GctFormatTranslateV38.cc

Go to the documentation of this file.

#include "EventFilter/GctRawToDigi/src/GctFormatTranslateV38.h"
 
// C++ headers
#include <iostream>
#include <cassert>
#include <algorithm>
#include <cmath>
 
// Framework headers
#include "FWCore/MessageLogger/interface/MessageLogger.h"
 
// Namespace resolution
using std::cout;
using std::endl;
using std::make_pair;
using std::pair;
 
// INITIALISE STATIC VARIABLES
/*** Setup BlockID to BlockLength Map ***/
const GctFormatTranslateV38::BlockLengthMap GctFormatTranslateV38::m_blockLength = {
    // Miscellaneous Blocks
    {0x000, 0},  // NULL
    // ConcJet FPGA
    {0x580, 12},  // ConcJet: Input TrigPathA (Jet Cands)
    {0x581, 2},   // ConcJet: Input TrigPathB (HF Rings)
    {0x582, 4},   // ConcJet: Input TrigPathC (MissHt)
    {0x583, 8},   // ConcJet: Jet Cands and Counts Output to GT
    {0x587, 4},   // ConcJet: BX & Orbit Info
    // ConcElec FPGA
    {0x680, 16},  // ConcElec: Input TrigPathA (EM Cands)
    {0x681, 6},   // ConcElec: Input TrigPathB (Et Sums)
    {0x682, 2},   // ConcElec: Input TrigPathC (Ht Sums)
    {0x683, 6},   // ConcElec: EM Cands and Energy Sums Output to GT
    {0x686, 2},   // ConcElec: Test (GT Serdes Loopback)
    {0x687, 4},   // ConcElec: BX & Orbit Info
    // Electron Leaf FPGAs
    {0x800, 20},  // Leaf0ElecPosEtaU1: Sort Input
    {0x803, 4},   // Leaf0ElecPosEtaU1: Sort Output
    {0x804, 15},  // Leaf0ElecPosEtaU1: Raw Input
    {0x880, 16},  // Leaf0ElecPosEtaU2: Sort Input
    {0x883, 4},   // Leaf0ElecPosEtaU2: Sort Output
    {0x884, 12},  // Leaf0ElecPosEtaU2: Raw Input
    {0xc00, 20},  // Leaf0ElecNegEtaU1: Sort Input
    {0xc03, 4},   // Leaf0ElecNegEtaU1: Sort Output
    {0xc04, 15},  // Leaf0ElecNegEtaU1: Raw Input
    {0xc80, 16},  // Leaf0ElecNegEtaU2: Sort Input
    {0xc83, 4},   // Leaf0ElecNegEtaU2: Sort Output
    {0xc84, 12},  // Leaf0ElecNegEtaU2: Raw Input
    // Wheel Pos-eta Jet FPGA
    {0x300, 27},  // WheelPosEtaJet: Input TrigPathA (Jet Sort)
    {0x301, 3},   // WheelPosEtaJet: Input TrigPathB (MissHt)
    {0x303, 6},   // WheelPosEtaJet: Output TrigPathA (Jet Sort)
    {0x305, 2},   // WheelPosEtaJet: Output TrigPathB (MissHt)
    {0x306,
     32},  // WheelPosEtaJet: Test (deprecated)  (Doesn't exist in V27.1 format, but does in V24 & V25, so keep for CRUZET2 data compatibility reasons)
    {0x307,
     4},  // WheelPosEtaJet: Info (deprecated)  (Doesn't exist in V27.1 format, but does in V24 & V25, so keep for CRUZET2 data compatibility reasons)
    // Wheel Pos-eta Energy FPGA
    {0x380, 21},  // WheelPosEtaEnergy: Input TrigPathA (Et)
    {0x381, 6},   // WheelPosEtaEnergy: Input TrigPathB (Ht)
    {0x383, 7},   // WheelPosEtaEnergy: Output TrigPathA (Et)
    {0x385, 2},   // WheelPosEtaEnergy: Output TrigPathB (Ht)
    {0x386, 32},  // WheelPosEtaEnergy: Test
    {0x387,
     6},  // WheelPosEtaEnergy: BX & Orbit Info   (Potential data incompatibility between V24/V25 where block length=4, and V27.1 where block length=6)
    // Wheel Neg-eta Jet FPGA
    {0x700, 27},  // WheelNegEtaJet: Input TrigPathA (Jet Sort)
    {0x701, 3},   // WheelNegEtaJet: Input TrigPathB (MissHt)
    {0x703, 6},   // WheelNegEtaJet: Output TrigPathA (Jet Sort)
    {0x705, 2},   // WheelNegEtaJet: Output TrigPathB (MissHt)
    {0x706,
     32},  // WheelNegEtaJet: Test (deprecated)  (Doesn't exist in V27.1 format, but does in V24 & V25, so keep for CRUZET2 data compatibility reasons)
    {0x707,
     4},  // WheelNegEtaJet: Info (deprecated)  (Doesn't exist in V27.1 format, but does in V24 & V25, so keep for CRUZET2 data compatibility reasons)
    // Wheel Neg-eta Energy FPGA
    {0x780, 21},  // WheelNegEtaEnergy: Input TrigPathA (Et)
    {0x781, 6},   // WheelNegEtaEnergy: Input TrigPathB (Ht)
    {0x783, 7},   // WheelNegEtaEnergy: Output TrigPathA (Et)
    {0x785, 2},   // WheelNegEtaEnergy: Output TrigPathB (Ht)
    {0x786, 32},  // WheelNegEtaEnergy: Test
    {0x787,
     6},  // WheelNegEtaEnergy: BX & Orbit Info   (Potential data incompatibility between V24/V25 where block length=4, and V27.1 where block length=6)
    // Jet Leaf FPGAs - Positive Eta
    {0x900, 13},  // Leaf1JetPosEtaU1: JF2 Input
    {0x901, 3},   // Leaf1JetPosEtaU1: JF2 Shared Received
    {0x902, 3},   // Leaf1JetPosEtaU1: JF2 Shared Sent
    {0x903, 10},  // Leaf1JetPosEtaU1: JF2 Output
    {0x904, 8},   // Leaf1JetPosEtaU1: JF2 Raw Input
    {0x908, 13},  // Leaf1JetPosEtaU1: JF3 Input
    {0x909, 3},   // Leaf1JetPosEtaU1: JF3 Shared Received
    {0x90a, 3},   // Leaf1JetPosEtaU1: JF3 Shared Sent
    {0x90b, 10},  // Leaf1JetPosEtaU1: JF3 Output
    {0x90c, 8},   // Leaf1JetPosEtaU1: JF3 Raw Input
    {0x980, 6},   // Leaf1JetPosEtaU2: Eta0 Input
    {0x984, 6},   // Leaf1JetPosEtaU2: Eta0 Raw Input
    {0x988, 13},  // Leaf1JetPosEtaU2: JF1 Input
    {0x989, 3},   // Leaf1JetPosEtaU2: JF1 Shared Received
    {0x98a, 3},   // Leaf1JetPosEtaU2: JF1 Shared Sent
    {0x98b, 10},  // Leaf1JetPosEtaU2: JF1 Output
    {0x98c, 8},   // Leaf1JetPosEtaU2: JF1 Raw Input
    {0xa00, 13},  // Leaf2JetPosEtaU1: JF2 Input
    {0xa01, 3},   // Leaf2JetPosEtaU1: JF2 Shared Received
    {0xa02, 3},   // Leaf2JetPosEtaU1: JF2 Shared Sent
    {0xa03, 10},  // Leaf2JetPosEtaU1: JF2 Output
    {0xa04, 8},   // Leaf2JetPosEtaU1: JF2 Raw Input
    {0xa08, 13},  // Leaf2JetPosEtaU1: JF3 Input
    {0xa09, 3},   // Leaf2JetPosEtaU1: JF3 Shared Received
    {0xa0a, 3},   // Leaf2JetPosEtaU1: JF3 Shared Sent
    {0xa0b, 10},  // Leaf2JetPosEtaU1: JF3 Output
    {0xa0c, 8},   // Leaf2JetPosEtaU1: JF3 Raw Input
    {0xa80, 6},   // Leaf2JetPosEtaU2: Eta0 Input
    {0xa84, 6},   // Leaf2JetPosEtaU2: Eta0 Raw Input
    {0xa88, 13},  // Leaf2JetPosEtaU2: JF1 Input
    {0xa89, 3},   // Leaf2JetPosEtaU2: JF1 Shared Received
    {0xa8a, 3},   // Leaf2JetPosEtaU2: JF1 Shared Sent
    {0xa8b, 10},  // Leaf2JetPosEtaU2: JF1 Output
    {0xa8c, 8},   // Leaf2JetPosEtaU2: JF1 Raw Input
    {0xb00, 13},  // Leaf3JetPosEtaU1: JF2 Input
    {0xb01, 3},   // Leaf3JetPosEtaU1: JF2 Shared Received
    {0xb02, 3},   // Leaf3JetPosEtaU1: JF2 Shared Sent
    {0xb03, 10},  // Leaf3JetPosEtaU1: JF2 Output
    {0xb04, 8},   // Leaf3JetPosEtaU1: JF2 Raw Input
    {0xb08, 13},  // Leaf3JetPosEtaU1: JF3 Input
    {0xb09, 3},   // Leaf3JetPosEtaU1: JF3 Shared Received
    {0xb0a, 3},   // Leaf3JetPosEtaU1: JF3 Shared Sent
    {0xb0b, 10},  // Leaf3JetPosEtaU1: JF3 Output
    {0xb0c, 8},   // Leaf3JetPosEtaU1: JF3 Raw Input
    {0xb80, 6},   // Leaf3JetPosEtaU2: Eta0 Input
    {0xb84, 6},   // Leaf3JetPosEtaU2: Eta0 Raw Input
    {0xb88, 13},  // Leaf3JetPosEtaU2: JF1 Input
    {0xb89, 3},   // Leaf3JetPosEtaU2: JF1 Shared Received
    {0xb8a, 3},   // Leaf3JetPosEtaU2: JF1 Shared Sent
    {0xb8b, 10},  // Leaf3JetPosEtaU2: JF1 Output
    {0xb8c, 8},   // Leaf3JetPosEtaU2: JF1 Raw Input
    // Jet Leaf FPGAs - Negative Eta
    {0xd00, 13},  // Leaf1JetNegEtaU1: JF2 Input
    {0xd01, 3},   // Leaf1JetNegEtaU1: JF2 Shared Received
    {0xd02, 3},   // Leaf1JetNegEtaU1: JF2 Shared Sent
    {0xd03, 10},  // Leaf1JetNegEtaU1: JF2 Output
    {0xd04, 8},   // Leaf1JetNegEtaU1: JF2 Raw Input
    {0xd08, 13},  // Leaf1JetNegEtaU1: JF3 Input
    {0xd09, 3},   // Leaf1JetNegEtaU1: JF3 Shared Received
    {0xd0a, 3},   // Leaf1JetNegEtaU1: JF3 Shared Sent
    {0xd0b, 10},  // Leaf1JetNegEtaU1: JF3 Output
    {0xd0c, 8},   // Leaf1JetNegEtaU1: JF3 Raw Input
    {0xd80, 6},   // Leaf1JetNegEtaU2: Eta0 Input
    {0xd84, 6},   // Leaf1JetNegEtaU2: Eta0 Raw Input
    {0xd88, 13},  // Leaf1JetNegEtaU2: JF1 Input
    {0xd89, 3},   // Leaf1JetNegEtaU2: JF1 Shared Received
    {0xd8a, 3},   // Leaf1JetNegEtaU2: JF1 Shared Sent
    {0xd8b, 10},  // Leaf1JetNegEtaU2: JF1 Output
    {0xd8c, 8},   // Leaf1JetNegEtaU2: JF1 Raw Input
    {0xe00, 13},  // Leaf2JetNegEtaU1: JF2 Input
    {0xe01, 3},   // Leaf2JetNegEtaU1: JF2 Shared Received
    {0xe02, 3},   // Leaf2JetNegEtaU1: JF2 Shared Sent
    {0xe03, 10},  // Leaf2JetNegEtaU1: JF2 Output
    {0xe04, 8},   // Leaf2JetNegEtaU1: JF2 Raw Input
    {0xe08, 13},  // Leaf2JetNegEtaU1: JF3 Input
    {0xe09, 3},   // Leaf2JetNegEtaU1: JF3 Shared Received
    {0xe0a, 3},   // Leaf2JetNegEtaU1: JF3 Shared Sent
    {0xe0b, 10},  // Leaf2JetNegEtaU1: JF3 Output
    {0xe0c, 8},   // Leaf2JetNegEtaU1: JF3 Raw Input
    {0xe80, 6},   // Leaf2JetNegEtaU2: Eta0 Input
    {0xe84, 6},   // Leaf2JetNegEtaU2: Eta0 Raw Input
    {0xe88, 13},  // Leaf2JetNegEtaU2: JF1 Input
    {0xe89, 3},   // Leaf2JetNegEtaU2: JF1 Shared Received
    {0xe8a, 3},   // Leaf2JetNegEtaU2: JF1 Shared Sent
    {0xe8b, 10},  // Leaf2JetNegEtaU2: JF1 Output
    {0xe8c, 8},   // Leaf2JetNegEtaU2: JF1 Raw Input
    {0xf00, 13},  // Leaf3JetNegEtaU1: JF2 Input
    {0xf01, 3},   // Leaf3JetNegEtaU1: JF2 Shared Received
    {0xf02, 3},   // Leaf3JetNegEtaU1: JF2 Shared Sent
    {0xf03, 10},  // Leaf3JetNegEtaU1: JF2 Output
    {0xf04, 8},   // Leaf3JetNegEtaU1: JF2 Raw Input
    {0xf08, 13},  // Leaf3JetNegEtaU1: JF3 Input
    {0xf09, 3},   // Leaf3JetNegEtaU1: JF3 Shared Received
    {0xf0a, 3},   // Leaf3JetNegEtaU1: JF3 Shared Sent
    {0xf0b, 10},  // Leaf3JetNegEtaU1: JF3 Output
    {0xf0c, 8},   // Leaf3JetNegEtaU1: JF3 Raw Input
    {0xf80, 6},   // Leaf3JetNegEtaU2: Eta0 Input
    {0xf84, 6},   // Leaf3JetNegEtaU2: Eta0 Raw Input
    {0xf88, 13},  // Leaf3JetNegEtaU2: JF1 Input
    {0xf89, 3},   // Leaf3JetNegEtaU2: JF1 Shared Received
    {0xf8a, 3},   // Leaf3JetNegEtaU2: JF1 Shared Sent
    {0xf8b, 10},  // Leaf3JetNegEtaU2: JF1 Output
    {0xf8c, 8}    // Leaf3JetNegEtaU2: JF1 Raw Input
};
 
