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#include <L1MuDTTrackAssembler.h>
Public Member Functions | |
| int | address (int id, int stat) const |
| get address of a single station of selected track candidate | |
| L1MuDTAddressArray | address (int id) const |
| get address-array of selected track candidate | |
| bool | isEmpty (int id) const |
| is it a valid Track Class? | |
| L1MuDTTrackAssembler (const L1MuDTSectorProcessor &) | |
| constructor | |
| void | print () const |
| print result of Track Assembler | |
| virtual void | reset () |
| reset Track Assembler | |
| virtual void | run () |
| run Track Assembler | |
| const std::bitset< 4 > & | trackBitMap (int id) const |
| return bitmap of found track | |
| TrackClass | trackClass (int id) const |
| return Track Class of found track | |
| virtual | ~L1MuDTTrackAssembler () |
| destructor | |
Private Member Functions | |
| void | runAddressAssignment1 (int global, int group) |
| run the first Address Assignment Sub-Unit | |
| void | runAddressAssignment2 (int global, int group) |
| run the second Address Assignment Sub-Unit | |
| void | runEncoderSubUnit1 (unsigned &global, unsigned &group, unsigned &priority) |
| run the first Priority Encoder Sub-Unit | |
| void | runEncoderSubUnit2 (unsigned &global, unsigned &group, unsigned &priority) |
| run the second Priority Encoder Sub-Unit | |
Static Private Member Functions | |
| static unsigned int | addressEncoder12 (const std::bitset< 12 > &input) |
| 12 bit address encoder | |
| static unsigned int | addressEncoder12s (const std::bitset< 12 > &input) |
| special 12 bit address encoder | |
| static std::bitset< 56 > | getCancelationTable (unsigned int) |
| cancel Out Table | |
| static unsigned int | priorityEncoder12 (const std::bitset< 12 > &input) |
| 12 bit priority encoder | |
| static unsigned int | priorityEncoder21 (const std::bitset< 21 > &input) |
| 21 bit priority encoder | |
| static unsigned int | priorityEncoder22 (const std::bitset< 22 > &input) |
| 22 bit priority encoder | |
| static unsigned int | priorityEncoder4 (const std::bitset< 4 > &input) |
| 4 bit priority encoder | |
| static unsigned long | subBitset56 (const std::bitset< 56 > &input, int pos, int length) |
| get sub-bitmap of a 56-bit word | |
| static unsigned long | subBitset68 (const std::bitset< 68 > &input, int pos, int length) |
| get sub-bitmap of a 68-bit word | |
Private Attributes | |
| const L1MuDTSectorProcessor & | m_sp |
| L1MuDTAddressArray | m_theAddresses [2] |
| std::bitset< 4 > | m_theBitMaps [2] |
| unsigned int | m_theLastAddress [68] |
| unsigned int | m_theLastAddressI [12] |
| std::bitset< 68 > | m_thePriorityTable1 |
| std::bitset< 56 > | m_thePriorityTable2 |
| TrackClass | m_theTCs [2] |
Track Assembler:
The Track Assembler gets the 18 Bitmap tables from the Quality Sorter Unit and links the corresponding track segments to full tracks
(this version corresponds to the VHDL model b_sts_7 version 7 )
N. Neumeister CERN EP
Definition at line 51 of file L1MuDTTrackAssembler.h.
| L1MuDTTrackAssembler::L1MuDTTrackAssembler | ( | const L1MuDTSectorProcessor & | sp | ) |
| L1MuDTTrackAssembler::~L1MuDTTrackAssembler | ( | ) | [virtual] |
| int L1MuDTTrackAssembler::address | ( | int | id, |
| int | stat | ||
| ) | const [inline] |
get address of a single station of selected track candidate
Definition at line 80 of file L1MuDTTrackAssembler.h.
References errorMatrix2Lands_multiChannel::id, m_theAddresses, and L1MuDTAddressArray::station().
Referenced by L1MuDTAssignmentUnit::run().
{ return m_theAddresses[id].station(stat); }
| L1MuDTAddressArray L1MuDTTrackAssembler::address | ( | int | id | ) | const [inline] |
get address-array of selected track candidate
Definition at line 83 of file L1MuDTTrackAssembler.h.
References errorMatrix2Lands_multiChannel::id, and m_theAddresses.
{ return m_theAddresses[id]; }
| unsigned int L1MuDTTrackAssembler::addressEncoder12 | ( | const std::bitset< 12 > & | input | ) | [static, private] |
| unsigned int L1MuDTTrackAssembler::addressEncoder12s | ( | const std::bitset< 12 > & | input | ) | [static, private] |
special 12 bit address encoder
Definition at line 1027 of file L1MuDTTrackAssembler.cc.
References i, and query::result.
Referenced by run().
| bitset< 56 > L1MuDTTrackAssembler::getCancelationTable | ( | unsigned int | p | ) | [static, private] |
cancel Out Table
Definition at line 1080 of file L1MuDTTrackAssembler.cc.
References b.
Referenced by run().
{
// Cancellation Table
// Each 0 in this Table means a sub-track of the
// previous found Track
switch ( p ) {
case 67 : { bitset<56> b(string("00000111111100000111000001110000011100000111010101010101")); return b; break; }
case 66 : { bitset<56> b(string("00001011111100000111000001110000101100001011010101010110")); return b; break; }
case 65 : { bitset<56> b(string("00001101010100000111000001110000110100001101010101010111")); return b; break; }
case 64 : { bitset<56> b(string("00001110101000000111000001110000111000001110010101010111")); return b; break; }
case 63 : { bitset<56> b(string("01110000111100001011000010110000011101110000010101101001")); return b; break; }
case 62 : { bitset<56> b(string("10110000111100001011000010110000101110110000010101101010")); return b; break; }
case 61 : { bitset<56> b(string("11010000111100001011000010110000110111010000010101101011")); return b; break; }
case 60 : { bitset<56> b(string("11100000111100001011000010110000111011100000010101101011")); return b; break; }
case 59 : { bitset<56> b(string("11011101000100001101000011010000110111011101010101111111")); return b; break; }
case 58 : { bitset<56> b(string("11101110001000001101000011010000111011101110010101111111")); return b; break; }
case 57 : { bitset<56> b(string("11011101010000001110000011100000110111011101010101111111")); return b; break; }
case 56 : { bitset<56> b(string("11101110100000001110000011100000111011101110010101111111")); return b; break; }
case 55 : { bitset<56> b(string("00000000000001110000011100000111000000000111101010010101")); return b; break; }
case 54 : { bitset<56> b(string("00000000000001110000011100001011000000001011101010010110")); return b; break; }
case 53 : { bitset<56> b(string("00000000000001110000011100001101000000001101101010010111")); return b; break; }
case 52 : { bitset<56> b(string("00000000000001110000011100001110000000001110101010010111")); return b; break; }
case 51 : { bitset<56> b(string("00000000000010110000101100000111000001110000101010101001")); return b; break; }
case 50 : { bitset<56> b(string("00000000000010110000101100001011000010110000101010101010")); return b; break; }
case 49 : { bitset<56> b(string("00000000000010110000101100001101000011010000101010101011")); return b; break; }
case 48 : { bitset<56> b(string("00000000000010110000101100001110000011100000101010101011")); return b; break; }
case 47 : { bitset<56> b(string("00000000000011010000110100001101000011011101101010111111")); return b; break; }
case 46 : { bitset<56> b(string("00000000000011010000110100001110000011101110101010111111")); return b; break; }
case 45 : { bitset<56> b(string("00000000000011100000111000001101000011011101101010111111")); return b; break; }
case 44 : { bitset<56> b(string("00000000000011100000111000001110000011101110101010111111")); return b; break; }
case 43 : { bitset<56> b(string("00000000000000000111000001110000111100001111010101010111")); return b; break; }
case 42 : { bitset<56> b(string("00000000000000001011000010110000111111110000010101101011")); return b; break; }
case 41 : { bitset<56> b(string("00000000000000001101000011010000111111111111010101111111")); return b; break; }
case 40 : { bitset<56> b(string("00000000000000001110000011100000111111111111010101111111")); return b; break; }
case 39 : { bitset<56> b(string("00000000000000000000011100001111000000001111101010010111")); return b; break; }
case 38 : { bitset<56> b(string("00000000000000000000101100001111000011110000101010101011")); return b; break; }
