/************************************************************************** * Copyright(c) 1998-1999, ALICE Experiment at CERN, All rights reserved. * * * * Author: The ALICE Off-line Project. * * Contributors are mentioned in the code where appropriate. * * * * Permission to use, copy, modify and distribute this software and its * * documentation strictly for non-commercial purposes is hereby granted * * without fee, provided that the above copyright notice appears in all * * copies and that both the copyright notice and this permission notice * * appear in the supporting documentation. The authors make no claims * * about the suitability of this software for any purpose. It is * * provided "as is" without express or implied warranty. * **************************************************************************/ /* $Id$ */ //_________________________________________________________________________ // Implementation of local trigger board objects // A local trigger board has as input a bit pattern and returns // the local trigger response after comparison w/ a LUT //*-- Author: Rachid Guernane (LPCCFd) //* //* #include "AliMUONLocalTriggerBoard.h" #include "AliMUONTriggerLut.h" #include "AliMUONTriggerConstants.h" #include "AliLog.h" #include #include //___________________________________________ AliMUONLocalTriggerBoard::AliMUONLocalTriggerBoard() : AliMUONTriggerBoard() { //* constructor //* fNumber = 0; for (Int_t i=0; i<2; i++) for (Int_t j=0; j<4; j++) { fXY[i][j] = fXYU[i][j] = fXYD[i][j] = 0; fMask[i][j] = 0xFFFF; } for (Int_t i=0; i<10; i++) fSwitch[i] = 0; fTC = kTRUE; fLUT = 0x0; for (Int_t i=0; i<5; i++) fMinDevStrip[i] = fMinDev[i] = fCoordY[i] = 0; fOutput = 0; fStripX11 = fStripY11 = fDev = 0; for (Int_t i=0; i<2; i++) fLutLpt[i] = fLutHpt[i] = fLutApt[i] = 0; } //___________________________________________ AliMUONLocalTriggerBoard::AliMUONLocalTriggerBoard(const char *name, Int_t a, AliMUONTriggerLut* lut) : AliMUONTriggerBoard(name, a) { //* constructor //* fNumber = 0; for (Int_t i=0; i<2; i++) for (Int_t j=0; j<4; j++) { fXY[i][j] = fXYU[i][j] = fXYD[i][j] = 0; fMask[i][j] = 0xFFFF; } for (Int_t i=0; i<10; i++) fSwitch[i] = 0; fTC = kTRUE; fLUT = lut; for (Int_t i=0; i<5; i++) fMinDevStrip[i] = fMinDev[i] = fCoordY[i] = 0; fOutput = 0; fStripX11 = fStripY11 = fDev = 0; for (Int_t i=0; i<2; i++) fLutLpt[i] = fLutHpt[i] = fLutApt[i] = 0; } //______________________________________________________________________________ AliMUONLocalTriggerBoard::AliMUONLocalTriggerBoard(const AliMUONLocalTriggerBoard& right) : AliMUONTriggerBoard(right) { /// Protected copy constructor (not implemented) AliFatal("Copy constructor not provided."); } //______________________________________________________________________________ AliMUONLocalTriggerBoard& AliMUONLocalTriggerBoard::operator=(const AliMUONLocalTriggerBoard& right) { /// Protected assignement operator (not implemented) // check assignement to self if (this == &right) return *this; AliFatal("Assignement operator not provided."); return *this; } //___________________________________________ void AliMUONLocalTriggerBoard::Reset() { //* reset board //* for (Int_t i=0; i<2; i++) for (Int_t j=0; j<4; j++) fXY[i][j] = fXYU[i][j] = fXYD[i][j] = 0; fResponse = 0; for (Int_t i=0; i<5; i++) fMinDevStrip[i] = fMinDev[i] = fCoordY[i] = 0; fOutput = 0; fStripX11 = fStripY11 = fDev = 0; for (Int_t i=0; i<2; i++) fLutLpt[i] = fLutHpt[i] = fLutApt[i] = 0; } //___________________________________________ void AliMUONLocalTriggerBoard::Setbit(Int_t strip, Int_t cathode, Int_t chamber) { // 0 .. LBS : N-1 .. MSB TBits w, m; UShort_t xy = fXY[cathode][chamber], mask = fMask[cathode][chamber]; w.Set(16,&xy); m.Set(16,&mask); Int_t s = strip - int(strip / 16) * 16; w.SetBitNumber(s); w &= m; UShort_t value; w.Get(&value); fXY[cathode][chamber] = value; } //___________________________________________ void AliMUONLocalTriggerBoard::SetbitM(Int_t strip, Int_t cathode, Int_t chamber) { // 0 .. LBS : N-1 .. MSB TBits w, m; UShort_t xy = fXY[cathode][chamber], mask = fMask[cathode][chamber]; w.Set(16,&xy); m.Set(16,&mask); w.SetBitNumber(strip); w &= m; UShort_t value; w.Get(&value); fXY[cathode][chamber] = value; } //___________________________________________ void AliMUONLocalTriggerBoard::Pattern(Option_t *option) { //* print bit pattern //* TString op = option; if (op.Contains("X")) BP("X"); if (op.Contains("Y")) BP("Y"); } //___________________________________________ void AliMUONLocalTriggerBoard::BP(Option_t *option) { // RESPECT THE OLD PRINTOUT FORMAT TString op = option; TString nn = GetName(); if (op.Contains("X")) { printf("-------- TRIGGER INPUT ---------\n"); printf("===============================================================\n"); printf(" 5432109876543210"); char *x[4] = {"XMC11","XMC12","XMC21","XMC22"}; char *s[4] = {" ", " ", " ", " "}; for (Int_t ch=0; ch<4; ch++) { printf("\n %s%s", x[ch], s[ch]); UShort_t xy = fXY[0][ch]; TBits w(16); w.Set(16,&xy); if (ch<2) cout << w; else { UShort_t xyd = fXYD[0][ch], xyu = fXYU[0][ch]; TBits dw(16), uw(16); dw.Set(16,&xyd); uw.Set(16,&xyu); TBits ew(32); for (Int_t i=0;i<16;i++) ew[i+8] = w[i]; for (Int_t i=0;i<8;i++) { ew[i] = dw[i+8]; // 8 MSB ew[i+24] = uw[i]; // } cout << ew; } } printf("\n "); printf("10987654321098765432109876543210\n"); } if (op.Contains("Y")) { printf("---------------------------------------------------------------\n"); printf(" "); /* OLD NUMBERING STYLE */ /**/ Int_t idCircuit = 0, absidModule = 0; if (!(nn.Contains("Int"))) { idCircuit = AliMUONTriggerConstants::CircuitId(GetI()); absidModule = TMath::Abs(Int_t(idCircuit/10)); } Int_t iModule=0; for (Int_t i=0; i<63; i++) { if (AliMUONTriggerConstants::ModuleId(i)==absidModule) { iModule=i; break; } } Int_t nStrip = AliMUONTriggerConstants::NstripY(iModule); for (Int_t istrip=nStrip-1; istrip>=0; istrip--) { if (istrip>9) printf("%i",istrip-10*Int_t(istrip/10)); if (istrip<10) printf("%i",istrip); } /**/ /* */ UShort_t xyval = 0; if (fSwitch[1]) { xyval = fXY[1][0]; TBits v11(8); v11.Set(8,&xyval); printf("\n YMC11 "); cout << v11; xyval = fXY[1][1]; TBits v12(8); v12.Set(8,&xyval); printf("\n YMC12 "); cout << v12; xyval = fXY[1][2]; TBits v21(8); v21.Set(8,&xyval); printf("\n YMC21 "); cout << v21; xyval = fXY[1][3]; TBits v22(8); v22.Set(8,&xyval); printf("\n YMC22 "); cout << v22 << endl; } else { xyval = fXY[1][0]; TBits v11(16); v11.Set(16,&xyval); printf("\n YMC11 "); cout << v11; xyval = fXY[1][1]; TBits v12(16); v12.Set(16,&xyval); printf("\n YMC12 "); cout << v12; xyval = fXY[1][2]; TBits v21(16); v21.Set(16,&xyval); printf("\n YMC21 "); cout << v21; xyval = fXY[1][3]; TBits v22(16); v22.Set(16,&xyval); printf("\n YMC22 "); cout << v22 << endl; } // tmp printf("---------------------------------------------------------------"); printf("\n upper part of circuit %i",idCircuit); printf("\n UMC21 "); xyval = fXYU[1][2]; TBits wu21(16); wu21.Set(16,&xyval); cout << wu21; printf("\n UMC22 "); xyval = fXYU[1][3]; TBits wu22(16); wu22.Set(16,&xyval); cout << wu22; printf("\n lower part of circuit %i",idCircuit); printf("\n LMC21 "); xyval = fXYD[1][2]; TBits wl21(16); wl21.Set(16,&xyval); cout << wl21; printf("\n LMC22 "); xyval = fXYD[1][3]; TBits wl22(16); wl22.Set(16,&xyval); cout << wl22; printf("\n"); printf("===============================================================\n"); } } //___________________________________________ void AliMUONLocalTriggerBoard::Conf() { //* board switches //* cout << "Switch(" << GetName() << ")" << " x2d = " << fSwitch[0] << " x2m = " << fSwitch[1] << " x2u = " << fSwitch[2] << " OR[0] = " << fSwitch[3] << " OR[1] = " << fSwitch[4] << " EN-Y = " << fSwitch[5] << " ZERO-ALLY-LSB = " << fSwitch[6] << " ZERO-down = " << fSwitch[7] << " ZERO-middle = " << fSwitch[8] << " ZERO-up = " << fSwitch[9] << " trans. conn. " << fTC << " Slot = " << fSlot << endl; } //___________________________________________ void AliMUONLocalTriggerBoard::Module(char *mod) { //* get module from name //* const Int_t kMaxfields = 2; char **fields = new