/*** Setup BlockID to BlockName Map ***/
const GctFormatTranslateV38::BlockNameMap GctFormatTranslateV38::m_blockName = {
    // Miscellaneous Blocks
    {0x000, "NULL"},
    // ConcJet FPGA
    {0x580, "ConcJet: Input TrigPathA (Jet Cands)"},
    {0x581, "ConcJet: Input TrigPathB (HF Rings)"},
    {0x582, "ConcJet: Input TrigPathC (MissHt)"},
    {0x583, "ConcJet: Jet Cands and Counts Output to GT"},
    {0x587, "ConcJet: BX & Orbit Info"},
    // ConcElec FPGA
    {0x680, "ConcElec: Input TrigPathA (EM Cands)"},
    {0x681, "ConcElec: Input TrigPathB (Et Sums)"},
    {0x682, "ConcElec: Input TrigPathC (Ht Sums)"},
    {0x683, "ConcElec: EM Cands and Energy Sums Output to GT"},
    {0x686, "ConcElec: Test (GT Serdes Loopback)"},
    {0x687, "ConcElec: BX & Orbit Info"},
    // Electron Leaf FPGAs
    {0x800, "Leaf0ElecPosEtaU1: Sort Input"},
    {0x803, "Leaf0ElecPosEtaU1: Sort Output"},
    {0x804, "Leaf0ElecPosEtaU1: Raw Input"},
    {0x880, "Leaf0ElecPosEtaU2: Sort Input"},
    {0x883, "Leaf0ElecPosEtaU2: Sort Output"},
    {0x884, "Leaf0ElecPosEtaU2: Raw Input"},
    {0xc00, "Leaf0ElecNegEtaU1: Sort Input"},
    {0xc03, "Leaf0ElecNegEtaU1: Sort Output"},
    {0xc04, "Leaf0ElecNegEtaU1: Raw Input"},
    {0xc80, "Leaf0ElecNegEtaU2: Sort Input"},
    {0xc83, "Leaf0ElecNegEtaU2: Sort Output"},
    {0xc84, "Leaf0ElecNegEtaU2: Raw Input"},
    // Wheel Pos-eta Jet FPGA
    {0x300, "WheelPosEtaJet: Input TrigPathA (Jet Sort)"},
    {0x301, "WheelPosEtaJet: Input TrigPathB (MissHt)"},
    {0x303, "WheelPosEtaJet: Output TrigPathA (Jet Sort)"},
    {0x305, "WheelPosEtaJet: Output TrigPathB (MissHt)"},
    {0x306,
     "WheelPosEtaJet: Test (deprecated)"},  // (Doesn't exist in V27.1 format, but does in V24 & V25, so keep for CRUZET2 data compatibility reasons)
    {0x307,
     "WheelPosEtaJet: Info (deprecated)"},  // (Doesn't exist in V27.1 format, but does in V24 & V25, so keep for CRUZET2 data compatibility reasons)
    // Wheel Pos-eta Energy FPGA
    {0x380, "WheelPosEtaEnergy: Input TrigPathA (Et)"},
    {0x381, "WheelPosEtaEnergy: Input TrigPathB (Ht)"},
    {0x383, "WheelPosEtaEnergy: Output TrigPathA (Et)"},
    {0x385, "WheelPosEtaEnergy: Output TrigPathB (Ht)"},
    {0x386, "WheelPosEtaEnergy: Test"},
    {0x387, "WheelPosEtaEnergy: BX & Orbit Info"},
    // Wheel Neg-eta Jet FPGA
    {0x700, "WheelNegEtaJet: Input TrigPathA (Jet Sort)"},
    {0x701, "WheelNegEtaJet: Input TrigPathB (MissHt)"},
    {0x703, "WheelNegEtaJet: Output TrigPathA (Jet Sort)"},
    {0x705, "WheelNegEtaJet: Output TrigPathB (MissHt)"},
    {0x706,
     "WheelNegEtaJet: Test (deprecated)"},  // (Doesn't exist in V27.1 format, but does in V24 & V25, so keep for CRUZET2 data compatibility reasons)
    {0x707,
     "WheelNegEtaJet: Info (deprecated)"},  // (Doesn't exist in V27.1 format, but does in V24 & V25, so keep for CRUZET2 data compatibility reasons)
    // Wheel Neg-eta Energy FPGA
    {0x780, "WheelNegEtaEnergy: Input TrigPathA (Et)"},
    {0x781, "WheelNegEtaEnergy: Input TrigPathB (Ht)"},
    {0x783, "WheelNegEtaEnergy: Output TrigPathA (Et)"},
    {0x785, "WheelNegEtaEnergy: Output TrigPathB (Ht)"},
    {0x786, "WheelNegEtaEnergy: Test"},
    {0x787, "WheelNegEtaEnergy: BX & Orbit Info"},
    // Jet Leaf FPGAs - Positive Eta
    {0x900, "Leaf1JetPosEtaU1: JF2 Input"},
    {0x901, "Leaf1JetPosEtaU1: JF2 Shared Received"},
    {0x902, "Leaf1JetPosEtaU1: JF2 Shared Sent"},
    {0x903, "Leaf1JetPosEtaU1: JF2 Output"},
    {0x904, "Leaf1JetPosEtaU1: JF2 Raw Input"},
    {0x908, "Leaf1JetPosEtaU1: JF3 Input"},
    {0x909, "Leaf1JetPosEtaU1: JF3 Shared Received"},
    {0x90a, "Leaf1JetPosEtaU1: JF3 Shared Sent"},
    {0x90b, "Leaf1JetPosEtaU1: JF3 Output"},
    {0x90c, "Leaf1JetPosEtaU1: JF3 Raw Input"},
    {0x980, "Leaf1JetPosEtaU2: Eta0 Input"},  // Next Leaf Start
    {0x984, "Leaf1JetPosEtaU2: Eta0 Raw Input"},
    {0x988, "Leaf1JetPosEtaU2: JF1 Input"},
    {0x989, "Leaf1JetPosEtaU2: JF1 Shared Received"},
    {0x98a, "Leaf1JetPosEtaU2: JF1 Shared Sent"},
    {0x98b, "Leaf1JetPosEtaU2: JF1 Output"},
    {0x98c, "Leaf1JetPosEtaU2: JF1 Raw Input"},
    {0xa00, "Leaf2JetPosEtaU1: JF2 Input"},  // Next Leaf Start
    {0xa01, "Leaf2JetPosEtaU1: JF2 Shared Received"},
    {0xa02, "Leaf2JetPosEtaU1: JF2 Shared Sent"},
    {0xa03, "Leaf2JetPosEtaU1: JF2 Output"},
    {0xa04, "Leaf2JetPosEtaU1: JF2 Raw Input"},
    {0xa08, "Leaf2JetPosEtaU1: JF3 Input"},
    {0xa09, "Leaf2JetPosEtaU1: JF3 Shared Received"},
    {0xa0a, "Leaf2JetPosEtaU1: JF3 Shared Sent"},
    {0xa0b, "Leaf2JetPosEtaU1: JF3 Output"},
    {0xa0c, "Leaf2JetPosEtaU1: JF3 Raw Input"},
    {0xa80, "Leaf2JetPosEtaU2: Eta0 Input"},  // Next Leaf Start
    {0xa84, "Leaf2JetPosEtaU2: Eta0 Raw Input"},
    {0xa88, "Leaf2JetPosEtaU2: JF1 Input"},
    {0xa89, "Leaf2JetPosEtaU2: JF1 Shared Received"},
    {0xa8a, "Leaf2JetPosEtaU2: JF1 Shared Sent"},
    {0xa8b, "Leaf2JetPosEtaU2: JF1 Output"},
    {0xa8c, "Leaf2JetPosEtaU2: JF1 Raw Input"},
    {0xb00, "Leaf3JetPosEtaU1: JF2 Input"},  // Next Leaf Start
    {0xb01, "Leaf3JetPosEtaU1: JF2 Shared Received"},
    {0xb02, "Leaf3JetPosEtaU1: JF2 Shared Sent"},
    {0xb03, "Leaf3JetPosEtaU1: JF2 Output"},
    {0xb04, "Leaf3JetPosEtaU1: JF2 Raw Input"},
    {0xb08, "Leaf3JetPosEtaU1: JF3 Input"},
    {0xb09, "Leaf3JetPosEtaU1: JF3 Shared Received"},
    {0xb0a, "Leaf3JetPosEtaU1: JF3 Shared Sent"},
    {0xb0b, "Leaf3JetPosEtaU1: JF3 Output"},
    {0xb0c, "Leaf3JetPosEtaU1: JF3 Raw Input"},
    {0xb80, "Leaf3JetPosEtaU2: Eta0 Input"},  // Next Leaf Start
    {0xb84, "Leaf3JetPosEtaU2: Eta0 Raw Input"},
    {0xb88, "Leaf3JetPosEtaU2: JF1 Input"},
    {0xb89, "Leaf3JetPosEtaU2: JF1 Shared Received"},
    {0xb8a, "Leaf3JetPosEtaU2: JF1 Shared Sent"},
    {0xb8b, "Leaf3JetPosEtaU2: JF1 Output"},
    {0xb8c, "Leaf3JetPosEtaU2: JF1 Raw Input"},
    // Jet Leaf FPGAs - Negative Eta
    {0xd00, "Leaf1JetNegEtaU1: JF2 Input"},  // START OF NEG ETA JET LEAVES
    {0xd01, "Leaf1JetNegEtaU1: JF2 Shared Received"},
    {0xd02, "Leaf1JetNegEtaU1: JF2 Shared Sent"},
    {0xd03, "Leaf1JetNegEtaU1: JF2 Output"},
    {0xd04, "Leaf1JetNegEtaU1: JF2 Raw Input"},
    {0xd08, "Leaf1JetNegEtaU1: JF3 Input"},
    {0xd09, "Leaf1JetNegEtaU1: JF3 Shared Received"},
    {0xd0a, "Leaf1JetNegEtaU1: JF3 Shared Sent"},
    {0xd0b, "Leaf1JetNegEtaU1: JF3 Output"},
    {0xd0c, "Leaf1JetNegEtaU1: JF3 Raw Input"},
    {0xd80, "Leaf1JetNegEtaU2: Eta0 Input"},  // Next Leaf Start
    {0xd84, "Leaf1JetNegEtaU2: Eta0 Raw Input"},
    {0xd88, "Leaf1JetNegEtaU2: JF1 Input"},
    {0xd89, "Leaf1JetNegEtaU2: JF1 Shared Received"},
    {0xd8a, "Leaf1JetNegEtaU2: JF1 Shared Sent"},
    {0xd8b, "Leaf1JetNegEtaU2: JF1 Output"},
    {0xd8c, "Leaf1JetNegEtaU2: JF1 Raw Input"},
    {0xe00, "Leaf2JetNegEtaU1: JF2 Input"},  // Next Leaf Start
    {0xe01, "Leaf2JetNegEtaU1: JF2 Shared Received"},
    {0xe02, "Leaf2JetNegEtaU1: JF2 Shared Sent"},
    {0xe03, "Leaf2JetNegEtaU1: JF2 Output"},
    {0xe04, "Leaf2JetNegEtaU1: JF2 Raw Input"},
    {0xe08, "Leaf2JetNegEtaU1: JF3 Input"},
    {0xe09, "Leaf2JetNegEtaU1: JF3 Shared Received"},
    {0xe0a, "Leaf2JetNegEtaU1: JF3 Shared Sent"},
    {0xe0b, "Leaf2JetNegEtaU1: JF3 Output"},
    {0xe0c, "Leaf2JetNegEtaU1: JF3 Raw Input"},
    {0xe80, "Leaf2JetNegEtaU2: Eta0 Input"},  // Next Leaf Start
    {0xe84, "Leaf2JetNegEtaU2: Eta0 Raw Input"},
    {0xe88, "Leaf2JetNegEtaU2: JF1 Input"},
    {0xe89, "Leaf2JetNegEtaU2: JF1 Shared Received"},
    {0xe8a, "Leaf2JetNegEtaU2: JF1 Shared Sent"},
    {0xe8b, "Leaf2JetNegEtaU2: JF1 Output"},
    {0xe8c, "Leaf2JetNegEtaU2: JF1 Raw Input"},
    {0xf00, "Leaf3JetNegEtaU1: JF2 Input"},  // Next Leaf Start
    {0xf01, "Leaf3JetNegEtaU1: JF2 Shared Received"},
    {0xf02, "Leaf3JetNegEtaU1: JF2 Shared Sent"},
    {0xf03, "Leaf3JetNegEtaU1: JF2 Output"},
    {0xf04, "Leaf3JetNegEtaU1: JF2 Raw Input"},
    {0xf08, "Leaf3JetNegEtaU1: JF3 Input"},
    {0xf09, "Leaf3JetNegEtaU1: JF3 Shared Received"},
    {0xf0a, "Leaf3JetNegEtaU1: JF3 Shared Sent"},
    {0xf0b, "Leaf3JetNegEtaU1: JF3 Output"},
    {0xf0c, "Leaf3JetNegEtaU1: JF3 Raw Input"},
    {0xf80, "Leaf3JetNegEtaU2: Eta0 Input"},  // Next Leaf Start
    {0xf84, "Leaf3JetNegEtaU2: Eta0 Raw Input"},
    {0xf88, "Leaf3JetNegEtaU2: JF1 Input"},
    {0xf89, "Leaf3JetNegEtaU2: JF1 Shared Received"},
    {0xf8a, "Leaf3JetNegEtaU2: JF1 Shared Sent"},
    {0xf8b, "Leaf3JetNegEtaU2: JF1 Output"},
    {0xf8c, "Leaf3JetNegEtaU2: JF1 Raw Input"}};
 