case 37 : { bitset<56> b(string("00000000000000000000110100001111000011111111101010111111")); return b; break; }
case 36 : { bitset<56> b(string("00000000000000000000111000001111000011111111101010111111")); return b; break; }
case 35 : { bitset<56> b(string("00000000000000000000000001110000111100001111010101010111")); return b; break; }
case 34 : { bitset<56> b(string("00000000000000000000000010110000111111110000010101101011")); return b; break; }
case 33 : { bitset<56> b(string("00000000000000000000000011010000111111111111010101111111")); return b; break; }
case 32 : { bitset<56> b(string("00000000000000000000000011100000111111111111010101111111")); return b; break; }
case 31 : { bitset<56> b(string("00000000000000000000011100001111000000001111101010010111")); return b; break; }
case 30 : { bitset<56> b(string("00000000000000000000101100001111000011110000101010101011")); return b; break; }
case 29 : { bitset<56> b(string("00000000000000000000110100001111000011111111101010111111")); return b; break; }
case 28 : { bitset<56> b(string("00000000000000000000111000001111000011111111101010111111")); return b; break; }
case 27 : { bitset<56> b(string("00000000000000000000000000000000011101110111010101111101")); return b; break; }
case 26 : { bitset<56> b(string("00000000000000000000000000000000101110111011010101111110")); return b; break; }
case 25 : { bitset<56> b(string("00000000000000000000000000000000110111011101010101111111")); return b; break; }
case 24 : { bitset<56> b(string("00000000000000000000000000000000111011101110010101111111")); return b; break; }
case 23 : { bitset<56> b(string("00000000000000000000000000000000000001110111101010111101")); return b; break; }
case 22 : { bitset<56> b(string("00000000000000000000000000000000000010111011101010111110")); return b; break; }
case 21 : { bitset<56> b(string("00000000000000000000000000000000000011011101101010111111")); return b; break; }
case 20 : { bitset<56> b(string("00000000000000000000000000000000000011101110101010111111")); return b; break; }
case 19 : { bitset<56> b(string("00000000000000000000000000000000000000000111111111010101")); return b; break; }
case 18 : { bitset<56> b(string("00000000000000000000000000000000000000001011111111010110")); return b; break; }
case 17 : { bitset<56> b(string("00000000000000000000000000000000000000001101111111010111")); return b; break; }
case 16 : { bitset<56> b(string("00000000000000000000000000000000000000001110111111010111")); return b; break; }
case 15 : { bitset<56> b(string("00000000000000000000000000000000000000000000111111101001")); return b; break; }
case 14 : { bitset<56> b(string("00000000000000000000000000000000000000000000111111101010")); return b; break; }
case 13 : { bitset<56> b(string("00000000000000000000000000000000000000000000111111101011")); return b; break; }
case 12 : { bitset<56> b(string("00000000000000000000000000000000000000000000111111101011")); return b; break; }
case 11 : { bitset<56> b(string("00000000000000000000000000000000000000000000010101111111")); return b; break; }
case 10 : { bitset<56> b(string("00000000000000000000000000000000000000000000001010111111")); return b; break; }
case 9 : { bitset<56> b(string("00000000000000000000000000000000000000000000000101111111")); return b; break; }
case 8 : { bitset<56> b(string("00000000000000000000000000000000000000000000000010111111")); return b; break; }
case 7 : { bitset<56> b(string("00000000000000000000000000000000000000000000000001111111")); return b; break; }
case 6 : { bitset<56> b(string("00000000000000000000000000000000000000000000000000111111")); return b; break; }
case 5 : { bitset<56> b(string("00000000000000000000000000000000000000000000000000010111")); return b; break; }
case 4 : { bitset<56> b(string("00000000000000000000000000000000000000000000000000001011")); return b; break; }
case 3 : { bitset<56> b(string("00000000000000000000000000000000000000000000000000000111")); return b; break; }
case 2 : { bitset<56> b(string("00000000000000000000000000000000000000000000000000000011")); return b; break; }
case 1 : { bitset<56> b(string("00000000000000000000000000000000000000000000000000000001")); return b; break; }
case 0 : { bitset<56> b(string("00000000000000000000000000000000000000000000000000000000")); return b; break; }
default : { bitset<56> b; return b; break; }
}
}
| bool L1MuDTTrackAssembler::isEmpty | ( | int | id | ) | const [inline] |
is it a valid Track Class?
Definition at line 77 of file L1MuDTTrackAssembler.h.
References m_theTCs, and UNDEF.
Referenced by L1MuDTSectorProcessor::run().
| void L1MuDTTrackAssembler::print | ( | void | ) | const |
print result of Track Assembler
Definition at line 478 of file L1MuDTTrackAssembler.cc.
References gather_cfg::cout, m_theAddresses, m_theBitMaps, m_thePriorityTable1, m_thePriorityTable2, and m_theTCs.
Referenced by run(), and L1MuDTSectorProcessor::run().
{
cout << "Track Assembler : " << endl;
cout << " Priority Table 1 : " << m_thePriorityTable1 << endl;
cout << " Priority Table 2 : " << " " << m_thePriorityTable2 << endl;
// print result
cout << "Track 1: " << m_theTCs[0] << " " << m_theBitMaps[0] << '\t' << m_theAddresses[0] << endl;
cout << "Track 2: " << m_theTCs[1] << " " << m_theBitMaps[1] << '\t' << m_theAddresses[1] << endl;
}
| unsigned int L1MuDTTrackAssembler::priorityEncoder12 | ( | const std::bitset< 12 > & | input | ) | [static, private] |
12 bit priority encoder
Definition at line 942 of file L1MuDTTrackAssembler.cc.
References i, and query::result.
Referenced by runEncoderSubUnit1(), and runEncoderSubUnit2().
| unsigned int L1MuDTTrackAssembler::priorityEncoder21 | ( | const std::bitset< 21 > & | input | ) | [static, private] |
21 bit priority encoder
Definition at line 990 of file L1MuDTTrackAssembler.cc.
References i, and query::result.
Referenced by runEncoderSubUnit2().
| unsigned int L1MuDTTrackAssembler::priorityEncoder22 | ( | const std::bitset< 22 > & | input | ) | [static, private] |
22 bit priority encoder
Definition at line 974 of file L1MuDTTrackAssembler.cc.
References i, and query::result.
Referenced by runEncoderSubUnit1().
| unsigned int L1MuDTTrackAssembler::priorityEncoder4 | ( | const std::bitset< 4 > & | input | ) | [static, private] |
4 bit priority encoder
Definition at line 958 of file L1MuDTTrackAssembler.cc.
References i, and query::result.
Referenced by runEncoderSubUnit1(), and runEncoderSubUnit2().
| void L1MuDTTrackAssembler::reset | ( | void | ) | [virtual] |
reset Track Assembler
Implements L1AbstractProcessor.
Definition at line 459 of file L1MuDTTrackAssembler.cc.
References i, j, m_theAddresses, m_theBitMaps, m_theLastAddress, m_theLastAddressI, m_thePriorityTable1, m_thePriorityTable2, m_theTCs, L1MuDTAddressArray::reset(), and UNDEF.
Referenced by L1MuDTSectorProcessor::reset().
{
for ( int i = 0; i < 68; i++ ) m_theLastAddress[i] = 15;
for ( int j = 0; j < 12; j++ ) m_theLastAddressI[j] = 15;
m_thePriorityTable1.reset();
m_thePriorityTable2.reset();
m_theTCs[0] = UNDEF;
m_theTCs[1] = UNDEF;
m_theBitMaps[0].reset();
m_theBitMaps[1].reset();
m_theAddresses[0].reset();
m_theAddresses[1].reset();
}
| void L1MuDTTrackAssembler::run | ( | void | ) | [virtual] |
run Track Assembler
Reimplemented from L1AbstractProcessor.
Definition at line 70 of file L1MuDTTrackAssembler.cc.
References addressEncoder12(), addressEncoder12s(), gather_cfg::cout, L1MuDTTFConfig::Debug(), L1MuDTSectorProcessor::EU(), EX12, EX13, EX14, EX23, EX24, EX34, getCancelationTable(), L1MuDTExtrapolationUnit::getQSTable(), i, m_sp, m_theAddresses, m_theBitMaps, m_theLastAddress, m_theLastAddressI, m_thePriorityTable1, m_thePriorityTable2, m_theTCs, p1, p2, print(), L1MuDTAddressArray::reset(), runAddressAssignment1(), runAddressAssignment2(), runEncoderSubUnit1(), runEncoderSubUnit2(), L1MuDTAddressArray::setStation(), relativeConstraints::station, L1MuDTAddressArray::station(), T12, T123, T1234, T124, T13, T134, T14, T23, T234, T24, T34, and UNDEF.
Referenced by L1MuDTSectorProcessor::run().