char*[kMaxfields]; char s[100]; strcpy(s, GetName()); Int_t numlines = 0; for (char *token = strtok(s, "B"); token != NULL; token = strtok(NULL, " ")) { fields[numlines] = new char[strlen(token)+1]; strcpy(fields[numlines++],token); } strcpy(mod,fields[0]); } //___________________________________________ void AliMUONLocalTriggerBoard::TrigX(Int_t ch1q[16], Int_t ch2q[16], Int_t ch3q[32], Int_t ch4q[32], Int_t coinc44) { // note : coinc44 = flag 0 or 1 (0 coincidence -> 3/4, 1 coincidence -> 4/4) //--------------------------------------------------------- // step # 1 : declustering, reduction DS, calculate sgle & dble //--------------------------------------------------------- Int_t ch1e[19], ch2e[20], ch3e[35], ch4e[36]; Int_t sgleHit1[31], sgleHit2[63]; Int_t dbleHit1[31], dbleHit2[63]; Int_t i; Int_t j; Int_t istrip; for (i=0; i<31; i++) { sgleHit1[i]=0; dbleHit1[i]=0; } for (i=0; i<63; i++) { sgleHit2[i]=0; dbleHit2[i]=0; } //--- inititialize che using chq for (i=0; i<19; i++) { if (i<1||i>16) ch1e[i]=0; else ch1e[i]=ch1q[i-1]; } for (i=0; i<20; i++) { if (i<2||i>17) ch2e[i]=0; else ch2e[i]=ch2q[i-2]; } for (i=0; i<35; i++) { if (i<1||i>32) ch3e[i]=0; else ch3e[i]=ch3q[i-1]; } for (i=0; i<36; i++) { if (i<2||i>33) ch4e[i]=0; else ch4e[i]=ch4q[i-2]; } //--- calculate dble & sgle first station for (i=0; i<=15; i++) { sgleHit1[2*i] = (!ch1e[i+1]|(ch1e[i]^ch1e[i+2])) & (!ch2e[i+2] | (ch2e[i+1]^ch2e[i+3])); dbleHit1[2*i] = ch1e[i+1]&!(ch1e[i+2]^ch1e[i]) & (ch2e[i+2] | (!ch2e[i]&ch2e[i+1]) | (ch2e[i+3]&!ch2e[i+4])); } for (i=0; i<=14; i++) { sgleHit1[2*i+1] = (!ch1e[i+1]|!ch1e[i+2]|(ch1e[i]^ch1e[i+3])) & (!ch2e[i+2] | !ch2e[i+3] | (ch2e[i+1]^ch2e[i+4])); dbleHit1[2*i+1] = ch1e[i+1]&ch1e[i+2]&!(ch1e[i]^ch1e[i+3]) & (ch2e[i+2]&(!ch2e[i+1]|!ch2e[i]) | ch2e[i+3]&(ch2e[i+2]|!ch2e[i+4]|!ch2e[i+5])); } //--- calculate dble & sgle second station for (i=0; i<=31; i++) { sgleHit2[2*i] = (!ch3e[i+1]|(ch3e[i]^ch3e[i+2])) & (!ch4e[i+2] | (ch4e[i+1]^ch4e[i+3])); dbleHit2[2*i] = ch3e[i+1]&!(ch3e[i+2]^ch3e[i]) & (ch4e[i+2] | (!ch4e[i]&ch4e[i+1]) | (ch4e[i+3]&!ch4e[i+4])); } for (i=0; i<=30; i++) { sgleHit2[2*i+1] = (!ch3e[i+1]|!ch3e[i+2]|(ch3e[i]^ch3e[i+3])) & (!ch4e[i+2] | !ch4e[i+3] | (ch4e[i+1]^ch4e[i+4])); dbleHit2[2*i+1] = ch3e[i+1]&ch3e[i+2]&!(ch3e[i]^ch3e[i+3]) & (ch4e[i+2]&(!ch4e[i+1]|!ch4e[i]) | ch4e[i+3]&(ch4e[i+2]|!ch4e[i+4]|!ch4e[i+5])); } //--- if(AliDebugLevel()==3||AliDebugLevel()==5) { printf("===============================================================\n"); printf(" X plane after sgle and dble \n"); printf(" 0987654321098765432109876543210"); printf("\n SGLE1 "); for (istrip=30; istrip>=0; istrip--) printf("%i",(!sgleHit1[istrip])); printf("\n DBLE1 "); for (istrip=30; istrip>=0; istrip--) printf("%i",dbleHit1[istrip]); printf("\n SGLE2 "); for (istrip=62; istrip>=0; istrip--) printf("%i",(!sgleHit2[istrip])); printf("\n DBLE2 "); for (istrip=62; istrip>=0; istrip--) printf("%i",dbleHit2[istrip]); printf("\n 210987654321098765432109876543210987654321098765432109876543210\n"); } //--------------------------------------------------------- // step # 2 : coincidence 3/4 //--------------------------------------------------------- Int_t rearImage[31][31]; for (i=0; i<31; i++) { for (j=0; j<31; j++) { rearImage[i][j]=0; } } Int_t notOr1=!dbleHit1[30] & !dbleHit1[29] & !dbleHit1[28] & !dbleHit1[27] & !dbleHit1[26] & !dbleHit1[25] & !dbleHit1[24] & !dbleHit1[23] & !dbleHit1[22] & !dbleHit1[21] & !dbleHit1[20] & !dbleHit1[19] & !dbleHit1[18] & !dbleHit1[17] & !dbleHit1[16] & !dbleHit1[15] & !dbleHit1[14] & !dbleHit1[13] & !dbleHit1[12] & !dbleHit1[11] & !dbleHit1[10] & !dbleHit1[9] & !dbleHit1[8] & !dbleHit1[7] & !dbleHit1[6] & !dbleHit1[5] & !dbleHit1[4] & !dbleHit1[3] & !dbleHit1[2] & !dbleHit1[1] & !dbleHit1[0] & !coinc44; Int_t