/*** Setup BlockID to Unpack-Function Map ***/
const GctFormatTranslateV38::BlockIdToUnpackFnMap GctFormatTranslateV38::m_blockUnpackFn = {
    // Miscellaneous Blocks
    {0x000, &GctFormatTranslateV38::blockDoNothing},  // NULL
    // ConcJet FPGA
    {0x580, &GctFormatTranslateV38::blockToGctTrigObjects},            // ConcJet: Input TrigPathA (Jet Cands)
    {0x581, &GctFormatTranslateV38::blockToGctInternRingSums},         // ConcJet: Input TrigPathB (HF Rings)
    {0x582, &GctFormatTranslateV38::blockToGctInternHtMissPostWheel},  // ConcJet: Input TrigPathC (MissHt)
    {0x583, &GctFormatTranslateV38::blockToGctJetCandsAndCounts},      // ConcJet: Jet Cands and Counts Output to GT
    {0x587, &GctFormatTranslateV38::blockDoNothing},                   // ConcJet: BX & Orbit Info
    // ConcElec FPGA
    {0x680, &GctFormatTranslateV38::blockToGctInternEmCand},          // ConcElec: Input TrigPathA (EM Cands)
    {0x681, &GctFormatTranslateV38::blockToGctInternEtSums},          // ConcElec: Input TrigPathB (Et Sums)
    {0x682, &GctFormatTranslateV38::blockToGctInternEtSums},          // ConcElec: Input TrigPathC (Ht Sums)
    {0x683, &GctFormatTranslateV38::blockToGctEmCandsAndEnergySums},  // ConcElec: EM Cands and Energy Sums Output to GT
    {0x686, &GctFormatTranslateV38::blockDoNothing},                  // ConcElec: Test (GT Serdes Loopback)
    {0x687, &GctFormatTranslateV38::blockDoNothing},                  // ConcElec: BX & Orbit Info
    // Electron Leaf FPGAs
    {0x800, &GctFormatTranslateV38::blockToGctInternEmCand},       // Leaf0ElecPosEtaU1: Sort Input
    {0x803, &GctFormatTranslateV38::blockToGctInternEmCand},       // Leaf0ElecPosEtaU1: Sort Output
    {0x804, &GctFormatTranslateV38::blockToFibresAndToRctEmCand},  // Leaf0ElecPosEtaU1: Raw Input
    {0x880, &GctFormatTranslateV38::blockToGctInternEmCand},       // Leaf0ElecPosEtaU2: Sort Input
    {0x883, &GctFormatTranslateV38::blockToGctInternEmCand},       // Leaf0ElecPosEtaU2: Sort Output
    {0x884, &GctFormatTranslateV38::blockToFibresAndToRctEmCand},  // Leaf0ElecPosEtaU2: Raw Input
    {0xc00, &GctFormatTranslateV38::blockToGctInternEmCand},       // Leaf0ElecNegEtaU1: Sort Input
    {0xc03, &GctFormatTranslateV38::blockToGctInternEmCand},       // Leaf0ElecNegEtaU1: Sort Output
    {0xc04, &GctFormatTranslateV38::blockToFibresAndToRctEmCand},  // Leaf0ElecNegEtaU1: Raw Input
    {0xc80, &GctFormatTranslateV38::blockToGctInternEmCand},       // Leaf0ElecNegEtaU2: Sort Input
    {0xc83, &GctFormatTranslateV38::blockToGctInternEmCand},       // Leaf0ElecNegEtaU2: Sort Output
    {0xc84, &GctFormatTranslateV38::blockToFibresAndToRctEmCand},  // Leaf0ElecNegEtaU2: Raw Input
    // Wheel Pos-eta Jet FPGA
    {0x300, &GctFormatTranslateV38::blockToGctJetClusterMinimal},      // WheelPosEtaJet: Input TrigPathA (Jet Sort)
    {0x301, &GctFormatTranslateV38::blockToGctInternHtMissPreWheel},   // WheelPosEtaJet: Input TrigPathB (MissHt)
    {0x303, &GctFormatTranslateV38::blockToGctTrigObjects},            // WheelPosEtaJet: Output TrigPathA (Jet Sort)
    {0x305, &GctFormatTranslateV38::blockToGctInternHtMissPostWheel},  // WheelPosEtaJet: Output TrigPathB (MissHt)
    {0x306,
     &GctFormatTranslateV38::
         blockDoNothing},  // WheelPosEtaJet: Test (deprecated)  (Doesn't exist in V27.1 format, but does in V24 & V25, so keep for CRUZET2 data compatibility reasons)
    {0x307,
     &GctFormatTranslateV38::
         blockDoNothing},  // WheelPosEtaJet: Info (deprecated)  (Doesn't exist in V27.1 format, but does in V24 & V25, so keep for CRUZET2 data compatibility reasons)
    // Wheel Pos-eta Energy FPGA
    {0x380,
     &GctFormatTranslateV38::blockToGctWheelInputInternEtAndRingSums},  // WheelPosEtaEnergy: Input TrigPathA (Et)
    {0x381, &GctFormatTranslateV38::blockToGctInternEtSums},            // WheelPosEtaEnergy: Input TrigPathB (Ht)
    {0x383,
     &GctFormatTranslateV38::blockToGctWheelOutputInternEtAndRingSums},  // WheelPosEtaEnergy: Output TrigPathA (Et)
    {0x385, &GctFormatTranslateV38::blockToGctInternEtSums},             // WheelPosEtaEnergy: Output TrigPathB (Ht)
    {0x386, &GctFormatTranslateV38::blockDoNothing},                     // WheelPosEtaEnergy: Test
    {0x387,
     &GctFormatTranslateV38::
         blockDoNothing},  // WheelPosEtaEnergy: BX & Orbit Info   (Potential data incompatibility between V24/V25 where block length=4, and V27.1 where block length=6)
    // Wheel Neg-eta Jet FPGA
    {0x700, &GctFormatTranslateV38::blockToGctJetClusterMinimal},      // WheelNegEtaJet: Input TrigPathA (Jet Sort)
    {0x701, &GctFormatTranslateV38::blockToGctInternHtMissPreWheel},   // WheelNegEtaJet: Input TrigPathB (MissHt)
    {0x703, &GctFormatTranslateV38::blockToGctTrigObjects},            // WheelNegEtaJet: Output TrigPathA (Jet Sort)
    {0x705, &GctFormatTranslateV38::blockToGctInternHtMissPostWheel},  // WheelNegEtaJet: Output TrigPathB (MissHt)
    {0x706,
     &GctFormatTranslateV38::
         blockDoNothing},  // WheelNegEtaJet: Test (deprecated)  (Doesn't exist in V27.1 format, but does in V24 & V25, so keep for CRUZET2 data compatibility reasons)
    {0x707,
     &GctFormatTranslateV38::
         blockDoNothing},  // WheelNegEtaJet: Info (deprecated)  (Doesn't exist in V27.1 format, but does in V24 & V25, so keep for CRUZET2 data compatibility reasons)
    // Wheel Neg-eta Energy FPGA
    {0x780,
     &GctFormatTranslateV38::blockToGctWheelInputInternEtAndRingSums},  // WheelNegEtaEnergy: Input TrigPathA (Et)
    {0x781, &GctFormatTranslateV38::blockToGctInternEtSums},            // WheelNegEtaEnergy: Input TrigPathB (Ht)
    {0x783,
     &GctFormatTranslateV38::blockToGctWheelOutputInternEtAndRingSums},  // WheelNegEtaEnergy: Output TrigPathA (Et)
    {0x785, &GctFormatTranslateV38::blockToGctInternEtSums},             // WheelNegEtaEnergy: Output TrigPathB (Ht)
    {0x786, &GctFormatTranslateV38::blockDoNothing},                     // WheelNegEtaEnergy: Test
    {0x787,
     &GctFormatTranslateV38::
         blockDoNothing},  // WheelNegEtaEnergy: BX & Orbit Info   (Potential data incompatibility between V24/V25 where block length=4, and V27.1 where block length=6)
    // Jet Leaf FPGAs - Positive Eta
    {0x900, &GctFormatTranslateV38::blockToRctCaloRegions},                // Leaf1JetPosEtaU1: JF2 Input
    {0x901, &GctFormatTranslateV38::blockToGctJetPreCluster},              // Leaf1JetPosEtaU1: JF2 Shared Received
    {0x902, &GctFormatTranslateV38::blockToGctJetPreCluster},              // Leaf1JetPosEtaU1: JF2 Shared Sent
    {0x903, &GctFormatTranslateV38::blockToGctInternEtSumsAndJetCluster},  // Leaf1JetPosEtaU1: JF2 Output
    {0x904, &GctFormatTranslateV38::blockToFibres},                        // Leaf1JetPosEtaU1: JF2 Raw Input
    {0x908, &GctFormatTranslateV38::blockToRctCaloRegions},                // Leaf1JetPosEtaU1: JF3 Input
    {0x909, &GctFormatTranslateV38::blockToGctJetPreCluster},              // Leaf1JetPosEtaU1: JF3 Shared Received
    {0x90a, &GctFormatTranslateV38::blockToGctJetPreCluster},              // Leaf1JetPosEtaU1: JF3 Shared Sent
    {0x90b, &GctFormatTranslateV38::blockToGctInternEtSumsAndJetCluster},  // Leaf1JetPosEtaU1: JF3 Output
    {0x90c, &GctFormatTranslateV38::blockToFibres},                        // Leaf1JetPosEtaU1: JF3 Raw Input
    {0x980, &GctFormatTranslateV38::blockDoNothing},                       // Leaf1JetPosEtaU2: Eta0 Input
    {0x984, &GctFormatTranslateV38::blockToFibres},                        // Leaf1JetPosEtaU2: Eta0 Raw Input
    {0x988, &GctFormatTranslateV38::blockToRctCaloRegions},                // Leaf1JetPosEtaU2: JF1 Input
    {0x989, &GctFormatTranslateV38::blockToGctJetPreCluster},              // Leaf1JetPosEtaU2: JF1 Shared Received
    {0x98a, &GctFormatTranslateV38::blockToGctJetPreCluster},              // Leaf1JetPosEtaU2: JF1 Shared Sent
    {0x98b, &GctFormatTranslateV38::blockToGctInternEtSumsAndJetCluster},  // Leaf1JetPosEtaU2: JF1 Output
    {0x98c, &GctFormatTranslateV38::blockToFibres},                        // Leaf1JetPosEtaU2: JF1 Raw Input
    {0xa00, &GctFormatTranslateV38::blockToRctCaloRegions},                // Leaf2JetPosEtaU1: JF2 Input
    {0xa01, &GctFormatTranslateV38::blockToGctJetPreCluster},              // Leaf2JetPosEtaU1: JF2 Shared Received
    {0xa02, &GctFormatTranslateV38::blockToGctJetPreCluster},              // Leaf2JetPosEtaU1: JF2 Shared Sent
    {0xa03, &GctFormatTranslateV38::blockToGctInternEtSumsAndJetCluster},  // Leaf2JetPosEtaU1: JF2 Output
    {0xa04, &GctFormatTranslateV38::blockToFibres},                        // Leaf2JetPosEtaU1: JF2 Raw Input
    {0xa08, &GctFormatTranslateV38::blockToRctCaloRegions},                // Leaf2JetPosEtaU1: JF3 Input