{
// get the 18 bitmap tables from the Quality Sorter Unit
bitset<12> b_adr12_8 = m_sp.EU()->getQSTable(EX12, 0);
bitset<12> b_adr12_9 = m_sp.EU()->getQSTable(EX12, 1);
bitset<12> b_adr13_8 = m_sp.EU()->getQSTable(EX13, 0);
bitset<12> b_adr13_9 = m_sp.EU()->getQSTable(EX13, 1);
bitset<12> b_adr14_8 = m_sp.EU()->getQSTable(EX14, 0);
bitset<12> b_adr14_9 = m_sp.EU()->getQSTable(EX14, 1);
bitset<12> b_adr23_8 = m_sp.EU()->getQSTable(EX23, 0);
bitset<12> b_adr23_9 = m_sp.EU()->getQSTable(EX23, 1);
bitset<12> b_adr23_0 = m_sp.EU()->getQSTable(EX23, 2);
bitset<12> b_adr23_1 = m_sp.EU()->getQSTable(EX23, 3);
bitset<12> b_adr24_8 = m_sp.EU()->getQSTable(EX24, 0);
bitset<12> b_adr24_9 = m_sp.EU()->getQSTable(EX24, 1);
bitset<12> b_adr24_0 = m_sp.EU()->getQSTable(EX24, 2);
bitset<12> b_adr24_1 = m_sp.EU()->getQSTable(EX24, 3);
bitset<12> b_adr34_8 = m_sp.EU()->getQSTable(EX34, 0);
bitset<12> b_adr34_9 = m_sp.EU()->getQSTable(EX34, 1);
bitset<12> b_adr34_0 = m_sp.EU()->getQSTable(EX34, 2);
bitset<12> b_adr34_1 = m_sp.EU()->getQSTable(EX34, 3);
// Last segment node building
bitset<12> n_1234_888 = ( b_adr14_8 & b_adr24_8 & b_adr34_8 );
bitset<12> n_1234_889 = ( b_adr14_8 & b_adr24_8 & b_adr34_9 );
bitset<12> n_1234_880 = ( b_adr14_8 & b_adr24_8 & b_adr34_0 );
bitset<12> n_1234_881 = ( b_adr14_8 & b_adr24_8 & b_adr34_1 );
bitset<12> n_1234_898 = ( b_adr14_8 & b_adr24_9 & b_adr34_8 );
bitset<12> n_1234_899 = ( b_adr14_8 & b_adr24_9 & b_adr34_9 );
bitset<12> n_1234_890 = ( b_adr14_8 & b_adr24_9 & b_adr34_0 );
bitset<12> n_1234_891 = ( b_adr14_8 & b_adr24_9 & b_adr34_1 );
bitset<12> n_1234_800 = ( b_adr14_8 & b_adr24_0 & b_adr34_0 );
bitset<12> n_1234_801 = ( b_adr14_8 & b_adr24_0 & b_adr34_1 );
bitset<12> n_1234_810 = ( b_adr14_8 & b_adr24_1 & b_adr34_0 );
bitset<12> n_1234_811 = ( b_adr14_8 & b_adr24_1 & b_adr34_1 );
bitset<12> n_1234_988 = ( b_adr14_9 & b_adr24_8 & b_adr34_8 );
bitset<12> n_1234_989 = ( b_adr14_9 & b_adr24_8 & b_adr34_9 );
bitset<12> n_1234_980 = ( b_adr14_9 & b_adr24_8 & b_adr34_0 );
bitset<12> n_1234_981 = ( b_adr14_9 & b_adr24_8 & b_adr34_1 );
bitset<12> n_1234_998 = ( b_adr14_9 & b_adr24_9 & b_adr34_8 );
bitset<12> n_1234_999 = ( b_adr14_9 & b_adr24_9 & b_adr34_9 );
bitset<12> n_1234_990 = ( b_adr14_9 & b_adr24_9 & b_adr34_0 );
bitset<12> n_1234_991 = ( b_adr14_9 & b_adr24_9 & b_adr34_1 );
bitset<12> n_1234_900 = ( b_adr14_9 & b_adr24_0 & b_adr34_0 );
bitset<12> n_1234_901 = ( b_adr14_9 & b_adr24_0 & b_adr34_1 );
bitset<12> n_1234_910 = ( b_adr14_9 & b_adr24_1 & b_adr34_0 );
bitset<12> n_1234_911 = ( b_adr14_9 & b_adr24_1 & b_adr34_1 );
bitset<12> n_123_88 = ( b_adr13_8 & b_adr23_8 );
bitset<12> n_123_89 = ( b_adr13_8 & b_adr23_9 );
bitset<12> n_123_80 = ( b_adr13_8 & b_adr23_0 );
bitset<12> n_123_81 = ( b_adr13_8 & b_adr23_1 );
bitset<12> n_123_98 = ( b_adr13_9 & b_adr23_8 );
bitset<12> n_123_99 = ( b_adr13_9 & b_adr23_9 );
bitset<12> n_123_90 = ( b_adr13_9 & b_adr23_0 );
bitset<12> n_123_91 = ( b_adr13_9 & b_adr23_1 );
bitset<12> n_124_88 = ( b_adr14_8 & b_adr24_8 );
bitset<12> n_124_89 = ( b_adr14_8 & b_adr24_9 );
bitset<12> n_124_80 = ( b_adr14_8 & b_adr24_0 );
bitset<12> n_124_81 = ( b_adr14_8 & b_adr24_1 );
bitset<12> n_124_98 = ( b_adr14_9 & b_adr24_8 );
bitset<12> n_124_99 = ( b_adr14_9 & b_adr24_9 );
bitset<12> n_124_90 = ( b_adr14_9 & b_adr24_0 );
bitset<12> n_124_91 = ( b_adr14_9 & b_adr24_1 );
bitset<12> n_134_88 = ( b_adr14_8 & b_adr34_8 );
bitset<12> n_134_89 = ( b_adr14_8 & b_adr34_9 );
bitset<12> n_134_80 = ( b_adr14_8 & b_adr34_0 );
bitset<12> n_134_81 = ( b_adr14_8 & b_adr34_1 );
bitset<12> n_134_98 = ( b_adr14_9 & b_adr34_8 );
bitset<12> n_134_99 = ( b_adr14_9 & b_adr34_9 );
bitset<12> n_134_90 = ( b_adr14_9 & b_adr34_0 );
bitset<12> n_134_91 = ( b_adr14_9 & b_adr34_1 );
bitset<12> n_234_88 = ( b_adr24_8 & b_adr34_8 );
bitset<12> n_234_89 = ( b_adr24_8 & b_adr34_9 );
bitset<12> n_234_80 = ( b_adr24_8 & b_adr34_0 );
bitset<12> n_234_81 = ( b_adr24_8 & b_adr34_1 );
bitset<12> n_234_98 = ( b_adr24_9 & b_adr34_8 );
bitset<12> n_234_99 = ( b_adr24_9 & b_adr34_9 );
bitset<12> n_234_90 = ( b_adr24_9 & b_adr34_0 );
bitset<12> n_234_91 = ( b_adr24_9 & b_adr34_1 );
bitset<12> n_12_8 = b_adr12_8;
bitset<12> n_12_9 = b_adr12_9;
bitset<12> n_13_8 = b_adr13_8;
bitset<12> n_13_9 = b_adr13_9;
bitset<12> n_14_8 = b_adr14_8;
bitset<12> n_14_9 = b_adr14_9;
bitset<12> n_23_8 = b_adr23_8;
bitset<12> n_23_9 = b_adr23_9;
bitset<12> n_24_8 = b_adr24_8;
bitset<12> n_24_9 = b_adr24_9;
bitset<12> n_34_8 = b_adr34_8;
bitset<12> n_34_9 = b_adr34_9;
// Last address encoders
m_theLastAddress[67] = addressEncoder12(n_1234_888);
m_theLastAddress[66] = addressEncoder12(n_1234_889);
m_theLastAddress[65] = addressEncoder12(n_1234_880);
m_theLastAddress[64] = addressEncoder12(n_1234_881);
m_theLastAddress[63] = addressEncoder12(n_1234_898);
m_theLastAddress[62] = addressEncoder12(n_1234_899);
m_theLastAddress[61] = addressEncoder12(n_1234_890);
m_theLastAddress[60] = addressEncoder12(n_1234_891);
m_theLastAddress[59] = addressEncoder12(n_1234_800);
m_theLastAddress[58] = addressEncoder12(n_1234_801);
m_theLastAddress[57] = addressEncoder12(n_1234_810);
m_theLastAddress[56] = addressEncoder12(n_1234_811);
m_theLastAddress[55] = addressEncoder12(n_1234_988);
m_theLastAddress[54] = addressEncoder12(n_1234_989);
m_theLastAddress[53] = addressEncoder12(n_1234_980);
m_theLastAddress[52] = addressEncoder12(n_1234_981);
m_theLastAddress[51] = addressEncoder12(n_1234_998);