notOr2= !dbleHit2[62] & !dbleHit2[61] & !dbleHit2[60] & !dbleHit2[59] & !dbleHit2[58] & !dbleHit2[57] & !dbleHit2[56] & !dbleHit2[55] & !dbleHit2[54] & !dbleHit2[53] & !dbleHit2[52] & !dbleHit2[51] & !dbleHit2[50] & !dbleHit2[49] & !dbleHit2[48] & !dbleHit2[47] & !dbleHit2[46] & !dbleHit2[45] & !dbleHit2[44] & !dbleHit2[43] & !dbleHit2[42] & !dbleHit2[41] & !dbleHit2[40] & !dbleHit2[39] & !dbleHit2[38] & !dbleHit2[37] & !dbleHit2[36] & !dbleHit2[35] & !dbleHit2[34] & !dbleHit2[33] & !dbleHit2[32] & !dbleHit2[31] & !dbleHit2[30] & !dbleHit2[29] & !dbleHit2[28] & !dbleHit2[27] & !dbleHit2[26] & !dbleHit2[25] & !dbleHit2[24] & !dbleHit2[23] & !dbleHit2[22] & !dbleHit2[21] & !dbleHit2[20] & !dbleHit2[19] & !dbleHit2[18] & !dbleHit2[17] & !dbleHit2[16] & !dbleHit2[15] & !dbleHit2[14] & !dbleHit2[13] & !dbleHit2[12] & !dbleHit2[11] & !dbleHit2[10] & !dbleHit2[9] & !dbleHit2[8] & !dbleHit2[7] & !dbleHit2[6] & !dbleHit2[5] & !dbleHit2[4] & !dbleHit2[3] & !dbleHit2[2] & !dbleHit2[1] & !dbleHit2[0] & !coinc44; // DS reduction for (i=0; i<31; i++) { sgleHit1[i] = !sgleHit1[i]¬Or1; } for (i=0; i<63; i++) { sgleHit2[i] = !sgleHit2[i]¬Or2; } // extract rearImage for (i=0; i<31; i++){ Int_t tmpSgleHit2[31]; Int_t tmpDbleHit2[31]; for (j=0; j<31; j++){ tmpSgleHit2[j] = sgleHit2[i+j+1]; tmpDbleHit2[j] = dbleHit2[i+j+1]; } for (Int_t k=0; k<31; k++) { rearImage[i][k]=(sgleHit1[i]&tmpDbleHit2[k])| (dbleHit1[i]&(tmpSgleHit2[k]|tmpDbleHit2[k])); } } //----------- if(AliDebugLevel()==3||AliDebugLevel()==5) { printf("===============================================================\n"); for (i=30; i>=0; i--) { printf("%i \t",i); for (istrip=31; istrip>=0; istrip--) printf("%i",rearImage[i][istrip]); printf("\n"); } } //--------------------------------------------------------- // step # 3 : calculate deviation //--------------------------------------------------------- Int_t dev[31][6]; for (i=0; i<31; i++) { for (j=0; j<6; j++) { dev[i][j]=0; } } for (i=0; i<31; i++){ Int_t leftDev[5], rightDev[5]; Int_t orL1, andL1, andL2, orR1, orR2, andR1, andR2, andR3; // calculate Left deviation orL1=rearImage[i][16]|rearImage[i][18]|rearImage[i][20]|rearImage[i][22]; andL1=!rearImage[i][17]&!rearImage[i][19]&!rearImage[i][21] & !orL1; andL2=!rearImage[i][23]&!rearImage[i][24]&!rearImage[i][25]&!rearImage[i][26]; leftDev[0] = (rearImage[i][16]|!rearImage[i][17]) & (rearImage[i][16]|rearImage[i][18]|!rearImage[i][19]& (rearImage[i][20]|!rearImage[i][21])) & (orL1|!rearImage[i][23]&(rearImage[i][24]|!rearImage[i][25])) & (orL1|rearImage[i][24]|rearImage[i][26]|!rearImage[i][27]& (rearImage[i][28]|!rearImage[i][29])); leftDev[1] = !rearImage[i][16] & !(!rearImage[i][17]&!rearImage[i][18]&!rearImage[i][21]&!rearImage[i][22] & (!rearImage[i][25]&!rearImage[i][26]&(rearImage[i][27]|rearImage[i][28]))) & (rearImage[i][17]|rearImage[i][18] | !rearImage[i][19]&!rearImage[i][20]) & (rearImage[i][17]|rearImage[i][18]|rearImage[i][21]|rearImage[i][22] | !rearImage[i][23]&!rearImage[i][24]); leftDev[2] = (!rearImage[i][16]&!rearImage[i][17]&!rearImage[i][18]) & (rearImage[i][19]|rearImage[i][20]|rearImage[i][21]|rearImage[i][22] | andL2); leftDev[3] = andL1; leftDev[4] = !rearImage[i][27]&!rearImage[i][28]&!rearImage[i][29]&!rearImage[i][30] & andL1 & andL2; // calculate Right deviation orR1=rearImage[i][8]|rearImage[i][10]|rearImage[i][12]|rearImage[i][14]; orR2=rearImage[i][8]|rearImage[i][9]|rearImage[i][10]|rearImage[i][11]; andR1=!rearImage[i][12]&!rearImage[i][13]&!rearImage[i][14]&!rearImage[i][15]; andR2= !rearImage[i][8]&!rearImage[i][9]&!rearImage[i][10]&!rearImage[i][11] & andR1; andR3=!rearImage[i][4]&!rearImage[i][5]&!rearImage[i][6]&!rearImage[i][7]; rightDev[0] = !rearImage[i][15]&(rearImage[i][14]|!rearImage[i][13]) & ((rearImage[i][12]|rearImage[i][14]|!rearImage[i][11]& (rearImage[i][10]|!rearImage[i][9])) & ((orR1|!rearImage[i][7]&(rearImage[i][6]|!rearImage[i][5])) & (orR1|rearImage[i][4]|rearImage[i][6]|!rearImage[i][3]&(rearImage[i][2]| !rearImage[i][1])))); rightDev[1] = !rearImage[i][15]&!rearImage[i][14] & !