    {0xa09, &GctFormatTranslateV38::blockToGctJetPreCluster},              // Leaf2JetPosEtaU1: JF3 Shared Received
    {0xa0a, &GctFormatTranslateV38::blockToGctJetPreCluster},              // Leaf2JetPosEtaU1: JF3 Shared Sent
    {0xa0b, &GctFormatTranslateV38::blockToGctInternEtSumsAndJetCluster},  // Leaf2JetPosEtaU1: JF3 Output
    {0xa0c, &GctFormatTranslateV38::blockToFibres},                        // Leaf2JetPosEtaU1: JF3 Raw Input
    {0xa80, &GctFormatTranslateV38::blockDoNothing},                       // Leaf2JetPosEtaU2: Eta0 Input
    {0xa84, &GctFormatTranslateV38::blockToFibres},                        // Leaf2JetPosEtaU2: Eta0 Raw Input
    {0xa88, &GctFormatTranslateV38::blockToRctCaloRegions},                // Leaf2JetPosEtaU2: JF1 Input
    {0xa89, &GctFormatTranslateV38::blockToGctJetPreCluster},              // Leaf2JetPosEtaU2: JF1 Shared Received
    {0xa8a, &GctFormatTranslateV38::blockToGctJetPreCluster},              // Leaf2JetPosEtaU2: JF1 Shared Sent
    {0xa8b, &GctFormatTranslateV38::blockToGctInternEtSumsAndJetCluster},  // Leaf2JetPosEtaU2: JF1 Output
    {0xa8c, &GctFormatTranslateV38::blockToFibres},                        // Leaf2JetPosEtaU2: JF1 Raw Input
    {0xb00, &GctFormatTranslateV38::blockToRctCaloRegions},                // Leaf3JetPosEtaU1: JF2 Input
    {0xb01, &GctFormatTranslateV38::blockToGctJetPreCluster},              // Leaf3JetPosEtaU1: JF2 Shared Received
    {0xb02, &GctFormatTranslateV38::blockToGctJetPreCluster},              // Leaf3JetPosEtaU1: JF2 Shared Sent
    {0xb03, &GctFormatTranslateV38::blockToGctInternEtSumsAndJetCluster},  // Leaf3JetPosEtaU1: JF2 Output
    {0xb04, &GctFormatTranslateV38::blockToFibres},                        // Leaf3JetPosEtaU1: JF2 Raw Input
    {0xb08, &GctFormatTranslateV38::blockToRctCaloRegions},                // Leaf3JetPosEtaU1: JF3 Input
    {0xb09, &GctFormatTranslateV38::blockToGctJetPreCluster},              // Leaf3JetPosEtaU1: JF3 Shared Received
    {0xb0a, &GctFormatTranslateV38::blockToGctJetPreCluster},              // Leaf3JetPosEtaU1: JF3 Shared Sent
    {0xb0b, &GctFormatTranslateV38::blockToGctInternEtSumsAndJetCluster},  // Leaf3JetPosEtaU1: JF3 Output
    {0xb0c, &GctFormatTranslateV38::blockToFibres},                        // Leaf3JetPosEtaU1: JF3 Raw Input
    {0xb80, &GctFormatTranslateV38::blockDoNothing},                       // Leaf3JetPosEtaU2: Eta0 Input
    {0xb84, &GctFormatTranslateV38::blockToFibres},                        // Leaf3JetPosEtaU2: Eta0 Raw Input
    {0xb88, &GctFormatTranslateV38::blockToRctCaloRegions},                // Leaf3JetPosEtaU2: JF1 Input
    {0xb89, &GctFormatTranslateV38::blockToGctJetPreCluster},              // Leaf3JetPosEtaU2: JF1 Shared Received
    {0xb8a, &GctFormatTranslateV38::blockToGctJetPreCluster},              // Leaf3JetPosEtaU2: JF1 Shared Sent
    {0xb8b, &GctFormatTranslateV38::blockToGctInternEtSumsAndJetCluster},  // Leaf3JetPosEtaU2: JF1 Output
    {0xb8c, &GctFormatTranslateV38::blockToFibres},                        // Leaf3JetPosEtaU2: JF1 Raw Input
    // Jet Leaf FPGAs - Negative Eta
    {0xd00, &GctFormatTranslateV38::blockToRctCaloRegions},                // Leaf1JetNegEtaU1: JF2 Input
    {0xd01, &GctFormatTranslateV38::blockToGctJetPreCluster},              // Leaf1JetNegEtaU1: JF2 Shared Received
    {0xd02, &GctFormatTranslateV38::blockToGctJetPreCluster},              // Leaf1JetNegEtaU1: JF2 Shared Sent
    {0xd03, &GctFormatTranslateV38::blockToGctInternEtSumsAndJetCluster},  // Leaf1JetNegEtaU1: JF2 Output
    {0xd04, &GctFormatTranslateV38::blockToFibres},                        // Leaf1JetNegEtaU1: JF2 Raw Input
    {0xd08, &GctFormatTranslateV38::blockToRctCaloRegions},                // Leaf1JetNegEtaU1: JF3 Input
    {0xd09, &GctFormatTranslateV38::blockToGctJetPreCluster},              // Leaf1JetNegEtaU1: JF3 Shared Received
    {0xd0a, &GctFormatTranslateV38::blockToGctJetPreCluster},              // Leaf1JetNegEtaU1: JF3 Shared Sent
    {0xd0b, &GctFormatTranslateV38::blockToGctInternEtSumsAndJetCluster},  // Leaf1JetNegEtaU1: JF3 Output
    {0xd0c, &GctFormatTranslateV38::blockToFibres},                        // Leaf1JetNegEtaU1: JF3 Raw Input
    {0xd80, &GctFormatTranslateV38::blockDoNothing},                       // Leaf1JetNegEtaU2: Eta0 Input
    {0xd84, &GctFormatTranslateV38::blockToFibres},                        // Leaf1JetNegEtaU2: Eta0 Raw Input
    {0xd88, &GctFormatTranslateV38::blockToRctCaloRegions},                // Leaf1JetNegEtaU2: JF1 Input
    {0xd89, &GctFormatTranslateV38::blockToGctJetPreCluster},              // Leaf1JetNegEtaU2: JF1 Shared Received
    {0xd8a, &GctFormatTranslateV38::blockToGctJetPreCluster},              // Leaf1JetNegEtaU2: JF1 Shared Sent
    {0xd8b, &GctFormatTranslateV38::blockToGctInternEtSumsAndJetCluster},  // Leaf1JetNegEtaU2: JF1 Output
    {0xd8c, &GctFormatTranslateV38::blockToFibres},                        // Leaf1JetNegEtaU2: JF1 Raw Input
    {0xe00, &GctFormatTranslateV38::blockToRctCaloRegions},                // Leaf2JetNegEtaU1: JF2 Input
    {0xe01, &GctFormatTranslateV38::blockToGctJetPreCluster},              // Leaf2JetNegEtaU1: JF2 Shared Received
    {0xe02, &GctFormatTranslateV38::blockToGctJetPreCluster},              // Leaf2JetNegEtaU1: JF2 Shared Sent
    {0xe03, &GctFormatTranslateV38::blockToGctInternEtSumsAndJetCluster},  // Leaf2JetNegEtaU1: JF2 Output
    {0xe04, &GctFormatTranslateV38::blockToFibres},                        // Leaf2JetNegEtaU1: JF2 Raw Input
    {0xe08, &GctFormatTranslateV38::blockToRctCaloRegions},                // Leaf2JetNegEtaU1: JF3 Input
    {0xe09, &GctFormatTranslateV38::blockToGctJetPreCluster},              // Leaf2JetNegEtaU1: JF3 Shared Received
    {0xe0a, &GctFormatTranslateV38::blockToGctJetPreCluster},              // Leaf2JetNegEtaU1: JF3 Shared Sent
    {0xe0b, &GctFormatTranslateV38::blockToGctInternEtSumsAndJetCluster},  // Leaf2JetNegEtaU1: JF3 Output
    {0xe0c, &GctFormatTranslateV38::blockToFibres},                        // Leaf2JetNegEtaU1: JF3 Raw Input
    {0xe80, &GctFormatTranslateV38::blockDoNothing},                       // Leaf2JetNegEtaU2: Eta0 Input
    {0xe84, &GctFormatTranslateV38::blockToFibres},                        // Leaf2JetNegEtaU2: Eta0 Raw Input
    {0xe88, &GctFormatTranslateV38::blockToRctCaloRegions},                // Leaf2JetNegEtaU2: JF1 Input
    {0xe89, &GctFormatTranslateV38::blockToGctJetPreCluster},              // Leaf2JetNegEtaU2: JF1 Shared Received
    {0xe8a, &GctFormatTranslateV38::blockToGctJetPreCluster},              // Leaf2JetNegEtaU2: JF1 Shared Sent
    {0xe8b, &GctFormatTranslateV38::blockToGctInternEtSumsAndJetCluster},  // Leaf2JetNegEtaU2: JF1 Output
    {0xe8c, &GctFormatTranslateV38::blockToFibres},                        // Leaf2JetNegEtaU2: JF1 Raw Input
    {0xf00, &GctFormatTranslateV38::blockToRctCaloRegions},                // Leaf3JetNegEtaU1: JF2 Input
    {0xf01, &GctFormatTranslateV38::blockToGctJetPreCluster},              // Leaf3JetNegEtaU1: JF2 Shared Received
    {0xf02, &GctFormatTranslateV38::blockToGctJetPreCluster},              // Leaf3JetNegEtaU1: JF2 Shared Sent
    {0xf03, &GctFormatTranslateV38::blockToGctInternEtSumsAndJetCluster},  // Leaf3JetNegEtaU1: JF2 Output
    {0xf04, &GctFormatTranslateV38::blockToFibres},                        // Leaf3JetNegEtaU1: JF2 Raw Input
    {0xf08, &GctFormatTranslateV38::blockToRctCaloRegions},                // Leaf3JetNegEtaU1: JF3 Input
    {0xf09, &GctFormatTranslateV38::blockToGctJetPreCluster},              // Leaf3JetNegEtaU1: JF3 Shared Received
    {0xf0a, &GctFormatTranslateV38::blockToGctJetPreCluster},              // Leaf3JetNegEtaU1: JF3 Shared Sent
    {0xf0b, &GctFormatTranslateV38::blockToGctInternEtSumsAndJetCluster},  // Leaf3JetNegEtaU1: JF3 Output
    {0xf0c, &GctFormatTranslateV38::blockToFibres},                        // Leaf3JetNegEtaU1: JF3 Raw Input
    {0xf80, &GctFormatTranslateV38::blockDoNothing},                       // Leaf3JetNegEtaU2: Eta0 Input
    {0xf84, &GctFormatTranslateV38::blockToFibres},                        // Leaf3JetNegEtaU2: Eta0 Raw Input
    {0xf88, &GctFormatTranslateV38::blockToRctCaloRegions},                // Leaf3JetNegEtaU2: JF1 Input
    {0xf89, &GctFormatTranslateV38::blockToGctJetPreCluster},              // Leaf3JetNegEtaU2: JF1 Shared Received
    {0xf8a, &GctFormatTranslateV38::blockToGctJetPreCluster},              // Leaf3JetNegEtaU2: JF1 Shared Sent
    {0xf8b, &GctFormatTranslateV38::blockToGctInternEtSumsAndJetCluster},  // Leaf3JetNegEtaU2: JF1 Output
    {0xf8c, &GctFormatTranslateV38::blockToFibres},                        // Leaf3JetNegEtaU2: JF1 Raw Input
};
 