m_theLastAddress[50] = addressEncoder12(n_1234_999);
m_theLastAddress[49] = addressEncoder12(n_1234_990);
m_theLastAddress[48] = addressEncoder12(n_1234_991);
m_theLastAddress[47] = addressEncoder12(n_1234_900);
m_theLastAddress[46] = addressEncoder12(n_1234_901);
m_theLastAddress[45] = addressEncoder12(n_1234_910);
m_theLastAddress[44] = addressEncoder12(n_1234_911);
m_theLastAddress[43] = addressEncoder12(n_123_88);
m_theLastAddress[42] = addressEncoder12(n_123_89);
m_theLastAddress[41] = addressEncoder12(n_123_80);
m_theLastAddress[40] = addressEncoder12(n_123_81);
m_theLastAddress[39] = addressEncoder12(n_123_98);
m_theLastAddress[38] = addressEncoder12(n_123_99);
m_theLastAddress[37] = addressEncoder12(n_123_90);
m_theLastAddress[36] = addressEncoder12(n_123_91);
m_theLastAddress[35] = addressEncoder12(n_124_88);
m_theLastAddress[34] = addressEncoder12(n_124_89);
m_theLastAddress[33] = addressEncoder12(n_124_80);
m_theLastAddress[32] = addressEncoder12(n_124_81);
m_theLastAddress[31] = addressEncoder12(n_124_98);
m_theLastAddress[30] = addressEncoder12(n_124_99);
m_theLastAddress[29] = addressEncoder12(n_124_90);
m_theLastAddress[28] = addressEncoder12(n_124_91);
m_theLastAddress[27] = addressEncoder12(n_134_88);
m_theLastAddress[26] = addressEncoder12(n_134_89);
m_theLastAddress[25] = addressEncoder12(n_134_80);
m_theLastAddress[24] = addressEncoder12(n_134_81);
m_theLastAddress[23] = addressEncoder12(n_134_98);
m_theLastAddress[22] = addressEncoder12(n_134_99);
m_theLastAddress[21] = addressEncoder12(n_134_90);
m_theLastAddress[20] = addressEncoder12(n_134_91);
m_theLastAddress[19] = addressEncoder12(n_234_88);
m_theLastAddress[18] = addressEncoder12(n_234_89);
m_theLastAddress[17] = addressEncoder12(n_234_80);
m_theLastAddress[16] = addressEncoder12(n_234_81);
m_theLastAddress[15] = addressEncoder12(n_234_98);
m_theLastAddress[14] = addressEncoder12(n_234_99);
m_theLastAddress[13] = addressEncoder12(n_234_90);
m_theLastAddress[12] = addressEncoder12(n_234_91);
m_theLastAddress[11] = addressEncoder12(n_12_8);
m_theLastAddress[10] = addressEncoder12(n_12_9);
m_theLastAddress[9] = addressEncoder12(n_13_8);
m_theLastAddress[8] = addressEncoder12(n_13_9);
m_theLastAddress[7] = addressEncoder12(n_14_8);
m_theLastAddress[6] = addressEncoder12(n_14_9);
m_theLastAddress[5] = addressEncoder12(n_23_8);
m_theLastAddress[4] = addressEncoder12(n_23_9);
m_theLastAddress[3] = addressEncoder12(n_24_8);
m_theLastAddress[2] = addressEncoder12(n_24_9);
m_theLastAddress[1] = addressEncoder12(n_34_8);
m_theLastAddress[0] = addressEncoder12(n_34_9);
m_theLastAddressI[11] = addressEncoder12s(n_12_8);
m_theLastAddressI[10] = addressEncoder12s(n_12_9);
m_theLastAddressI[9] = addressEncoder12s(n_13_8);
m_theLastAddressI[8] = addressEncoder12s(n_13_9);
m_theLastAddressI[7] = addressEncoder12s(n_14_8);
m_theLastAddressI[6] = addressEncoder12s(n_14_9);
m_theLastAddressI[5] = addressEncoder12s(n_23_8);
m_theLastAddressI[4] = addressEncoder12s(n_23_9);
m_theLastAddressI[3] = addressEncoder12s(n_24_8);
m_theLastAddressI[2] = addressEncoder12s(n_24_9);
m_theLastAddressI[1] = addressEncoder12s(n_34_8);
m_theLastAddressI[0] = addressEncoder12s(n_34_9);
// Main equations (68)
m_thePriorityTable1[67] = ( b_adr12_8[0] & b_adr13_8[0] & b_adr23_8[0] & n_1234_888.any() );
m_thePriorityTable1[66] = ( b_adr12_8[0] & b_adr13_8[1] & b_adr23_8[1] & n_1234_889.any() );
m_thePriorityTable1[65] = ( b_adr12_8[0] & b_adr13_8[2] & b_adr23_8[2] & n_1234_880.any() );
m_thePriorityTable1[64] = ( b_adr12_8[0] & b_adr13_8[3] & b_adr23_8[3] & n_1234_881.any() );
m_thePriorityTable1[63] = ( b_adr12_8[1] & b_adr13_8[0] & b_adr23_9[0] & n_1234_898.any() );
m_thePriorityTable1[62] = ( b_adr12_8[1] & b_adr13_8[1] & b_adr23_9[1] & n_1234_899.any() );
m_thePriorityTable1[61] = ( b_adr12_8[1] & b_adr13_8[2] & b_adr23_9[2] & n_1234_890.any() );
m_thePriorityTable1[60] = ( b_adr12_8[1] & b_adr13_8[3] & b_adr23_9[3] & n_1234_891.any() );
m_thePriorityTable1[59] = ( b_adr12_8[2] & b_adr13_8[2] & b_adr23_0[2] & n_1234_800.any() );
m_thePriorityTable1[58] = ( b_adr12_8[2] & b_adr13_8[3] & b_adr23_0[3] & n_1234_801.any() );
m_thePriorityTable1[57] = ( b_adr12_8[3] & b_adr13_8[2] & b_adr23_1[2] & n_1234_810.any() );
m_thePriorityTable1[56] = ( b_adr12_8[3] & b_adr13_8[3] & b_adr23_1[3] & n_1234_811.any() );
m_thePriorityTable1[55] = ( b_adr12_9[0] & b_adr13_9[0] & b_adr23_8[0] & n_1234_988.any() );
m_thePriorityTable1[54] = ( b_adr12_9[0] & b_adr13_9[1] & b_adr23_8[1] & n_1234_989.any() );
m_thePriorityTable1[53] = ( b_adr12_9[0] & b_adr13_9[2] & b_adr23_8[2] & n_1234_980.any() );
m_thePriorityTable1[52] = ( b_adr12_9[0] & b_adr13_9[3] & b_adr23_8[3] & n_1234_981.any() );
m_thePriorityTable1[51] = ( b_adr12_9[1] & b_adr13_9[0] & b_adr23_9[0] & n_1234_998.any() );
m_thePriorityTable1[50] = ( b_adr12_9[1] & b_adr13_9[1] & b_adr23_9[1] & n_1234_999.any() );
m_thePriorityTable1[49] = ( b_adr12_9[1] & b_adr13_9[2] & b_adr23_9[2] & n_1234_990.any() );
m_thePriorityTable1[48] = ( b_adr12_9[1] & b_adr13_9[3] & b_adr23_9[3] & n_1234_991.any() );
m_thePriorityTable1[47] = ( b_adr12_9[2] & b_adr13_9[2] & b_adr23_0[2] & n_1234_900.any() );
m_thePriorityTable1[46] = ( b_adr12_9[2] & b_adr13_9[3] & b_adr23_0[3] & n_1234_901.any() );
m_thePriorityTable1[45] = ( b_adr12_9[3] & b_adr13_9[2] & b_adr23_1[2] & n_1234_910.any() );
m_thePriorityTable1[44] = ( b_adr12_9[3] & b_adr13_9[3] & b_adr23_1[3] & n_1234_911.any() );