(!rearImage[i][4]&!rearImage[i][5]&!rearImage[i][8]&!rearImage[i][9] & (!rearImage[i][12]&!rearImage[i][13]&(rearImage[i][2]|rearImage[i][3]))) & (rearImage[i][12]|rearImage[i][13] | !rearImage[i][10]&!rearImage[i][11]) & (rearImage[i][8]|rearImage[i][9]|rearImage[i][12]|rearImage[i][13] | !rearImage[i][6]&!rearImage[i][7]); rightDev[2] = andR1 & (orR2 | andR3); rightDev[3] = andR2; rightDev[4] = !rearImage[i][0]&!rearImage[i][1]&!rearImage[i][2]&!rearImage[i][3] & andR2 & andR3 ; // compare Left & Right deviations Int_t tmpLeftDev=0, tmpRightDev=0; for (j=0; j<5; j++){ tmpLeftDev = tmpLeftDev + Int_t(leftDev[j]<=0; i--) { printf("%i \t",i); for (istrip=5; istrip>=0; istrip--) printf("%i",dev[i][istrip]); printf(" \n"); } } //--------------------------------------------------------- // step # 4 : sort deviation //--------------------------------------------------------- Int_t bga1[16], bga2[8], bga3[4], bga4[2], bga5; Int_t tmpbga1[16][6], tmpbga2[8][6], tmpbga3[4][6], tmpbga4[2][6], tmpbga5[6]; Int_t tmpMax[6]={1,1,1,1,1,0}; for (i=0; i<15; i++) { Sort2x5(dev[2*i],dev[2*i+1],tmpbga1[i],bga1[i]); } Sort2x5(dev[30],tmpMax,tmpbga1[15],bga1[15]); //-- if(AliDebugLevel()==3||AliDebugLevel()==5) { printf("===============================================================\n"); printf(" sorting : 1st level \n"); for (i=15; i>=0; i--) { printf("\t %i \t",bga1[i]); for (j=5; j>=0; j--) printf("%i",tmpbga1[i][j]); printf(" \n"); } } for (i=0; i<8; i++) { Sort2x5(tmpbga1[2*i],tmpbga1[2*i+1],tmpbga2[i],bga2[i]); } //-- if(AliDebugLevel()==3||AliDebugLevel()==5) { printf("===============================================================\n"); printf(" sorting : 2nd level \n"); for (i=7; i>=0; i--) { printf("\t %i \t",bga2[i]); for (j=5; j>=0; j--) printf("%i",tmpbga1[i][j]); printf(" \n"); } } for (i=0; i<4; i++) { Sort2x5(tmpbga2[2*i],tmpbga2[2*i+1],tmpbga3[i],bga3[i]); } //-- if(AliDebugLevel()==3||AliDebugLevel()==5) { printf("===============================================================\n"); printf(" sorting : 3rd level \n"); for (i=3; i>=0; i--) { printf("\t %i \t",bga3[i]); for (j=5; j>=0; j--) printf("%i",tmpbga3[i][j]); printf(" \n"); } } for (i=0; i<2; i++) { Sort2x5(tmpbga3[2*i],tmpbga3[2*i+1],tmpbga4[i],bga4[i]); } //-- if(AliDebugLevel()==3||AliDebugLevel()==5) { printf("===============================================================\n"); printf(" sorting : 4th level \n"); for (i=1; i>=0; i--) { printf("\t %i \t",bga4[i]); for (j=5; j>=0; j--) printf("%i",tmpbga4[i][j]); printf(" \n"); } } Sort2x5(tmpbga4[0],tmpbga4[1],tmpbga5,bga5); // coding from 6 to 5 bits fMinDev[4] = tmpbga5[5] | tmpbga5[4]; for (i=0; i<4; i++) { fMinDev[i]=tmpbga5[i] & !tmpbga5[4]; } // find address of strip with minimum deviation fMinDevStrip[4]=bga5; if (bga5<=1) fMinDevStrip[3]=bga4[bga5]; Int_t tmpAd=fMinDevStrip[3]+fMinDevStrip[4]*2; if (tmpAd<=3) fMinDevStrip[2]=bga3[tmpAd]; tmpAd=fMinDevStrip[2]+fMinDevStrip[3]*2+fMinDevStrip[4]*4; if (tmpAd<=7) fMinDevStrip[1]=bga2[tmpAd]; tmpAd=fMinDevStrip[1]+fMinDevStrip[2]*2+fMinDevStrip[3]*4+fMinDevStrip[4]*8; if (tmpAd<=15) fMinDevStrip[0]=bga1[tmpAd]; if(AliDebugLevel()==3||AliDebugLevel()==5) { printf("===============================================================\n"); printf("minDevStrip = "); for (i=4; i>=0; i--) printf("%i",fMinDevStrip[i]); printf(" minDev = "); for (i=4; i>=0; i--) printf("%i",fMinDev[i]); printf(" \n"); printf("===============================================================\n"); } } //___________________________________________ void AliMUONLocalTriggerBoard::Sort2x5(Int_t dev1[6], Int_t dev2[6], Int_t minDev[6], Int_t &dev1GTdev2) { // returns minimun between dev1 and dev2 Int_t tmpDev1=0, tmpDev2=0; for (Int_t j=0; j<5; j++) { tmpDev1 += Int_t(dev1[j]< cancel //--------------------------------------------------------- // step # 1 : prehandling Y //--------------------------------------------------------- Int_t i; Int_t istrip; for (i=0; i<16; i++) { y3[i]=y3[i]&!fSwitch[8]; y4[i]=y4[i]&!fSwitch[8]; } // 10/29/04 fZeroAllYLSB added // for (i=0; i<8; i++) // { // y1[i] = y1[i]&!fSwitch[6]; // y2[i] = y2[i]&!fSwitch[6]; // y3[i] = y3[i]&!fSwitch[6]; // y4[i] = y4[i]&!fSwitch[6]; // } Int_t ch1[16], ch2[16], ch3[16], ch4[16]; Int_t tmpy3to16[16], tmpy4to16[16]; Int_t