/*** Setup RCT Em Crate Map ***/
const GctFormatTranslateV38::BlkToRctCrateMap GctFormatTranslateV38::m_rctEmCrate = {
    {0x804, 13}, {0x884, 9}, {0xc04, 4}, {0xc84, 0}};
 
/*** Setup RCT jet crate map. ***/
const GctFormatTranslateV38::BlkToRctCrateMap GctFormatTranslateV38::m_rctJetCrate = {
    {0x900, 9},   // PosEta Leaf 1 JF2
    {0x908, 10},  // PosEta Leaf 1 JF3
    {0x988, 17},  // PosEta Leaf 1 JF1
    {0xa00, 12},  // PosEta Leaf 2 JF2
    {0xa08, 13},  // PosEta Leaf 2 JF3
    {0xa88, 11},  // PosEta Leaf 2 JF1
    {0xb00, 15},  // PosEta Leaf 3 JF2
    {0xb08, 16},  // PosEta Leaf 3 JF3
    {0xb88, 14},  // PosEta Leaf 3 JF1
    {0xd00, 0},   // NegEta Leaf 1 JF2
    {0xd08, 1},   // NegEta Leaf 1 JF3
    {0xd88, 8},   // NegEta Leaf 1 JF1
    {0xe00, 3},   // NegEta Leaf 2 JF2
    {0xe08, 4},   // NegEta Leaf 2 JF3
    {0xe88, 2},   // NegEta Leaf 2 JF1
    {0xf00, 6},   // NegEta Leaf 3 JF2
    {0xf08, 7},   // NegEta Leaf 3 JF3
    {0xf88, 5}    // NegEta Leaf 3 JF1
};
 
/*** Setup Block ID map for pipeline payload positions of isolated Internal EM Cands. ***/
const GctFormatTranslateV38::BlockIdToEmCandIsoBoundMap GctFormatTranslateV38::m_internEmIsoBounds = {
    {0x680, IsoBoundaryPair(8, 15)},
    {0x800, IsoBoundaryPair(0, 9)},
    {0x803, IsoBoundaryPair(0, 1)},
    {0x880, IsoBoundaryPair(0, 7)},
    {0x883, IsoBoundaryPair(0, 1)},
    {0xc00, IsoBoundaryPair(0, 9)},
    {0xc03, IsoBoundaryPair(0, 1)},
    {0xc80, IsoBoundaryPair(0, 7)},
    {0xc83, IsoBoundaryPair(0, 1)}};
 