m_thePriorityTable1[43] = ( b_adr12_8[0] & n_123_88.any() );
m_thePriorityTable1[42] = ( b_adr12_8[1] & n_123_89.any() );
m_thePriorityTable1[41] = ( b_adr12_8[2] & n_123_80.any() );
m_thePriorityTable1[40] = ( b_adr12_8[3] & n_123_81.any() );
m_thePriorityTable1[39] = ( b_adr12_9[0] & n_123_98.any() );
m_thePriorityTable1[38] = ( b_adr12_9[1] & n_123_99.any() );
m_thePriorityTable1[37] = ( b_adr12_9[2] & n_123_90.any() );
m_thePriorityTable1[36] = ( b_adr12_9[3] & n_123_91.any() );
m_thePriorityTable1[35] = ( b_adr12_8[0] & n_124_88.any() );
m_thePriorityTable1[34] = ( b_adr12_8[1] & n_124_89.any() );
m_thePriorityTable1[33] = ( b_adr12_8[2] & n_124_80.any() );
m_thePriorityTable1[32] = ( b_adr12_8[3] & n_124_81.any() );
m_thePriorityTable1[31] = ( b_adr12_9[0] & n_124_98.any() );
m_thePriorityTable1[30] = ( b_adr12_9[1] & n_124_99.any() );
m_thePriorityTable1[29] = ( b_adr12_9[2] & n_124_90.any() );
m_thePriorityTable1[28] = ( b_adr12_9[3] & n_124_91.any() );
m_thePriorityTable1[27] = ( b_adr13_8[0] & n_134_88.any() );
m_thePriorityTable1[26] = ( b_adr13_8[1] & n_134_89.any() );
m_thePriorityTable1[25] = ( b_adr13_8[2] & n_134_80.any() );
m_thePriorityTable1[24] = ( b_adr13_8[3] & n_134_81.any() );
m_thePriorityTable1[23] = ( b_adr13_9[0] & n_134_98.any() );
m_thePriorityTable1[22] = ( b_adr13_9[1] & n_134_99.any() );
m_thePriorityTable1[21] = ( b_adr13_9[2] & n_134_90.any() );
m_thePriorityTable1[20] = ( b_adr13_9[3] & n_134_91.any() );
m_thePriorityTable1[19] = ( b_adr23_8[0] & n_234_88.any() );
m_thePriorityTable1[18] = ( b_adr23_8[1] & n_234_89.any() );
m_thePriorityTable1[17] = ( b_adr23_8[2] & n_234_80.any() );
m_thePriorityTable1[16] = ( b_adr23_8[3] & n_234_81.any() );
m_thePriorityTable1[15] = ( b_adr23_9[0] & n_234_98.any() );
m_thePriorityTable1[14] = ( b_adr23_9[1] & n_234_99.any() );
m_thePriorityTable1[13] = ( b_adr23_9[2] & n_234_90.any() );
m_thePriorityTable1[12] = ( b_adr23_9[3] & n_234_91.any() );
m_thePriorityTable1[11] = n_12_8.any();
m_thePriorityTable1[10] = n_12_9.any();
m_thePriorityTable1[9] = n_13_8.any();
m_thePriorityTable1[8] = n_13_9.any();
m_thePriorityTable1[7] = n_14_8.any();
m_thePriorityTable1[6] = n_14_9.any();
m_thePriorityTable1[5] = n_23_8.any();
m_thePriorityTable1[4] = n_23_9.any();
m_thePriorityTable1[3] = n_24_8.any();
m_thePriorityTable1[2] = n_24_9.any();
m_thePriorityTable1[1] = n_34_8.any();
m_thePriorityTable1[0] = n_34_9.any();
if ( !m_thePriorityTable1.any() ) return;
// first Priority Encoder Sub-Unit
unsigned int global1 = 0;
unsigned int group1 = 0;
unsigned int p1 = 0;
runEncoderSubUnit1(global1, group1, p1);
// Address Assignment for the highest priority track
runAddressAssignment1(global1, group1);
// Cancellation and second Track Finder Unit
for ( int i = 0; i < 56; i++ ) {
m_thePriorityTable2[i] = m_thePriorityTable1[i];
}
m_thePriorityTable2 &= getCancelationTable(p1);
if ( !m_thePriorityTable2.any() ) return;
// second Priority Encoder Sub-Unit
unsigned int global2 = 0;
unsigned int group2 = 0;
unsigned int p2 = 0;
runEncoderSubUnit2(global2, group2, p2);
// Address Assignment for the second priority track
runAddressAssignment2(global2, group2);
// Fake Pair Cancellation Unit
unsigned int s1_2 = m_theAddresses[1].station(1);
unsigned int s2_2 = m_theAddresses[1].station(2);
unsigned int s3_2 = m_theAddresses[1].station(3);
unsigned int s4_2 = m_theAddresses[1].station(4);
if ( s2_2 == m_theAddresses[0].station(2) ) {
s2_2 = 15; m_theBitMaps[1].reset(1); m_theAddresses[1].setStation(2,15);
if ( m_theTCs[1] == T1234 ) m_theTCs[1] = T134;
if ( m_theTCs[1] == T123 ) m_theTCs[1] = T13;
if ( m_theTCs[1] == T124 ) m_theTCs[1] = T14;
if ( m_theTCs[1] == T234 ) m_theTCs[1] = T34;
}
if ( s3_2 == m_theAddresses[0].station(3) ) {
s3_2 = 15; m_theBitMaps[1].reset(2); m_theAddresses[1].setStation(3,15);
if ( m_theTCs[1] == T1234 ) m_theTCs[1] = T124;
if ( m_theTCs[1] == T123 ) m_theTCs[1] = T12;
if ( m_theTCs[1] == T134 ) m_theTCs[1] = T14;
if ( m_theTCs[1] == T234 ) m_theTCs[1] = T24;
}
if ( s4_2 == m_theAddresses[0].station(4) ) {
s4_2 = 15; m_theBitMaps[1].reset(3); m_theAddresses[1].setStation(4,15);
if ( m_theTCs[1] == T1234 ) m_theTCs[1] = T123;
if ( m_theTCs[1] == T124 ) m_theTCs[1] = T12;
if ( m_theTCs[1] == T134 ) m_theTCs[1] = T13;
if ( m_theTCs[1] == T234 ) m_theTCs[1] = T23;
}
if ( ( s2_2 == 15 && s3_2 == 15 && s4_2 == 15 ) ||
( s1_2 == 15 && s3_2 == 15 && s4_2 == 15 ) ||
( s1_2 == 15 && s2_2 == 15 && s4_2 == 15 ) ||
( s1_2 == 15 && s2_2 == 15 && s3_2 == 15 ) ) {
if ( L1MuDTTFConfig::Debug(5) ) cout << "L1MuDTTrackAssembler: second track has been cancelled" << endl;
if ( L1MuDTTFConfig::Debug(5) ) print();
m_theTCs[1] = UNDEF;
m_theAddresses[1].reset();
m_theBitMaps[1].reset();
}
/*
if ( m_theBitMaps[1].to_ulong() != tc2bitmap(m_theTCs[1]) ) {
if ( L1MuDTTFConfig::Debug(5) ) cout << "L1MuDTTrackAssembler: second track has been cancelled" << endl;
if ( L1MuDTTFConfig::Debug(5) ) print();
m_theTCs[1] = UNDEF;
m_theAddresses[1].reset();
m_theBitMaps[1].reset();
}
*/
}
| void L1MuDTTrackAssembler::runAddressAssignment1 | ( | int | global, |
| int | group | ||
| ) | [private] |
run the first Address Assignment Sub-Unit
Definition at line 689 of file L1MuDTTrackAssembler.cc.
References m_theAddresses, m_theBitMaps, m_theLastAddress, m_theTCs, L1MuDTAddressArray::setStations(), T12, T123, T1234, T124, T13, T134, T14, T23, T234, T24, T34, tc2bitmap(), and UNDEF.
Referenced by run().
