {
         zone_code |= (1 << izone);
       }
     }
   }
   emtf_assert(zone_code > 0);
   return zone_code;
 }

References emtf_assert, get_fs_zone_code(), L1TMuon::kCSC, emtf::NUM_ZONES, l1t::EMTFHit::Ring(), l1t::EMTFHit::Station(), l1t::EMTFHit::Subsystem(), zoneBoundaries_, and zoneOverlap_.

Referenced by convert_csc_details(), convert_other_details(), and convert_rpc_details().

◆ is_valid_for_run2()

bool PrimitiveConversion::is_valid_for_run2 ( const EMTFHit & conv_hit ) const

Definition at line 1268 of file PrimitiveConversion.cc.

                                                                          {
   bool is_csc = conv_hit.Is_CSC();
   bool is_rpc = conv_hit.Is_RPC();
   bool is_irpc = conv_hit.Is_RPC() && ((conv_hit.Station() == 3 || conv_hit.Station() == 4) && (conv_hit.Ring() == 1));
   bool is_omtf = conv_hit.Is_RPC() && ((conv_hit.Station() == 1 || conv_hit.Station() == 2) &&
                                        (conv_hit.Ring() == 3));  // RPC in the overlap region
   return (is_csc || (is_rpc && !is_irpc && !is_omtf));
 }

References l1t::EMTFHit::Is_CSC(), l1t::EMTFHit::Is_RPC(), l1t::EMTFHit::Ring(), and l1t::EMTFHit::Station().

◆ pc_lut()

const SectorProcessorLUT& PrimitiveConversion::pc_lut ( ) const

inline

Definition at line 30 of file PrimitiveConversion.h.

30 { return *pc_lut_; }

References pc_lut_.

Referenced by configure(), convert_csc_details(), and convert_rpc_details().

◆ process()

void PrimitiveConversion::process	(	const std::map< int, TriggerPrimitiveCollection > &	selected_prim_map,
		EMTFHitCollection &	conv_hits
	)		const

Definition at line 49 of file PrimitiveConversion.cc.

                                                                       {
   std::map<int, TriggerPrimitiveCollection>::const_iterator map_tp_it = selected_prim_map.begin();
   std::map<int, TriggerPrimitiveCollection>::const_iterator map_tp_end = selected_prim_map.end();
  
   for (; map_tp_it != map_tp_end; ++map_tp_it) {
     // Unique chamber ID in FW, {0, 53} as defined in get_index_csc in src/PrimitiveSelection.cc
     int selected = map_tp_it->first;
     // "Primitive Conversion" sector/station/chamber ID scheme used in FW
     int pc_sector = sector_;
     int pc_station = selected / 9;  // {0, 5} = {ME1 sub 1, ME1 sub 2, ME2, ME3, ME4, neighbor}
     int pc_chamber = selected % 9;  // Equals CSC ID - 1 for all except neighbor chambers
     int pc_segment = 0;             // Counts hits in a single chamber
  
     TriggerPrimitiveCollection::const_iterator tp_it = map_tp_it->second.begin();
     TriggerPrimitiveCollection::const_iterator tp_end = map_tp_it->second.end();
  
     for (; tp_it != tp_end; ++tp_it) {
       EMTFHit conv_hit;
       if (tp_it->subsystem() == L1TMuon::kCSC) {
         convert_csc(pc_sector, pc_station, pc_chamber, pc_segment, *tp_it, conv_hit);
       } else if (tp_it->subsystem() == L1TMuon::kRPC) {
         convert_rpc(pc_sector, pc_station, pc_chamber, pc_segment, *tp_it, conv_hit);
       } else if (tp_it->subsystem() == L1TMuon::kGEM) {
         convert_gem(pc_sector, 0, selected, pc_segment, *tp_it, conv_hit);  // pc_station and pc_chamber are meaningless
       } else if (tp_it->subsystem() == L1TMuon::kME0) {
         convert_me0(pc_sector, 0, selected, pc_segment, *tp_it, conv_hit);  // pc_station and pc_chamber are meaningless
       } else if (tp_it->subsystem() == L1TMuon::kDT) {
         convert_dt(pc_sector, 0, selected, pc_segment, *tp_it, conv_hit);  // pc_station and pc_chamber are meaningless
       } else {
         emtf_assert(false && "Incorrect subsystem type");
       }
       conv_hits.push_back(conv_hit);
       pc_segment += 1;
     }
   }
 }

References convert_csc(), convert_dt(), convert_gem(), convert_me0(), convert_rpc(), emtf_assert, L1TMuon::kCSC, L1TMuon::kDT, L1TMuon::kGEM, L1TMuon::kME0, L1TMuon::kRPC, and sector_.