// PUBLIC METHODS
 
GctFormatTranslateV38::GctFormatTranslateV38(bool hltMode,
                                             bool unpackSharedRegions,
                                             unsigned numberOfGctSamplesToUnpack,
                                             unsigned numberOfRctSamplesToUnpack)
    : GctFormatTranslateBase(hltMode, unpackSharedRegions),
      m_numberOfGctSamplesToUnpack(numberOfGctSamplesToUnpack),
      m_numberOfRctSamplesToUnpack(numberOfRctSamplesToUnpack) {}
 
GctFormatTranslateV38::~GctFormatTranslateV38() {}
 
GctBlockHeader GctFormatTranslateV38::generateBlockHeader(const unsigned char* data) const {
  // Turn the four 8-bit header words into the full 32-bit header.
  uint32_t hdr = data[0] + (data[1] << 8) + (data[2] << 16) + (data[3] << 24);
 
  //  Bit mapping of V35 header:
  //  --------------------------
  //  11:0   => block_id  Unique pipeline identifier.
  //   - 3:0    =>> pipe_id There can be up to 16 different pipelines per FPGA.
  //   - 6:4    =>> reserved  Do not use yet. Set to zero.
  //   - 11:7   =>> fpga geograpical add  The VME geographical address of the FPGA.
  //  15:12  => event_id  Determined locally.  Not reset by Resync.
  //  19:16  => number_of_time_samples  If time samples 15 or more then value = 15.
  //  31:20  => event_bcid  The bunch crossing the data was recorded.
 
  unsigned blockId = hdr & 0xfff;
  unsigned blockLength = 0;  // Set to zero until we know it's a valid block
  unsigned nSamples = (hdr >> 16) & 0xf;
  unsigned bxId = (hdr >> 20) & 0xfff;
  unsigned eventId = (hdr >> 12) & 0xf;
  bool valid = (blockLengthMap().find(blockId) != blockLengthMap().end());
 
  if (valid) {
    blockLength = blockLengthMap().find(blockId)->second;
  }
 
  return GctBlockHeader(blockId, blockLength, nSamples, bxId, eventId, valid);
}
 
// conversion
bool GctFormatTranslateV38::convertBlock(const unsigned char* data, const GctBlockHeader& hdr) {
  // if the block has no time samples, don't bother with it.
  if (hdr.nSamples() < 1) {
    return true;
  }
 
  if (!checkBlock(hdr)) {
    return false;
  }  // Check the block to see if it's possible to unpack.
 
  // The header validity check above will protect against
  // the map::find() method returning the end of the map,
  // assuming the block header definitions are up-to-date.
  (this->*m_blockUnpackFn.find(hdr.blockId())->second)(data,
                                                       hdr);  // Calls the correct unpack function, based on block ID.
 
  return true;
}
 
// PROTECTED METHODS
 
uint32_t GctFormatTranslateV38::generateRawHeader(const uint32_t blockId,
                                                  const uint32_t nSamples,
                                                  const uint32_t bxId,
                                                  const uint32_t eventId) const {
  //  Bit mapping of V35 header:
  //  --------------------------
  //  11:0   => block_id  Unique pipeline identifier.
  //   - 3:0    =>> pipe_id There can be up to 16 different pipelines per FPGA.
  //   - 6:4    =>> reserved  Do not use yet. Set to zero.
  //   - 11:7   =>> fpga geograpical add  The VME geographical address of the FPGA.
  //  15:12  => event_id  Determined locally.  Not reset by Resync.
  //  19:16  => number_of_time_samples  If time samples 15 or more then value = 15.
  //  31:20  => event_bxId  The bunch crossing the data was recorded.
 
  return ((bxId & 0xfff) << 20) | ((nSamples & 0xf) << 16) | ((eventId & 0xf) << 12) | (blockId & 0xfff);
}
 
// PRIVATE METHODS
 
// Throughout the code, bx refers to the hardware definition of time-samples
// ie. if 5 time samples are unpacked, they are bx=0, 1, 2, 3, 4 in order
// what is written to digi would be -2, -1, 0, +1, +2
 
// Output EM Candidates unpacking
void GctFormatTranslateV38::blockToGctEmCandsAndEnergySums(const unsigned char* d, const GctBlockHeader& hdr) {
  const unsigned int id = hdr.blockId();
  const unsigned int nSamples = hdr.nSamples();
 
  // Re-interpret pointer.  p16 will be pointing at the 16 bit word that
  // contains the rank0 non-isolated electron of the zeroth time-sample.
  const uint16_t* p16 = reinterpret_cast<const uint16_t*>(d);
 
  // UNPACK EM CANDS
 
  const unsigned int emCandCategoryOffset =
      nSamples * 4;  // Offset to jump from the non-iso electrons to the isolated ones.
  const unsigned int timeSampleOffset = nSamples * 2;  // Offset to jump to next candidate pair in the same time-sample.
 
  unsigned int samplesToUnpack =
      std::min(nSamples, m_numberOfGctSamplesToUnpack);  // Unpack as many as asked for if they are in the raw data
  unsigned int centralSample =
      (unsigned)std::ceil((double)nSamples / 2.) - 1;  // think this works when nSamples is even, need to check!!!
  unsigned int firstSample = centralSample - (unsigned)std::ceil((double)samplesToUnpack / 2.) + 1;
  unsigned int lastSample = centralSample + (unsigned)(samplesToUnpack / 2);
 
  LogDebug("GCT") << "Unpacking output EM.  Central sample=" << centralSample << " first=" << firstSample
                  << " last=" << lastSample;
 
  for (unsigned int iso = 0; iso < 2; ++iso)  // loop over non-iso/iso candidate pairs
  {
    bool isoFlag = (iso == 1);
 
    // Get the correct collection to put them in.
    L1GctEmCandCollection* em;
    if (isoFlag) {
      em = colls()->gctIsoEm();
    } else {
      em = colls()->gctNonIsoEm();
    }
 
    for (unsigned int bx = firstSample; bx <= lastSample; ++bx)  // loop over samples to be unpacked
    {
      // cand0Offset will give the offset on p16 to get the rank 0 candidate
      // of the correct category and timesample.
      const unsigned int cand0Offset = iso * emCandCategoryOffset + bx * 2;
 
      em->push_back(L1GctEmCand(p16[cand0Offset], isoFlag, id, 0, (int)bx - (int)centralSample));  // rank0 electron
      em->push_back(L1GctEmCand(
          p16[cand0Offset + timeSampleOffset], isoFlag, id, 1, (int)bx - (int)centralSample));         // rank1 electron
      em->push_back(L1GctEmCand(p16[cand0Offset + 1], isoFlag, id, 2, (int)bx - (int)centralSample));  // rank2 electron
      em->push_back(L1GctEmCand(
          p16[cand0Offset + timeSampleOffset + 1], isoFlag, id, 3, (int)bx - (int)centralSample));  // rank3 electron
 
      LogDebug("GCT") << "Unpacked a bunch of EG.  iso=" << iso << " bx=" << bx << std::endl;
    }
  }
 
  p16 += emCandCategoryOffset * 2;  // Move the pointer over the data we've already unpacked.
 
  // UNPACK ENERGY SUMS
 
  for (unsigned int bx = firstSample; bx <= lastSample; ++bx)  // loop over all time samples
  {
    const unsigned int offset = bx * 2;
    colls()->gctEtTot()->push_back(L1GctEtTotal(p16[offset], (int)bx - (int)centralSample));    // Et total
    colls()->gctEtHad()->push_back(L1GctEtHad(p16[offset + 1], (int)bx - (int)centralSample));  // Et hadronic
  }
 
  p16 += nSamples * 2;
 
  // 32-bit pointer for getting Missing Et.
  const uint32_t* p32 = reinterpret_cast<const uint32_t*>(p16);
 
  for (unsigned int bx = firstSample; bx <= lastSample; ++bx) {
    colls()->gctEtMiss()->push_back(L1GctEtMiss(p32[bx], (int)bx - (int)centralSample));  // Et Miss
    LogDebug("GCT") << "Unpacked energy sums bx=" << bx << std::endl;
  }
}
 
void GctFormatTranslateV38::blockToGctJetCandsAndCounts(const unsigned char* d, const GctBlockHeader& hdr) {
  const unsigned int id = hdr.blockId();         // Capture block ID.
  const unsigned int nSamples = hdr.nSamples();  // Number of time-samples.
 
  // Re-interpret block payload pointer to 16 bits so it sees one candidate at a time.
  // p16 points to the start of the block payload, at the rank0 tau jet candidate.
  const uint16_t* p16 = reinterpret_cast<const uint16_t*>(d);
 
  // UNPACK JET CANDS
 
  const unsigned int jetCandCategoryOffset = nSamples * 4;  // Offset to jump from one jet category to the next.
  const unsigned int timeSampleOffset = nSamples * 2;  // Offset to jump to next candidate pair in the same time-sample.
 
  unsigned int samplesToUnpack =
      std::min(nSamples, m_numberOfGctSamplesToUnpack);  // Unpack as many as asked for if they are in the raw data
  unsigned int centralSample =
      (unsigned)std::ceil((double)nSamples / 2.) - 1;  // think this works when nSamples is even, need to check!!!
  unsigned int firstSample = centralSample - (unsigned)std::ceil((double)samplesToUnpack / 2.) + 1;
  unsigned int lastSample = centralSample + (unsigned)(samplesToUnpack / 2);
 
  LogDebug("GCT") << "Unpacking output Jets. Samples to unpack=" << samplesToUnpack << " central=" << centralSample
                  << " first=" << firstSample << " last=" << lastSample;
 
  // Loop over the different catagories of jets
  for (unsigned int iCat = 0; iCat < NUM_JET_CATEGORIES; ++iCat) {
    L1GctJetCandCollection* const jets = gctJets(iCat);
    assert(jets->empty());  // The supplied vector should be empty.
 
    bool tauflag = (iCat == TAU_JETS);
    bool forwardFlag = (iCat == FORWARD_JETS);
 
    // Loop over the different timesamples (bunch crossings).
    for (unsigned int bx = firstSample; bx <= lastSample; ++bx) {
      // cand0Offset will give the offset on p16 to get the rank 0 Jet Cand of the correct category and timesample.
      const unsigned int cand0Offset = iCat * jetCandCategoryOffset + bx * 2;
 
      // Rank 0 Jet.
      jets->push_back(L1GctJetCand(p16[cand0Offset], tauflag, forwardFlag, id, 0, (int)bx - (int)centralSample));
      // Rank 1 Jet.
      jets->push_back(
          L1GctJetCand(p16[cand0Offset + timeSampleOffset], tauflag, forwardFlag, id, 1, (int)bx - (int)centralSample));
      // Rank 2 Jet.
      jets->push_back(L1GctJetCand(p16[cand0Offset + 1], tauflag, forwardFlag, id, 2, (int)bx - (int)centralSample));
      // Rank 3 Jet.
      jets->push_back(L1GctJetCand(
          p16[cand0Offset + timeSampleOffset + 1], tauflag, forwardFlag, id, 3, (int)bx - (int)centralSample));
    }
  }
 
  p16 += NUM_JET_CATEGORIES * jetCandCategoryOffset;  // Move the pointer over the data we've already unpacked.
 