{
TrackClass tc(UNDEF);
switch ( global ) {
case 21 : { tc = T1234;
switch ( group ) {
case 11 : m_theAddresses[0].setStations( 0, 0, 0, m_theLastAddress[67]); break;
case 10 : m_theAddresses[0].setStations( 0, 0, 1, m_theLastAddress[66]); break;
case 9 : m_theAddresses[0].setStations( 0, 0, 2, m_theLastAddress[65]); break;
case 8 : m_theAddresses[0].setStations( 0, 0, 3, m_theLastAddress[64]); break;
case 7 : m_theAddresses[0].setStations( 0, 1, 0, m_theLastAddress[63]); break;
case 6 : m_theAddresses[0].setStations( 0, 1, 1, m_theLastAddress[62]); break;
case 5 : m_theAddresses[0].setStations( 0, 1, 2, m_theLastAddress[61]); break;
case 4 : m_theAddresses[0].setStations( 0, 1, 3, m_theLastAddress[60]); break;
case 3 : m_theAddresses[0].setStations( 0, 2, 2, m_theLastAddress[59]); break;
case 2 : m_theAddresses[0].setStations( 0, 2, 3, m_theLastAddress[58]); break;
case 1 : m_theAddresses[0].setStations( 0, 3, 2, m_theLastAddress[57]); break;
case 0 : m_theAddresses[0].setStations( 0, 3, 3, m_theLastAddress[56]); break;
}
break;
}
case 20 : { tc = T1234;
switch ( group ) {
case 11 : m_theAddresses[0].setStations( 1, 0, 0, m_theLastAddress[55]); break;
case 10 : m_theAddresses[0].setStations( 1, 0, 1, m_theLastAddress[54]); break;
case 9 : m_theAddresses[0].setStations( 1, 0, 2, m_theLastAddress[53]); break;
case 8 : m_theAddresses[0].setStations( 1, 0, 3, m_theLastAddress[52]); break;
case 7 : m_theAddresses[0].setStations( 1, 1, 0, m_theLastAddress[51]); break;
case 6 : m_theAddresses[0].setStations( 1, 1, 1, m_theLastAddress[50]); break;
case 5 : m_theAddresses[0].setStations( 1, 1, 2, m_theLastAddress[49]); break;
case 4 : m_theAddresses[0].setStations( 1, 1, 3, m_theLastAddress[48]); break;
case 3 : m_theAddresses[0].setStations( 1, 2, 2, m_theLastAddress[47]); break;
case 2 : m_theAddresses[0].setStations( 1, 2, 3, m_theLastAddress[46]); break;
case 1 : m_theAddresses[0].setStations( 1, 3, 2, m_theLastAddress[45]); break;
case 0 : m_theAddresses[0].setStations( 1, 3, 3, m_theLastAddress[44]); break;
}
break;
}
case 19 : { tc = T123;
switch ( group ) {
case 3 : m_theAddresses[0].setStations( 0, 0, m_theLastAddress[43],15); break;
case 2 : m_theAddresses[0].setStations( 0, 1, m_theLastAddress[42],15); break;
case 1 : m_theAddresses[0].setStations( 0, 2, m_theLastAddress[41],15); break;
case 0 : m_theAddresses[0].setStations( 0, 3, m_theLastAddress[40],15); break;
}
break;
}
case 18 : { tc = T123;
switch ( group ) {
case 3 : m_theAddresses[0].setStations( 1, 0, m_theLastAddress[39],15); break;
case 2 : m_theAddresses[0].setStations( 1, 1, m_theLastAddress[38],15); break;
case 1 : m_theAddresses[0].setStations( 1, 2, m_theLastAddress[37],15); break;
case 0 : m_theAddresses[0].setStations( 1, 3, m_theLastAddress[36],15); break;
}
break;
}
case 17 : { tc = T124;
switch ( group ) {
case 3 : m_theAddresses[0].setStations( 0, 0,15, m_theLastAddress[35]); break;
case 2 : m_theAddresses[0].setStations( 0, 1,15, m_theLastAddress[34]); break;
case 1 : m_theAddresses[0].setStations( 0, 2,15, m_theLastAddress[33]); break;
case 0 : m_theAddresses[0].setStations( 0, 3,15, m_theLastAddress[32]); break;
}
break;
}
case 16 : { tc = T124;
switch ( group ) {
case 3 : m_theAddresses[0].setStations( 1, 0,15, m_theLastAddress[31]); break;
case 2 : m_theAddresses[0].setStations( 1, 1,15, m_theLastAddress[30]); break;
case 1 : m_theAddresses[0].setStations( 1, 2,15, m_theLastAddress[29]); break;
case 0 : m_theAddresses[0].setStations( 1, 3,15, m_theLastAddress[28]); break;
}
break;
}
case 15 : { tc = T134;
switch ( group ) {
case 3 : m_theAddresses[0].setStations( 0,15, 0, m_theLastAddress[27]); break;
case 2 : m_theAddresses[0].setStations( 0,15, 1, m_theLastAddress[26]); break;
case 1 : m_theAddresses[0].setStations( 0,15, 2, m_theLastAddress[25]); break;
case 0 : m_theAddresses[0].setStations( 0,15, 3, m_theLastAddress[24]); break;
}
break;
}
case 14 : { tc = T134;
switch ( group ) {
case 3 : m_theAddresses[0].setStations( 1,15, 0, m_theLastAddress[23]); break;
case 2 : m_theAddresses[0].setStations( 1,15, 1, m_theLastAddress[22]); break;
case 1 : m_theAddresses[0].setStations( 1,15, 2, m_theLastAddress[21]); break;
case 0 : m_theAddresses[0].setStations( 1,15, 3, m_theLastAddress[20]); break;
}
break;
}
case 13 : { tc = T234;
switch ( group ) {
case 3 : m_theAddresses[0].setStations(15, 0, 0, m_theLastAddress[19]); break;
case 2 : m_theAddresses[0].setStations(15, 0, 1, m_theLastAddress[18]); break;
case 1 : m_theAddresses[0].setStations(15, 0, 2, m_theLastAddress[17]); break;
case 0 : m_theAddresses[0].setStations(15, 0, 3, m_theLastAddress[16]); break;
}
break;
}
case 12 : { tc = T234;
switch ( group ) {
case 3 : m_theAddresses[0].setStations(15, 1, 0, m_theLastAddress[15]); break;
case 2 : m_theAddresses[0].setStations(15, 1, 1, m_theLastAddress[14]); break;
case 1 : m_theAddresses[0].setStations(15, 1, 2, m_theLastAddress[13]); break;
case 0 : m_theAddresses[0].setStations(15, 1, 3, m_theLastAddress[12]); break;
}
break;
}
case 11 : { tc = T12; m_theAddresses[0].setStations( 0, m_theLastAddress[11],15,15); break; }
case 10 : { tc = T12; m_theAddresses[0].setStations( 1, m_theLastAddress[10],15,15); break; }
case 9 : { tc = T13; m_theAddresses[0].setStations( 0,15, m_theLastAddress[9],15); break; }
case 8 : { tc = T13; m_theAddresses[0].setStations( 1,15, m_theLastAddress[8],15); break; }
case 7 : { tc = T14; m_theAddresses[0].setStations( 0,15,15, m_theLastAddress[7]); break; }
case 6 : { tc = T14; m_theAddresses[0].setStations( 1,15,15, m_theLastAddress[6]); break; }
case 5 : { tc = T23; m_theAddresses[0].setStations(15, 0, m_theLastAddress[5],15); break; }
case 4 : { tc = T23; m_theAddresses[0].setStations(15, 1, m_theLastAddress[4],15); break; }
case 3 : { tc = T24; m_theAddresses[0].setStations(15, 0,15, m_theLastAddress[3]); break; }
case 2 : { tc = T24; m_theAddresses[0].setStations(15, 1,15, m_theLastAddress[2]); break; }
case 1 : { tc = T34; m_theAddresses[0].setStations(15,15, 0, m_theLastAddress[1]); break; }
case 0 : { tc = T34; m_theAddresses[0].setStations(15,15, 1, m_theLastAddress[0]); break; }
}
// set Track Class and covert to bitmap
m_theTCs[0] = tc;
m_theBitMaps[0] = tc2bitmap(tc);
}
| void L1MuDTTrackAssembler::runAddressAssignment2 | ( | int | global, |
| int | group | ||
| ) | [private] |
run the second Address Assignment Sub-Unit
Definition at line 824 of file L1MuDTTrackAssembler.cc.
References m_theAddresses, m_theBitMaps, m_theLastAddress, m_theLastAddressI, m_theTCs, L1MuDTAddressArray::setStations(), T12, T123, T1234, T124, T13, T134, T14, T23, T234, T24, T34, tc2bitmap(), and UNDEF.
Referenced by run().