Referenced by SectorProcessor::process_single_bx().

Member Data Documentation

◆ bugME11Dupes_

bool PrimitiveConversion::bugME11Dupes_

private

Definition at line 105 of file PrimitiveConversion.h.

Referenced by configure(), and convert_csc_details().

◆ bx_

int PrimitiveConversion::bx_

private

Definition at line 98 of file PrimitiveConversion.h.

Referenced by configure().

◆ bxShiftCSC_

int PrimitiveConversion::bxShiftCSC_

private

Definition at line 100 of file PrimitiveConversion.h.

Referenced by configure(), and convert_csc().

◆ bxShiftGEM_

int PrimitiveConversion::bxShiftGEM_

private

Definition at line 100 of file PrimitiveConversion.h.

Referenced by configure(), and convert_gem().

◆ bxShiftME0_

int PrimitiveConversion::bxShiftME0_

private

Definition at line 100 of file PrimitiveConversion.h.

Referenced by configure(), and convert_me0().

◆ bxShiftRPC_

int PrimitiveConversion::bxShiftRPC_

private

Definition at line 100 of file PrimitiveConversion.h.

Referenced by configure(), and convert_rpc().

◆ duplicateTheta_

bool PrimitiveConversion::duplicateTheta_

private

Definition at line 104 of file PrimitiveConversion.h.

Referenced by configure().

◆ endcap_

int PrimitiveConversion::endcap_

private

Definition at line 98 of file PrimitiveConversion.h.

Referenced by configure(), convert_csc(), convert_csc_details(), convert_dt(), convert_gem(), convert_me0(), and convert_rpc().

◆ fixME11Edges_

bool PrimitiveConversion::fixME11Edges_

private

Definition at line 104 of file PrimitiveConversion.h.

Referenced by configure(), and convert_csc_details().

◆ fixZonePhi_

bool PrimitiveConversion::fixZonePhi_

private

Definition at line 104 of file PrimitiveConversion.h.

Referenced by configure(), and convert_csc_details().

◆ pc_lut_

const SectorProcessorLUT* PrimitiveConversion::pc_lut_

private

Definition at line 96 of file PrimitiveConversion.h.

Referenced by configure(), and pc_lut().

◆ sector_

int PrimitiveConversion::sector_

private

Definition at line 98 of file PrimitiveConversion.h.

Referenced by configure(), convert_csc(), convert_csc_details(), convert_dt(), convert_gem(), convert_me0(), convert_rpc(), and process().

◆ tp_geom_

const GeometryTranslator* PrimitiveConversion::tp_geom_

private

Definition at line 94 of file PrimitiveConversion.h.

Referenced by configure(), convert_csc(), convert_dt(), convert_gem(), convert_me0(), and convert_rpc().

◆ useNewZones_

bool PrimitiveConversion::useNewZones_

private

Definition at line 104 of file PrimitiveConversion.h.

Referenced by configure(), and get_fs_zone_code().

◆ verbose_

int PrimitiveConversion::verbose_

private

Definition at line 98 of file PrimitiveConversion.h.

Referenced by configure(), convert_csc_details(), convert_other_details(), and convert_rpc_details().

◆ zoneBoundaries_

std::vector<int> PrimitiveConversion::zoneBoundaries_

private

Definition at line 102 of file PrimitiveConversion.h.

Referenced by configure(), and get_zone_code().

◆ zoneOverlap_

int PrimitiveConversion::zoneOverlap_

private

Definition at line 103 of file PrimitiveConversion.h.

Referenced by configure(), and get_zone_code().

Public Member Functions

Private Attributes

Detailed Description

Member Function Documentation

◆ configure()

◆ convert_csc()

◆ convert_csc_details()

◆ convert_dt()

◆ convert_gem()

◆ convert_me0()

◆ convert_other_details()

◆ convert_rpc()

◆ convert_rpc_details()

◆ get_bt_segment()

◆ get_bt_station()

◆ get_fs_segment()

◆ get_fs_zone_code()

◆ get_phzvl()

◆ get_zone_code()

◆ is_valid_for_run2()

◆ pc_lut()

◆ process()

Member Data Documentation

◆ bugME11Dupes_

◆ bx_

◆ bxShiftCSC_

◆ bxShiftGEM_

◆ bxShiftME0_

◆ bxShiftRPC_

◆ duplicateTheta_

◆ endcap_

◆ fixME11Edges_

◆ fixZonePhi_

◆ pc_lut_

◆ sector_

◆ tp_geom_

◆ useNewZones_

◆ verbose_

◆ zoneBoundaries_

◆ zoneOverlap_