  // NOW UNPACK: HFBitCounts, HFRingEtSums and Missing Ht
 
  // Re-interpret block payload pointer to 32 bits so it sees six jet counts at a time.
  const uint32_t* p32 = reinterpret_cast<const uint32_t*>(p16);
 
  for (unsigned int bx = firstSample; bx <= lastSample; ++bx)  // loop over all time samples
  {
    // Channel 0 carries both HF counts and sums
    colls()->gctHfBitCounts()->push_back(
        L1GctHFBitCounts::fromConcHFBitCounts(id, 6, (int)bx - (int)centralSample, p32[bx]));
    colls()->gctHfRingEtSums()->push_back(
        L1GctHFRingEtSums::fromConcRingSums(id, 6, (int)bx - (int)centralSample, p32[bx]));
 
    // Channel 1 carries Missing HT.
    colls()->gctHtMiss()->push_back(L1GctHtMiss(p32[bx + nSamples], (int)bx - (int)centralSample));
  }
}
 
// Internal EM Candidates unpacking
void GctFormatTranslateV38::blockToGctInternEmCand(const unsigned char* d, const GctBlockHeader& hdr) {
  // Don't want to do this in HLT optimisation mode!
  if (hltMode()) {
    LogDebug("GCT") << "HLT mode - skipping unpack of internal EM Cands";
    return;
  }
 
  unsigned int id = hdr.blockId();
  unsigned int nSamples = hdr.nSamples();
  unsigned int numCandPairs = hdr.blockLength();
 
  // Debug assertion to prevent problems if definitions not up to date.
  auto found = internEmIsoBounds().find(id);
  assert(found != internEmIsoBounds().end());
 
  unsigned int lowerIsoPairBound = found->second.first;
  unsigned int upperIsoPairBound = found->second.second;
 
  // Re-interpret pointer to 16 bits so it sees one candidate at a time.
  const uint16_t* p = reinterpret_cast<const uint16_t*>(d);
 
  // Loop over timesamples (i.e. bunch crossings)
  for (unsigned int bx = 0; bx < nSamples; ++bx) {
    // Loop over candidate pairs (i.e. each iteration unpacks a pair of candidates)
    for (unsigned int candPair = 0; candPair < numCandPairs; ++candPair) {
      // Is the candidate electron pair an isolated pair or not?
      bool iso = ((candPair >= lowerIsoPairBound) && (candPair <= upperIsoPairBound));
 
      // Loop over the two electron candidates in each pair
      for (unsigned int i = 0; i < 2; ++i) {
        unsigned offset = 2 * (bx + candPair * nSamples) + i;
        uint16_t candRaw = p[offset];
        colls()->gctInternEm()->push_back(L1GctInternEmCand(candRaw, iso, id, candPair * 2 + i, bx));
      }
    }
  }
}
 
// Input EM Candidates unpacking
// this is the last time I deal the RCT bit assignment travesty!!!
void GctFormatTranslateV38::blockToRctEmCand(const unsigned char* d, const GctBlockHeader& hdr) {
  // Don't want to do this in HLT optimisation mode!
  if (hltMode()) {
    LogDebug("GCT") << "HLT mode - skipping unpack of RCT EM Cands";
    return;
  }
 
  unsigned int id = hdr.blockId();
  unsigned int nSamples = hdr.nSamples();
  unsigned int length = hdr.blockLength();
 
  // re-interpret pointer
  const uint16_t* p = reinterpret_cast<const uint16_t*>(d);
 
  // arrays of source card data
  uint16_t sfp[2][4];  // [ cycle ] [ SFP ]
  uint16_t eIsoRank[4];
  uint16_t eIsoCard[4];
  uint16_t eIsoRgn[4];
  uint16_t eNonIsoRank[4];
  uint16_t eNonIsoCard[4];
  uint16_t eNonIsoRgn[4];
  uint16_t MIPbits[7][2];
  uint16_t QBits[7][2];
 
  unsigned int bx = 0;
 
  auto found = rctEmCrateMap().find(id);
  assert(found != rctEmCrateMap().end());
  // loop over crates
  for (unsigned int crate = found->second; crate < found->second + length / 3; ++crate) {
    // read SC SFP words
    for (unsigned short iSfp = 0; iSfp < 4; ++iSfp) {
      for (unsigned short cyc = 0; cyc < 2; ++cyc) {
        if (iSfp == 0) {
          sfp[cyc][iSfp] = 0;
        }       // muon bits
        else {  // EM candidate
          sfp[cyc][iSfp] = *p;
          ++p;
        }
      }
      p = p + 2 * (nSamples - 1);
    }
 
    // fill SC arrays
    srcCardRouting().SFPtoEMU(eIsoRank, eIsoCard, eIsoRgn, eNonIsoRank, eNonIsoCard, eNonIsoRgn, MIPbits, QBits, sfp);
 
    // create EM cands
    for (unsigned short int i = 0; i < 4; ++i) {
      colls()->rctEm()->push_back(L1CaloEmCand(eIsoRank[i], eIsoRgn[i], eIsoCard[i], crate, true, i, bx));
    }
    for (unsigned short int i = 0; i < 4; ++i) {
      colls()->rctEm()->push_back(L1CaloEmCand(eNonIsoRank[i], eNonIsoRgn[i], eNonIsoCard[i], crate, false, i, bx));
    }
  }
}
 
// Input RCT region unpacking
void GctFormatTranslateV38::blockToRctCaloRegions(const unsigned char* d, const GctBlockHeader& hdr) {
  // Don't want to do this in HLT optimisation mode!
  if (hltMode()) {
    LogDebug("GCT") << "HLT mode - skipping unpack of RCT Regions";
    return;
  }
 
  unsigned int id = hdr.blockId();
  unsigned int nSamples = hdr.nSamples();
  unsigned int length = hdr.blockLength();
 
  // Debug assertion to prevent problems if definitions not up to date.
  auto found = rctJetCrateMap().find(id);
  assert(found != rctJetCrateMap().end());
 
  // get crate (need this to get ieta and iphi)
  unsigned int crate = found->second;
 
  // re-interpret pointer
  const uint16_t* p = reinterpret_cast<const uint16_t*>(d);
 
  // eta and phi
  unsigned int ieta;
  unsigned int iphi;
 
  for (unsigned int i = 0; i < length; ++i) {
    for (uint16_t bx = 0; bx < nSamples; ++bx) {
      // First figure out eta and phi
      if (crate < 9) {  // negative eta
        ieta = 12 - i;
        iphi = 2 * ((11 - crate) % 9);
      } else {  // positive eta
        ieta = 9 + i;
        iphi = 2 * ((20 - crate) % 9);
      }
 
      // Skip the first four regions (i.e. where i<2) which are duplicates (shared data).
      if (i > 1) {
        // First region is phi=0
        colls()->rctCalo()->push_back(L1CaloRegion::makeRegionFromUnpacker(*p, ieta, iphi, id, i, bx));
        ++p;
        // Second region is phi=1
        if (iphi > 0) {
          iphi -= 1;
        } else {
          iphi = 17;
        }
        colls()->rctCalo()->push_back(L1CaloRegion::makeRegionFromUnpacker(*p, ieta, iphi, id, i, bx));
        ++p;
      }
      // Unpack the shared data if asked for debugging
      else if (unpackSharedRegions()) {
        // First region is phi=0
        colls()->rctCalo()->push_back(L1CaloRegion::makeRegionFromUnpacker(*p, ieta, iphi, id, i, bx));
        ++p;
        // Second region is phi=1
        if (iphi > 0) {
          iphi -= 1;
        } else {
          iphi = 17;
        }
        colls()->rctCalo()->push_back(L1CaloRegion::makeRegionFromUnpacker(*p, ieta, iphi, id, i, bx));
        ++p;
 
      } else {  // Skip the shared data
        ++p;
        ++p;
      }
    }
  }
}
 
// Fibre unpacking
void GctFormatTranslateV38::blockToFibres(const unsigned char* d, const GctBlockHeader& hdr) {
  // Don't want to do this in HLT optimisation mode!
  if (hltMode()) {
    LogDebug("GCT") << "HLT mode - skipping unpack of GCT Fibres";
    return;
  }
 
  unsigned int id = hdr.blockId();
  unsigned int nSamples = hdr.nSamples();
  unsigned int length = hdr.blockLength();
 
  // re-interpret pointer
  const uint32_t* p = reinterpret_cast<const uint32_t*>(d);
 
  for (unsigned int i = 0; i < length; ++i) {
    for (unsigned int bx = 0; bx < nSamples; ++bx) {
      colls()->gctFibres()->push_back(L1GctFibreWord(*p, id, i, bx));
      ++p;
    }
  }
}
 
void GctFormatTranslateV38::blockToFibresAndToRctEmCand(const unsigned char* d, const GctBlockHeader& hdr) {
  this->blockToRctEmCand(d, hdr);
  this->blockToFibres(d, hdr);
}
 
void GctFormatTranslateV38::blockToGctInternEtSums(const unsigned char* d, const GctBlockHeader& hdr) {
  // Don't want to do this in HLT optimisation mode!
 
  if (hltMode()) {
    LogDebug("GCT") << "HLT mode - skipping unpack of internal Et Sums";
    return;
  }
 
  unsigned int id = hdr.blockId();
  unsigned int nSamples = hdr.nSamples();
  unsigned int length = hdr.blockLength();
 
  // Re-interpret pointer to 32 bits
  const uint32_t* p = reinterpret_cast<const uint32_t*>(d);
 
  for (unsigned int i = 0; i < length; ++i) {
    // Loop over timesamples (i.e. bunch crossings)
    for (unsigned int bx = 0; bx < nSamples; ++bx) {
      colls()->gctInternEtSums()->push_back(L1GctInternEtSum::fromTotalEtOrHt(id, i, bx, *p));
      ++p;
    }
  }
}
 
void GctFormatTranslateV38::blockToGctInternEtSumsAndJetCluster(const unsigned char* d, const GctBlockHeader& hdr) {
  // Don't want to do this in HLT optimisation mode!
  if (hltMode()) {
    LogDebug("GCT") << "HLT mode - skipping unpack of internal Jet Cands";
    return;
  }
 
  unsigned int id = hdr.blockId();
  unsigned int nSamples = hdr.nSamples();
  unsigned int length = hdr.blockLength();
 