{
TrackClass tc(UNDEF);
switch ( global ) {
case 20 : { tc = T1234;
switch ( group ) {
case 11 : m_theAddresses[1].setStations( 1, 0, 0, m_theLastAddress[55]); break;
case 10 : m_theAddresses[1].setStations( 1, 0, 1, m_theLastAddress[54]); break;
case 9 : m_theAddresses[1].setStations( 1, 0, 2, m_theLastAddress[53]); break;
case 8 : m_theAddresses[1].setStations( 1, 0, 3, m_theLastAddress[52]); break;
case 7 : m_theAddresses[1].setStations( 1, 1, 0, m_theLastAddress[51]); break;
case 6 : m_theAddresses[1].setStations( 1, 1, 1, m_theLastAddress[50]); break;
case 5 : m_theAddresses[1].setStations( 1, 1, 2, m_theLastAddress[49]); break;
case 4 : m_theAddresses[1].setStations( 1, 1, 3, m_theLastAddress[48]); break;
case 3 : m_theAddresses[1].setStations( 1, 2, 2, m_theLastAddress[47]); break;
case 2 : m_theAddresses[1].setStations( 1, 2, 3, m_theLastAddress[46]); break;
case 1 : m_theAddresses[1].setStations( 1, 3, 2, m_theLastAddress[45]); break;
case 0 : m_theAddresses[1].setStations( 1, 3, 3, m_theLastAddress[44]); break;
}
break;
}
case 19 : { tc = T123;
switch ( group ) {
case 3 : m_theAddresses[1].setStations( 0, 0, m_theLastAddress[43],15); break;
case 2 : m_theAddresses[1].setStations( 0, 1, m_theLastAddress[42],15); break;
case 1 : m_theAddresses[1].setStations( 0, 2, m_theLastAddress[41],15); break;
case 0 : m_theAddresses[1].setStations( 0, 3, m_theLastAddress[40],15); break;
}
break;
}
case 18 : { tc = T123;
switch ( group ) {
case 3 : m_theAddresses[1].setStations( 1, 0, m_theLastAddress[39],15); break;
case 2 : m_theAddresses[1].setStations( 1, 1, m_theLastAddress[38],15); break;
case 1 : m_theAddresses[1].setStations( 1, 2, m_theLastAddress[37],15); break;
case 0 : m_theAddresses[1].setStations( 1, 3, m_theLastAddress[36],15); break;
}
break;
}
case 17 : { tc = T124;
switch ( group ) {
case 3 : m_theAddresses[1].setStations( 0, 0,15, m_theLastAddress[35]); break;
case 2 : m_theAddresses[1].setStations( 0, 1,15, m_theLastAddress[34]); break;
case 1 : m_theAddresses[1].setStations( 0, 2,15, m_theLastAddress[33]); break;
case 0 : m_theAddresses[1].setStations( 0, 3,15, m_theLastAddress[32]); break;
}
break;
}
case 16 : { tc = T124;
switch ( group ) {
case 3 : m_theAddresses[1].setStations( 1, 0,15, m_theLastAddress[31]); break;
case 2 : m_theAddresses[1].setStations( 1, 1,15, m_theLastAddress[30]); break;
case 1 : m_theAddresses[1].setStations( 1, 2,15, m_theLastAddress[29]); break;
case 0 : m_theAddresses[1].setStations( 1, 3,15, m_theLastAddress[28]); break;
}
break;
}
case 15 : { tc = T134;
switch ( group ) {
case 3 : m_theAddresses[1].setStations( 0,15, 0, m_theLastAddress[27]); break;
case 2 : m_theAddresses[1].setStations( 0,15, 1, m_theLastAddress[26]); break;
case 1 : m_theAddresses[1].setStations( 0,15, 2, m_theLastAddress[25]); break;
case 0 : m_theAddresses[1].setStations( 0,15, 3, m_theLastAddress[24]); break;
}
break;
}
case 14 : { tc = T134;
switch ( group ) {
case 3 : m_theAddresses[1].setStations( 1,15, 0, m_theLastAddress[23]); break;
case 2 : m_theAddresses[1].setStations( 1,15, 1, m_theLastAddress[22]); break;
case 1 : m_theAddresses[1].setStations( 1,15, 2, m_theLastAddress[21]); break;
case 0 : m_theAddresses[1].setStations( 1,15, 3, m_theLastAddress[20]); break;
}
break;
}
case 13 : { tc = T234;
switch ( group ) {
case 3 : m_theAddresses[1].setStations(15, 0, 0, m_theLastAddress[19]); break;
case 2 : m_theAddresses[1].setStations(15, 0, 1, m_theLastAddress[18]); break;
case 1 : m_theAddresses[1].setStations(15, 0, 2, m_theLastAddress[17]); break;
case 0 : m_theAddresses[1].setStations(15, 0, 3, m_theLastAddress[16]); break;
}
break;
}
case 12 : { tc = T234;
switch ( group ) {
case 3 : m_theAddresses[1].setStations(15, 1, 0, m_theLastAddress[15]); break;
case 2 : m_theAddresses[1].setStations(15, 1, 1, m_theLastAddress[14]); break;
case 1 : m_theAddresses[1].setStations(15, 1, 2, m_theLastAddress[13]); break;
case 0 : m_theAddresses[1].setStations(15, 1, 3, m_theLastAddress[12]); break;
}
break;
}
case 11 : { tc = T12; m_theAddresses[1].setStations( 0, m_theLastAddressI[11],15,15); break; }
case 10 : { tc = T12; m_theAddresses[1].setStations( 1, m_theLastAddressI[10],15,15); break; }
case 9 : { tc = T13; m_theAddresses[1].setStations( 0,15, m_theLastAddressI[9],15); break; }
case 8 : { tc = T13; m_theAddresses[1].setStations( 1,15, m_theLastAddressI[8],15); break; }
case 7 : { tc = T14; m_theAddresses[1].setStations( 0,15,15, m_theLastAddressI[7]); break; }
case 6 : { tc = T14; m_theAddresses[1].setStations( 1,15,15, m_theLastAddressI[6]); break; }
case 5 : { tc = T23; m_theAddresses[1].setStations(15, 0, m_theLastAddressI[5],15); break; }
case 4 : { tc = T23; m_theAddresses[1].setStations(15, 1, m_theLastAddressI[4],15); break; }
case 3 : { tc = T24; m_theAddresses[1].setStations(15, 0,15, m_theLastAddressI[3]); break; }
case 2 : { tc = T24; m_theAddresses[1].setStations(15, 1,15, m_theLastAddressI[2]); break; }
case 1 : { tc = T34; m_theAddresses[1].setStations(15,15, 0, m_theLastAddressI[1]); break; }
case 0 : { tc = T34; m_theAddresses[1].setStations(15,15, 1, m_theLastAddressI[0]); break; }
}
// set Track Class and covert to bitmap
m_theTCs[1] = tc;
m_theBitMaps[1] = tc2bitmap(tc);
}
| void L1MuDTTrackAssembler::runEncoderSubUnit1 | ( | unsigned & | global, |
| unsigned & | group, | ||
| unsigned & | priority | ||
| ) | [private] |
run the first Priority Encoder Sub-Unit
Definition at line 494 of file L1MuDTTrackAssembler.cc.
References m_thePriorityTable1, priorityEncoder12(), priorityEncoder22(), priorityEncoder4(), subBitset68(), x, and detailsBasic3DVector::y.
Referenced by run().
{
// Global Grouping
bitset<22> exi;
exi[21] = m_thePriorityTable1[67] || m_thePriorityTable1[66] ||
m_thePriorityTable1[65] || m_thePriorityTable1[64] ||
m_thePriorityTable1[63] || m_thePriorityTable1[62] ||
m_thePriorityTable1[61] || m_thePriorityTable1[60] ||
m_thePriorityTable1[59] || m_thePriorityTable1[58] ||
m_thePriorityTable1[57] || m_thePriorityTable1[56];
exi[20] = m_thePriorityTable1[55] || m_thePriorityTable1[54] ||
m_thePriorityTable1[53] || m_thePriorityTable1[52] ||
m_thePriorityTable1[51] || m_thePriorityTable1[50] ||
m_thePriorityTable1[49] || m_thePriorityTable1[48] ||
m_thePriorityTable1[47] || m_thePriorityTable1[46] ||
m_thePriorityTable1[45] || m_thePriorityTable1[44];
exi[19] = m_thePriorityTable1[43] || m_thePriorityTable1[42] ||
m_thePriorityTable1[41] || m_thePriorityTable1[40];
exi[18] = m_thePriorityTable1[39] || m_thePriorityTable1[38] ||
m_thePriorityTable1[37] || m_thePriorityTable1[36];
exi[17] = m_thePriorityTable1[35] || m_thePriorityTable1[34] ||
m_thePriorityTable1[33] || m_thePriorityTable1[32];
exi[16] = m_thePriorityTable1[31] || m_thePriorityTable1[30] ||
m_thePriorityTable1[29] || m_thePriorityTable1[28];
exi[15] = m_thePriorityTable1[27] || m_thePriorityTable1[26] ||
m_thePriorityTable1[25] || m_thePriorityTable1[24];
exi[14] = m_thePriorityTable1[23] || m_thePriorityTable1[22] ||
m_thePriorityTable1[21] || m_thePriorityTable1[20];
exi[13] = m_thePriorityTable1[19] || m_thePriorityTable1[18] ||
m_thePriorityTable1[17] || m_thePriorityTable1[16];
exi[12] = m_thePriorityTable1[15] || m_thePriorityTable1[14] ||
m_thePriorityTable1[13] || m_thePriorityTable1[12];
exi[11] = m_thePriorityTable1[11];
exi[10] = m_thePriorityTable1[10];
exi[9] = m_thePriorityTable1[9];
exi[8] = m_thePriorityTable1[8];
exi[7] = m_thePriorityTable1[7];
exi[6] = m_thePriorityTable1[6];
exi[5] = m_thePriorityTable1[5];
exi[4] = m_thePriorityTable1[4];
exi[3] = m_thePriorityTable1[3];
exi[2] = m_thePriorityTable1[2];
exi[1] = m_thePriorityTable1[1];
exi[0] = m_thePriorityTable1[0];
// Global Priority Encoder
global = priorityEncoder22(exi);
if ( global == 31 ) {
group = 15;
priority = 0;
return;
}
// Group priority encoders
bitset<12> x;
x = subBitset68(m_thePriorityTable1,56,12);
unsigned int prio1234a = priorityEncoder12(x);
x = subBitset68(m_thePriorityTable1,44,12);
unsigned int prio1234b = priorityEncoder12(x);
bitset<4> y;
y = subBitset68(m_thePriorityTable1,40,4);
unsigned int prio123a = priorityEncoder4(y);
y = subBitset68(m_thePriorityTable1,36,4);
unsigned int prio123b = priorityEncoder4(y);
y = subBitset68(m_thePriorityTable1,32,4);
unsigned int prio124a = priorityEncoder4(y);
y = subBitset68(m_thePriorityTable1,28,4);
unsigned int prio124b = priorityEncoder4(y);
y = subBitset68(m_thePriorityTable1,24,4);
unsigned int prio134a = priorityEncoder4(y);
y = subBitset68(m_thePriorityTable1,20,4);
unsigned int prio134b = priorityEncoder4(y);
y = subBitset68(m_thePriorityTable1,16,4);
unsigned int prio234a = priorityEncoder4(y);
y = subBitset68(m_thePriorityTable1,12,4);
unsigned int prio234b = priorityEncoder4(y);
switch ( global ) {
case 21 : { group = prio1234a; priority = 56 + group; break; }
case 20 : { group = prio1234b; priority = 44 + group; break; }
case 19 : { group = prio123a; priority = 40 + group; break; }
case 18 : { group = prio123b; priority = 36 + group; break; }
case 17 : { group = prio124a; priority = 32 + group; break; }
case 16 : { group = prio124b; priority = 28 + group; break; }
case 15 : { group = prio134a; priority = 24 + group; break; }
case 14 : { group = prio134b; priority = 20 + group; break; }
case 13 : { group = prio234a; priority = 16 + group; break; }
case 12 : { group = prio234b; priority = 12 + group; break; }
default : { group = 15; priority = global; break; }
}
}
| void L1MuDTTrackAssembler::runEncoderSubUnit2 | ( | unsigned & | global, |
| unsigned & | group, | ||
| unsigned & | priority | ||
| ) | [private] |
run the second Priority Encoder Sub-Unit
Definition at line 596 of file L1MuDTTrackAssembler.cc.