tmpy3uto16[16], tmpy3dto16[16], tmpy4uto16[16], tmpy4dto16[16]; for (i=0; i<8; i++){ ch1[2*i] = y1[i]&fSwitch[1] | y1[2*i]&!fSwitch[1]; ch1[2*i+1] = y1[i]&fSwitch[1] | y1[2*i+1]&!fSwitch[1]; ch2[2*i] = y2[i]&fSwitch[1] | y2[2*i]&!fSwitch[1]; ch2[2*i+1] = y2[i]&fSwitch[1] | y2[2*i+1]&!fSwitch[1]; tmpy3to16[2*i ] = y3[i]&fSwitch[1] | y3[2*i ]&!fSwitch[1]; tmpy3to16[2*i+1] = y3[i]&fSwitch[1] | y3[2*i+1]&!fSwitch[1]; tmpy4to16[2*i ] = y4[i]&fSwitch[1] | y4[2*i ]&!fSwitch[1]; tmpy4to16[2*i+1] = y4[i]&fSwitch[1] | y4[2*i+1]&!fSwitch[1]; tmpy3uto16[2*i ] = y3u[i]&fSwitch[2] | y3u[2*i ]&!fSwitch[2]; tmpy3uto16[2*i+1] = y3u[i]&fSwitch[2] | y3u[2*i+1]&!fSwitch[2]; tmpy4uto16[2*i ] = y4u[i]&fSwitch[2] | y4u[2*i ]&!fSwitch[2]; tmpy4uto16[2*i+1] = y4u[i]&fSwitch[2] | y4u[2*i+1]&!fSwitch[2]; tmpy3dto16[2*i ] = y3d[i]&fSwitch[0] | y3d[2*i ]&!fSwitch[0]; tmpy3dto16[2*i+1] = y3d[i]&fSwitch[0] | y3d[2*i+1]&!fSwitch[0]; tmpy4dto16[2*i ] = y4d[i]&fSwitch[0] | y4d[2*i ]&!fSwitch[0]; tmpy4dto16[2*i+1] = y4d[i]&fSwitch[0] | y4d[2*i+1]&!fSwitch[0]; } if (fSwitch[3]==0&&fSwitch[4]==0){ for (i=0; i<16; i++){ ch3[i] = tmpy3to16[i]; ch4[i] = tmpy4to16[i]; } } if (fSwitch[3]==0&&fSwitch[4]==1){ for (i=0; i<16; i++){ ch3[i] = tmpy3dto16[i]|tmpy3to16[i]; ch4[i] = tmpy4dto16[i]|tmpy4to16[i]; } } if (fSwitch[3]==1&&fSwitch[4]==0){ for (i=0; i<16; i++){ ch3[i] = tmpy3uto16[i]|tmpy3to16[i]; ch4[i] = tmpy4uto16[i]|tmpy4to16[i]; } } if (fSwitch[3]==1&&fSwitch[4]==1){ for (i=0; i<16; i++){ ch3[i] = tmpy3dto16[i]|tmpy3to16[i]|tmpy3uto16[i]; ch4[i] = tmpy4dto16[i]|tmpy4to16[i]|tmpy4uto16[i]; } } // debug if(AliDebugLevel()==4||AliDebugLevel()==5) { printf("===============================================================\n"); printf(" Y plane after PreHandling x2m x2u x2d orMud %i %i %i %i %i \n", fSwitch[1],fSwitch[2], fSwitch[0],fSwitch[3],fSwitch[4]); printf(" "); for (istrip=15; istrip>=0; istrip--) { if (istrip>9) printf("%i",istrip-10*Int_t(istrip/10)); if (istrip<10) printf("%i",istrip); } printf("\n YMC11 "); for (istrip=15; istrip>=0; istrip--) printf("%i",ch1[istrip]); printf("\n YMC12 "); for (istrip=15; istrip>=0; istrip--) printf("%i",ch2[istrip]); printf("\n YMC21 "); for (istrip=15; istrip>=0; istrip--) printf("%i",ch3[istrip]); printf("\n YMC22 "); for (istrip=15; istrip>=0; istrip--) printf("%i",ch4[istrip]); printf(" \n"); } //debug //--------------------------------------------------------- // step # 2 : calculate sgle and dble, apply DS reduction //--------------------------------------------------------- Int_t sgle1[16], dble1[16]; Int_t sgle2[16], dble2[16]; // Calculate simple and double hits for (i=0; i<16; i++) { dble1[i] = ch1[i] & ch2[i]; dble2[i] = ch3[i] & ch4[i]; sgle1[i] = (ch1[i]|ch2[i]); sgle2[i] = (ch3[i]|ch4[i]); } //debug if(AliDebugLevel()==4||AliDebugLevel()==5) { printf("===============================================================\n"); printf(" Y plane after sgle dble \n"); printf(" "); for (istrip=15; istrip>=0; istrip--) { if (istrip>9) printf("%i",istrip-10*Int_t(istrip/10)); if (istrip<10) printf("%i",istrip); } printf("\n SGLE1 "); for (istrip=15; istrip>=0; istrip--) printf("%i",sgle1[istrip]); printf("\n DBLE1 "); for (istrip=15; istrip>=0; istrip--) printf("%i",dble1[istrip]); printf("\n SGLE2 "); for (istrip=15; istrip>=0; istrip--) printf("%i",sgle2[istrip]); printf("\n DBLE2 "); for (istrip=15; istrip>=0; istrip--) printf("%i",dble2[istrip]); printf(" \n"); } //debug // DS Reduction Int_t notOr1, notOr2; notOr1=!dble1[15] & !dble1[14] & !dble1[13] & !dble1[12] & !dble1[11] & !dble1[10] & !dble1[9] & !dble1[8] & !dble1[7] & !dble1[6] & !dble1[5] & !dble1[4] & !dble1[3] & !dble1[2] & !dble1[1] & !dble1[0]; notOr2=!dble2[15] & !dble2[14] & !dble2[13] & !dble2[12] & !dble2[11] & !dble2[10] & !dble2[9] & !dble2[8] & !dble2[7] & !dble2[6] & !dble2[5] & !dble2[4] & !dble2[3] & !dble2[2] & !dble2[1] & !dble2[0]; for (i=0; i<16; i++) { sgle1[i] = sgle1[i] & notOr1 & !coinc44; sgle2[i] = sgle2[i] & notOr2 & !coinc44; } //--------------------------------------------------------- // step # 3 : 3/4 coincidence //--------------------------------------------------------- Int_t frontImage[16]; for (i=1; i<15; i++) { frontImage[i] = (dble1[i] | sgle1[i]) & (dble2[i+1] | dble2[i] | dble2[i-1]) | dble1[i] & (sgle2[i+1] | sgle2[i] | sgle2[i-1]); } frontImage[0] = (dble1[0] | sgle1[0]) & (dble2[1] | dble2[0]) | dble1[0] & (sgle2[1] | sgle2[0]); frontImage[15] = (dble1[15] | sgle1[15]) & (dble2[15] | dble2[14]) | dble1[15] & (sgle2[15] | sgle2[14]); //debug if(AliDebugLevel()==4||AliDebugLevel()==5) { printf("===============================================================\n"); printf(" Y plane frontImage\n"); printf(" "); for (istrip=15; istrip>=0; istrip--) { if (istrip>9) printf("%i",istrip-10*Int_t(istrip/10)); if (istrip<10) printf("%i",istrip); } printf("\n "); for (istrip=15; istrip>=0; istrip--) printf("%i",frontImage[istrip]); printf("\n"); } //debug //--------------------------------------------------------- // step # 4 : Y position //--------------------------------------------------------- Int_t or1, or2, and1, and2, and3; or1 = frontImage[7]|frontImage[5]|frontImage[3]|frontImage[1]; or2 = frontImage[7]|frontImage[6]|frontImage[5]|frontImage[4]; and1 = !frontImage[3]&!frontImage[2]&!frontImage[1]&!frontImage[0]; and2 = !frontImage[7]&!frontImage[6]&!frontImage[5]&!frontImage[4] & and1; and3 = !frontImage[11]&!frontImage[10]&!frontImage[9]&!frontImage[8]; fCoordY[0] = !frontImage[0]&(frontImage[1]|!frontImage[2]) & (frontImage[3]|frontImage[1]|!frontImage[4]&(frontImage[5]|!frontImage[6])) & (or1|!frontImage[8]&(frontImage[9]|!frontImage[10])) & (or1|frontImage[11]|frontImage[9]|!frontImage[12]&(frontImage[13]|!frontImage[14])); fCoordY[1] = !frontImage[0]&!frontImage[1] & !(!frontImage[11]&!frontImage[10]&!frontImage[7]&!frontImage[6] & !frontImage[3]&!frontImage[2]&(frontImage[13]|frontImage[12])) & (frontImage[3]|frontImage[2] | !frontImage[5]&!frontImage[4]) & (frontImage[7]|frontImage[6]|frontImage[3]|frontImage[2] | !frontImage[9]&!frontImage[8]); fCoordY[2] = and1 & (or2 | and3); fCoordY[3] = and2; fCoordY[4] = !frontImage[15]&!frontImage[14]&!frontImage[13]&!frontImage[12] & and2 & and3 ; } //___________________________________________ void AliMUONLocalTriggerBoard::LocalTrigger() { //* L0 trigger after LUT //* Int_t deviation=0, iStripY=0; for (Int_t i=0; i<4; i++) deviation += static_cast( fMinDev[i] << i ); for (Int_t i=0; i<4; i++) iStripY += static_cast( fCoordY[i] << i ); if (fMinDev[4]==1 && !deviation) fOutput=0; // No trigger else { if (fCoordY[4]==1 && iStripY==15) fOutput=0; // No trigger else fOutput=1; } if (fOutput) { for (Int_t i=0; i<5; i++) fStripX11 += static_cast( fMinDevStrip[i] << i ); fDev = deviation; fStripY11 = iStripY; if ( fSwitch[1] && (fSwitch[0] || fSwitch[2]) && !(!fSwitch[0] && fSwitch[4]) && !(!fSwitch[2] && fSwitch[3]) ) fStripY11 /= 2; Int_t sign = 0; if ( !fMinDev[4] && deviation ) sign=-1; if ( !fMinDev[4] && !deviation ) sign= 0; if ( fMinDev[4]==1) sign=+1; fDev *= sign; // calculate deviation in [0;+30] fDev += 15; Int_t icirc = GetI(); // LEFT SHIFT OF ZERO-ALLY-LSB BOARDS TO ACCESS TO LUT if (GetSwitch(6)) fStripY11 -= 8; // GET LUT OUTPUT FOR icirc/istripX1/deviation/istripY fLUT->GetLutOutput(icirc, fStripX11, fDev, fStripY11, fLutLpt, fLutHpt, fLutApt); } } //___________________________________________ Int_t AliMUONLocalTriggerBoard::GetI() { //* old numbering //* const Int_t kMaxfields = 2; char **fields = new char*[kMaxfields]; char s[100]; strcpy(s, GetName()); Int_t numlines = 0; for (char *token = strtok(s, "B"); token != NULL; token = strtok(NULL, " ")) { fields[numlines] = new char[strlen(token)+1]; strcpy(fields[numlines++], token); } TString l(fields[0]); char copy = l[0]; Int_t lL = atoi(&l[4]), cC = atoi(&l[2]), sS = (copy=='R') ? +1 : -1; char *b[4] = {"12", "34", "56", "78"}; Int_t ib = 0; for (Int_t i=0; i<4; i++) if (!strcmp(fields[1],b[i])) {ib = i; break;} ib++; // lL=1 ON TOP lL -= 9; lL = abs(lL); lL++; Int_t code = 100 * lL + 10 * cC + ib; code *= sS; Int_t ic = 0; for (Int_t i=0; i<234; i++) if (AliMUONTriggerConstants::CircuitId(i) == code) {ic = i; break;} return ic; } //___________________________________________ void AliMUONLocalTriggerBoard::Mask(Int_t index, UShort_t mask) { //* set mask //* if ( index >= 0 && index < 2*4 ) { Int_t i = index/4; Int_t j = index - i*4; fMask[i][j]=mask; } else { AliError(Form("Index %d out of bounds (max %d)",index,8)); } } //___________________________________________ void AliMUONLocalTriggerBoard::Scan(Option_t *option) { //* full dump //* TString op = option; if (op.Contains("CONF")) Conf(); if (op.Contains("BITP")) Pattern(); if (op.Contains("RESPI")) Resp("I"); if (op.Contains("RESPF")) Resp("F"); if (op.Contains("ALL")) { Conf(); Pattern(); Resp("I"); Resp("F"); } } //___________________________________________ void AliMUONLocalTriggerBoard::Resp(Option_t *option) { //* board I/O //* TString op = option; if (op.Contains("I")) { // print Local trigger output before the LuT step printf("===============================================================\n"); printf("-------- TRIGGER OUTPUT --------\n"); printf("minDevStrip = "); for (Int_t i=4; i>=0; i--) printf("%i",fMinDevStrip[i]); printf(" minDev = "); for (Int_t i=4; i>=0; i--) printf("%i",fMinDev[i]); printf(" coordY = "); for (Int_t i=4; i>=0; i--) printf("%i",fCoordY[i]); printf(" \n"); } if (op.Contains("F")) { Int_t icirc = GetI(); Int_t idCircuit = AliMUONTriggerConstants::CircuitId(icirc); Int_t deviation = 0, iStripY = 0; for (Int_t i=0; i<4; i++) iStripY += static_cast( fCoordY[i] << i ); for (Int_t i=0; i<4; i++) deviation += Int_t(fMinDev[i]<PtCal(fStripX11, fDev, fStripY11); printf("-------------------------------------------\n"); printf(" Local Trigger info for circuit Id %i (number %i ) \n", idCircuit, icirc); printf(" istripX1 signDev deviation istripY = %i %i %i %i \n", fStripX11, fMinDev[4], deviation, iStripY); printf(" pt = %f (GeV/c) \n", pt); printf("-------------------------------------------\n"); printf(" Local Trigger Lut Output = Lpt : "); for (Int_t i=1; i>=0; i--) printf("%i", fLutLpt[i]); printf(" Hpt : "); for (Int_t i=1; i>=0; i--) printf("%i", fLutHpt[i]); printf(" Apt : "); for (Int_t i=1; i>=0; i--) printf("%i", fLutApt[i]); printf("\n"); printf("-------------------------------------------\n"); } } //___________________________________________ void AliMUONLocalTriggerBoard::Response() { //* algo //* Int_t xX1[16], xX2[16], xXX3[32], xXX4[32]; TBits x1(16), x2(16), x3(16), x4(16); UShort_t xyv = 0; xyv = fXY[0][0]; x1.Set(16,&xyv); xyv = fXY[0][1]; x2.Set(16,&xyv); xyv = fXY[0][2]; x3.Set(16,&xyv); xyv = fXY[0][3]; x4.Set(16,&xyv); TBits x3u(16), x4u(16), x3d(16), x4d(16); xyv = fXYU[0][2]; x3u.Set(16,&xyv); xyv = fXYU[0][3]; x4u.Set(16,&xyv); xyv = fXYD[0][2]; x3d.Set(16,&xyv); xyv = fXYD[0][3]; x4d.Set(16,&xyv); for (Int_t i=0;i<16;i++) { xX1[i] = x1[i]; xX2[i] = x2[i]; xXX3[i+8] = x3[i]; xXX4[i+8] = x4[i]; } for (Int_t i=0;i<8;i++) { xXX3[i] = x3d[i+8]; xXX4[i] = x4d[i+8]; xXX3[i+24] = x3u[i]; xXX4[i+24] = x4u[i]; } Int_t coinc44 = 0; TrigX(xX1, xX2, xXX3, xXX4, coinc44); Int_t yY1[16], yY2[16], yY3[16], yY4[16]; Int_t yY3U[16], yY3D[16], yY4U[16], yY4D[16]; TBits y1(16), y2(16), y3(16), y4(16); TBits y3u(16), y3d(16), y4u(16), y4d(16); xyv = fXY[1][0]; y1.Set(16,&xyv); xyv = fXY[1][1]; y2.Set(16,&xyv); xyv = fXY[1][2]; y3.Set(16,&xyv); xyv = fXY[1][3]; y4.Set(16,&xyv); xyv = fXYU[1][2]; y3u.Set(16,&xyv); xyv = fXYD[1][2]; y3d.Set(16,&xyv); xyv = fXYU[1][3]; y4u.Set(16,&xyv); xyv = fXYD[1][3]; y4d.Set(16,&xyv); for (Int_t i=0;i<16;i++) { yY1[i] = y1[i]; yY2[i] = y2[i]; yY3[i] = y3[i]; yY4[i] = y4[i]; yY3U[i] = y3u[i]; yY3D[i] = y3d[i]; yY4U[i] = y4u[i]; yY4D[i] = y4d[i]; } TrigY(yY1, yY2, yY3, yY4, yY3U, yY3D, yY4U, yY4D, coinc44); // ASIGN fLutLpt, fLutHpt, fLutApt LocalTrigger(); fResponse = fLutApt[0] + static_cast(fLutApt[1]<<1) + static_cast(fLutLpt[0]<<2) + static_cast(fLutLpt[1]<<3) + static_cast(fLutHpt[0]<<4) + static_cast(fLutHpt[1]<<5); } ClassImp(AliMUONLocalTriggerBoard)