  // Re-interpret pointer to 32 bits
  const uint32_t* p = reinterpret_cast<const uint32_t*>(d);
 
  for (unsigned int i = 0; i < length; ++i) {
    // Loop over timesamples (i.e. bunch crossings)
    for (unsigned int bx = 0; bx < nSamples; ++bx) {
      if (i < 2)
        colls()->gctInternEtSums()->push_back(L1GctInternEtSum::fromJetMissEt(id, i, bx, *p));
      if (i == 3) {
        colls()->gctInternEtSums()->push_back(L1GctInternEtSum::fromJetTotEt(id, i, bx, *p));
        colls()->gctInternEtSums()->push_back(L1GctInternEtSum::fromJetTotHt(id, i, bx, *p));
      }
      if (i > 4)
        colls()->gctInternJets()->push_back(L1GctInternJetData::fromJetCluster(L1CaloRegionDetId(0, 0), id, i, bx, *p));
      ++p;
    }
  }
}
 
void GctFormatTranslateV38::blockToGctTrigObjects(const unsigned char* d, const GctBlockHeader& hdr) {
  // Don't want to do this in HLT optimisation mode!
  if (hltMode()) {
    LogDebug("GCT") << "HLT mode - skipping unpack of internal Jet Cands";
    return;
  }
 
  unsigned int id = hdr.blockId();
  unsigned int nSamples = hdr.nSamples();
  unsigned int length = hdr.blockLength();
 
  // Re-interpret pointer to 16 bits so it sees one candidate at a time.
  const uint16_t* p = reinterpret_cast<const uint16_t*>(d);
 
  for (unsigned int i = 0; i < length; ++i) {
    // Loop over timesamples (i.e. bunch crossings)
    for (unsigned int bx = 0; bx < nSamples; ++bx) {
      colls()->gctInternJets()->push_back(
          L1GctInternJetData::fromGctTrigObject(L1CaloRegionDetId(0, 0), id, i, bx, *p));
      ++p;
      colls()->gctInternJets()->push_back(
          L1GctInternJetData::fromGctTrigObject(L1CaloRegionDetId(0, 0), id, i, bx, *p));
      ++p;
    }
  }
}
 
void GctFormatTranslateV38::blockToGctJetClusterMinimal(const unsigned char* d, const GctBlockHeader& hdr) {
  // Don't want to do this in HLT optimisation mode!
  if (hltMode()) {
    LogDebug("GCT") << "HLT mode - skipping unpack of internal Jet Cands";
    return;
  }
 
  unsigned int id = hdr.blockId();
  unsigned int nSamples = hdr.nSamples();
  unsigned int length = hdr.blockLength();
 
  // Re-interpret pointer to 16 bits so it sees one candidate at a time.
  const uint16_t* p = reinterpret_cast<const uint16_t*>(d);
 
  for (unsigned int i = 0; i < length; ++i) {
    // Loop over timesamples (i.e. bunch crossings)
    for (unsigned int bx = 0; bx < nSamples; ++bx) {
      colls()->gctInternJets()->push_back(
          L1GctInternJetData::fromJetClusterMinimal(L1CaloRegionDetId(0, 0), id, i, bx, *p));
      ++p;
      colls()->gctInternJets()->push_back(
          L1GctInternJetData::fromJetClusterMinimal(L1CaloRegionDetId(0, 0), id, i, bx, *p));
      ++p;
    }
  }
}
 
void GctFormatTranslateV38::blockToGctJetPreCluster(const unsigned char* d, const GctBlockHeader& hdr) {
  // Don't want to do this in HLT optimisation mode!
  if (hltMode()) {
    LogDebug("GCT") << "HLT mode - skipping unpack of internal Jet Cands";
    return;
  }
 
  unsigned int id = hdr.blockId();
  unsigned int nSamples = hdr.nSamples();
  unsigned int length = hdr.blockLength();
 
  // Re-interpret pointer to 16 bits so it sees one candidate at a time.
  const uint16_t* p = reinterpret_cast<const uint16_t*>(d);
 
  for (unsigned int i = 0; i < length; ++i) {
    // Loop over timesamples (i.e. bunch crossings)
    for (unsigned int bx = 0; bx < nSamples; ++bx) {
      colls()->gctInternJets()->push_back(
          L1GctInternJetData::fromJetPreCluster(L1CaloRegionDetId(0, 0), id, i, bx, *p));
      ++p;
      colls()->gctInternJets()->push_back(
          L1GctInternJetData::fromJetPreCluster(L1CaloRegionDetId(0, 0), id, i, bx, *p));
      ++p;
    }
  }
}
 
void GctFormatTranslateV38::blockToGctInternRingSums(const unsigned char* d, const GctBlockHeader& hdr) {
  // Don't want to do this in HLT optimisation mode!
  if (hltMode()) {
    LogDebug("GCT") << "HLT mode - skipping unpack of internal HF ring data";
    return;
  }
 
  unsigned int id = hdr.blockId();
  unsigned int nSamples = hdr.nSamples();
  unsigned int length = hdr.blockLength();
 
  // Re-interpret pointer to 32 bits
  const uint32_t* p = reinterpret_cast<const uint32_t*>(d);
 
  for (unsigned int i = 0; i < length / 2; ++i) {
    // Loop over timesamples (i.e. bunch crossings)
    for (unsigned int bx = 0; bx < nSamples; ++bx) {
      colls()->gctInternHFData()->push_back(L1GctInternHFData::fromConcRingSums(id, i, bx, *p));
      ++p;
    }
    for (unsigned int bx = 0; bx < nSamples; ++bx) {
      colls()->gctInternHFData()->push_back(L1GctInternHFData::fromConcBitCounts(id, i, bx, *p));
      ++p;
    }
  }
}
 
void GctFormatTranslateV38::blockToGctWheelInputInternEtAndRingSums(const unsigned char* d, const GctBlockHeader& hdr) {
  // Don't want to do this in HLT optimisation mode!
  if (hltMode()) {
    LogDebug("GCT") << "HLT mode - skipping unpack of wheel input internal Et sums and HF ring data";
    return;
  }
 
  unsigned int id = hdr.blockId();
  unsigned int nSamples = hdr.nSamples();
  unsigned int length = hdr.blockLength();
 
  // Re-interpret pointer to 32 bits
  const uint32_t* p = reinterpret_cast<const uint32_t*>(d);
 
  for (unsigned int i = 0; i < length; ++i) {
    // Loop over timesamples (i.e. bunch crossings)
    for (unsigned int bx = 0; bx < nSamples; ++bx) {
      if (i < 3) {
        colls()->gctInternEtSums()->push_back(L1GctInternEtSum::fromTotalEtOrHt(id, i, bx, *p));
      } else if (i > 2 && i < 9) {
        colls()->gctInternEtSums()->push_back(L1GctInternEtSum::fromMissEtxOrEty(id, i, bx, *p));
      } else if (i > 8 && i < 15) {
        colls()->gctInternHFData()->push_back(L1GctInternHFData::fromWheelRingSums(id, i, bx, *p));
      } else if (i > 14) {
        colls()->gctInternHFData()->push_back(L1GctInternHFData::fromWheelBitCounts(id, i, bx, *p));
      }
      ++p;
    }
  }
}
 
void GctFormatTranslateV38::blockToGctWheelOutputInternEtAndRingSums(const unsigned char* d,
                                                                     const GctBlockHeader& hdr) {
  // Don't want to do this in HLT optimisation mode!
  if (hltMode()) {
    LogDebug("GCT") << "HLT mode - skipping unpack of wheel output internal Et sums and HF ring data";
    return;
  }
 
  unsigned int id = hdr.blockId();
  unsigned int nSamples = hdr.nSamples();
  unsigned int length = hdr.blockLength();
 
  // Re-interpret pointer to 32 bits
  const uint32_t* p = reinterpret_cast<const uint32_t*>(d);
 
  for (unsigned int i = 0; i < length; ++i) {
    // Loop over timesamples (i.e. bunch crossings)
    for (unsigned int bx = 0; bx < nSamples; ++bx) {
      if (i < 1) {
        colls()->gctInternEtSums()->push_back(L1GctInternEtSum::fromTotalEtOrHt(id, i, bx, *p));
      } else if (i > 0 && i < 3) {
        colls()->gctInternEtSums()->push_back(L1GctInternEtSum::fromMissEtxOrEty(id, i, bx, *p));
      } else if (i > 2 && i < 5) {
        colls()->gctInternHFData()->push_back(L1GctInternHFData::fromWheelRingSums(id, i, bx, *p));
      } else if (i > 4) {
        colls()->gctInternHFData()->push_back(L1GctInternHFData::fromWheelBitCounts(id, i, bx, *p));
      }
      ++p;
    }
  }
}
 
void GctFormatTranslateV38::blockToGctInternHtMissPreWheel(const unsigned char* d, const GctBlockHeader& hdr) {
  // Don't want to do this in HLT optimisation mode!
  if (hltMode()) {
    LogDebug("GCT") << "HLT mode - skipping unpack of pre-wheel internal Missing Ht data";
    return;
  }
 
  unsigned int id = hdr.blockId();
  unsigned int nSamples = hdr.nSamples();
  unsigned int length = hdr.blockLength();
 
  // Re-interpret pointer to 32 bits
  const uint32_t* p = reinterpret_cast<const uint32_t*>(d);
 
  for (unsigned int iLength = 0; iLength < length; ++iLength) {
    // Loop over timesamples (i.e. bunch crossings)
    for (unsigned int bx = 0; bx < nSamples; ++bx) {
      colls()->gctInternHtMiss()->push_back(L1GctInternHtMiss::unpackerMissHtxHty(id, iLength, bx, *p));
      ++p;
    }
  }
}
 
void GctFormatTranslateV38::blockToGctInternHtMissPostWheel(const unsigned char* d, const GctBlockHeader& hdr) {
  // Don't want to do this in HLT optimisation mode!
  if (hltMode()) {
    LogDebug("GCT") << "HLT mode - skipping unpack of post-wheel internal Missing Ht data";
    return;
  }
 
  unsigned int id = hdr.blockId();
  unsigned int nSamples = hdr.nSamples();
  unsigned int length = hdr.blockLength();
 
  // Re-interpret pointer to 32 bits
  const uint32_t* p = reinterpret_cast<const uint32_t*>(d);
 
  for (unsigned int iLength = 0; iLength < length; ++iLength) {
    // Loop over timesamples (i.e. bunch crossings)
    for (unsigned int bx = 0; bx < nSamples; ++bx) {
      if (iLength % 2) {
        colls()->gctInternHtMiss()->push_back(L1GctInternHtMiss::unpackerMissHty(id, iLength, bx, *p));
      }  // Hty on odd numbers
      else {
        colls()->gctInternHtMiss()->push_back(L1GctInternHtMiss::unpackerMissHtx(id, iLength, bx, *p));
      }  // Htx on even numbers
      ++p;
    }
  }
}
 
//  LocalWords:  rctJetCrate