References m_thePriorityTable2, priorityEncoder12(), priorityEncoder21(), priorityEncoder4(), subBitset56(), x, and detailsBasic3DVector::y.
Referenced by run().
{
// Global Grouping
bitset<21> exi;
exi[20] = m_thePriorityTable2[55] || m_thePriorityTable2[54] ||
m_thePriorityTable2[53] || m_thePriorityTable2[52] ||
m_thePriorityTable2[51] || m_thePriorityTable2[50] ||
m_thePriorityTable2[49] || m_thePriorityTable2[48] ||
m_thePriorityTable2[47] || m_thePriorityTable2[46] ||
m_thePriorityTable2[45] || m_thePriorityTable2[44];
exi[19] = m_thePriorityTable2[43] || m_thePriorityTable2[42] ||
m_thePriorityTable2[41] || m_thePriorityTable2[40];
exi[18] = m_thePriorityTable2[39] || m_thePriorityTable2[38] ||
m_thePriorityTable2[37] || m_thePriorityTable2[36];
exi[17] = m_thePriorityTable2[35] || m_thePriorityTable2[34] ||
m_thePriorityTable2[33] || m_thePriorityTable2[32];
exi[16] = m_thePriorityTable2[31] || m_thePriorityTable2[30] ||
m_thePriorityTable2[29] || m_thePriorityTable2[28];
exi[15] = m_thePriorityTable2[27] || m_thePriorityTable2[26] ||
m_thePriorityTable2[25] || m_thePriorityTable2[24];
exi[14] = m_thePriorityTable2[23] || m_thePriorityTable2[22] ||
m_thePriorityTable2[21] || m_thePriorityTable2[20];
exi[13] = m_thePriorityTable2[19] || m_thePriorityTable2[18] ||
m_thePriorityTable2[17] || m_thePriorityTable2[16];
exi[12] = m_thePriorityTable2[15] || m_thePriorityTable2[14] ||
m_thePriorityTable2[13] || m_thePriorityTable2[12];
exi[11] = m_thePriorityTable2[11];
exi[10] = m_thePriorityTable2[10];
exi[9] = m_thePriorityTable2[9];
exi[8] = m_thePriorityTable2[8];
exi[7] = m_thePriorityTable2[7];
exi[6] = m_thePriorityTable2[6];
exi[5] = m_thePriorityTable2[5];
exi[4] = m_thePriorityTable2[4];
exi[3] = m_thePriorityTable2[3];
exi[2] = m_thePriorityTable2[2];
exi[1] = m_thePriorityTable2[1];
exi[0] = m_thePriorityTable2[0];
// Global Priority Encoder
global = priorityEncoder21(exi);
if ( global == 31 ) {
group = 15;
priority = 0;
return;
}
// Group priority encoders
bitset<12> x;
x = subBitset56(m_thePriorityTable2,44,12);
unsigned int prio1234b = priorityEncoder12(x);
bitset<4> y;
y = subBitset56(m_thePriorityTable2,40,4);
unsigned int prio123a = priorityEncoder4(y);
y = subBitset56(m_thePriorityTable2,36,4);
unsigned int prio123b = priorityEncoder4(y);
y = subBitset56(m_thePriorityTable2,32,4);
unsigned int prio124a = priorityEncoder4(y);
y = subBitset56(m_thePriorityTable2,28,4);
unsigned int prio124b = priorityEncoder4(y);
y = subBitset56(m_thePriorityTable2,24,4);
unsigned int prio134a = priorityEncoder4(y);
y = subBitset56(m_thePriorityTable2,20,4);
unsigned int prio134b = priorityEncoder4(y);
y = subBitset56(m_thePriorityTable2,16,4);
unsigned int prio234a = priorityEncoder4(y);
y = subBitset56(m_thePriorityTable2,12,4);
unsigned int prio234b = priorityEncoder4(y);
switch ( global ) {
case 20 : { group = prio1234b; priority = 44 + group; break; }
case 19 : { group = prio123a; priority = 40 + group; break; }
case 18 : { group = prio123b; priority = 36 + group; break; }
case 17 : { group = prio124a; priority = 32 + group; break; }
case 16 : { group = prio124b; priority = 28 + group; break; }
case 15 : { group = prio134a; priority = 24 + group; break; }
case 14 : { group = prio134b; priority = 20 + group; break; }
case 13 : { group = prio234a; priority = 16 + group; break; }
case 12 : { group = prio234b; priority = 12 + group; break; }
default : { group = 15; priority = global; break; }
}
}
| unsigned long L1MuDTTrackAssembler::subBitset56 | ( | const std::bitset< 56 > & | input, |
| int | pos, | ||
| int | length | ||
| ) | [static, private] |
| unsigned long L1MuDTTrackAssembler::subBitset68 | ( | const std::bitset< 68 > & | input, |
| int | pos, | ||
| int | length | ||
| ) | [static, private] |
| const std::bitset<4>& L1MuDTTrackAssembler::trackBitMap | ( | int | id | ) | const [inline] |
return bitmap of found track
Definition at line 74 of file L1MuDTTrackAssembler.h.
References errorMatrix2Lands_multiChannel::id, and m_theBitMaps.
Referenced by L1MuDTAssignmentUnit::getPtMethod().
{ return m_theBitMaps[id]; }
| TrackClass L1MuDTTrackAssembler::trackClass | ( | int | id | ) | const [inline] |
return Track Class of found track
Definition at line 71 of file L1MuDTTrackAssembler.h.
References errorMatrix2Lands_multiChannel::id, and m_theTCs.
Referenced by L1MuDTAssignmentUnit::QuaAU(), and L1MuDTAssignmentUnit::run().
const L1MuDTSectorProcessor& L1MuDTTrackAssembler::m_sp [private] |
Definition at line 128 of file L1MuDTTrackAssembler.h.
Referenced by run().
L1MuDTAddressArray L1MuDTTrackAssembler::m_theAddresses[2] [private] |
Definition at line 137 of file L1MuDTTrackAssembler.h.
Referenced by address(), print(), reset(), run(), runAddressAssignment1(), and runAddressAssignment2().
std::bitset<4> L1MuDTTrackAssembler::m_theBitMaps[2] [private] |
Definition at line 136 of file L1MuDTTrackAssembler.h.
Referenced by print(), reset(), run(), runAddressAssignment1(), runAddressAssignment2(), and trackBitMap().
unsigned int L1MuDTTrackAssembler::m_theLastAddress[68] [private] |
Definition at line 132 of file L1MuDTTrackAssembler.h.
Referenced by reset(), run(), runAddressAssignment1(), and runAddressAssignment2().
unsigned int L1MuDTTrackAssembler::m_theLastAddressI[12] [private] |
Definition at line 133 of file L1MuDTTrackAssembler.h.
Referenced by reset(), run(), and runAddressAssignment2().
std::bitset<68> L1MuDTTrackAssembler::m_thePriorityTable1 [private] |
Definition at line 130 of file L1MuDTTrackAssembler.h.
Referenced by print(), reset(), run(), and runEncoderSubUnit1().
std::bitset<56> L1MuDTTrackAssembler::m_thePriorityTable2 [private] |
Definition at line 131 of file L1MuDTTrackAssembler.h.
Referenced by print(), reset(), run(), and runEncoderSubUnit2().
TrackClass L1MuDTTrackAssembler::m_theTCs[2] [private] |
Definition at line 135 of file L1MuDTTrackAssembler.h.
Referenced by isEmpty(), print(), reset(), run(), runAddressAssignment1(), runAddressAssignment2(), and trackClass().
1.7.3