LEVEL2/src/crcalol2.for

*****************************************************************************
      INTEGER FUNCTION CRCALOL2()
c
      IMPLICIT NONE
C
      INCLUDE 'INTEST.TXT'
C
      integer ICONTROL5
      INTEGER  j,  m,  ii, nn
      INTEGER i
      INTEGER IPLANE, NNX, NNY, INFX, INFY, ISUPX, ISUPY
      INTEGER IBAR(2,NPLA)
      integer ifail
      INTEGER nin
      INTEGER good2
c      LOGICAL good2
c      REAL hsh
      double precision al_pp(2,5), al_p(5)
     &     , xout(npla),yout(npla),zin(npla)
      REAL PIANO(22)
C
      REAL TX, TY
      REAL timpx, timpy
      REAL TG(2)
      REAL SHIFT
      REAL BAR(2,NPLA)
      REAL DISTX, DISTY, Y(NPLA), YY(NPLA)
      REAL CX, CY
      REAL RIG, PLANEMAX, RMASS
      REAL RNSS, QTOTT, RQT
      REAL CHECK
      REAL ENER
c
      integer INDEX, NTOT(2), NPIANI,gtr,t
      integer trkchi2
c
      REAL EINF, ESUP, RPIANO(2)

      COMMON/TAGLIOEN/EINF,ESUP,ENER(2)
      SAVE /TAGLIOEN/
C
      REAL estrip(2,22,96), ispaw
c      real ab
C      parameter(AB=25.)
c      parameter(AB=260.)
      real zalig, xalig, yalig
C
      COMMON /SHIFT/ SHIFT
      SAVE / SHIFT /
C
      COMMON/ANGOLO/BAR,IBAR
      SAVE / ANGOLO /
C
      COMMON/WHERE/CX,CY,PIANO
      SAVE / WHERE /
C
      COMMON/GENERAL/RIG,RMASS
      SAVE / GENERAL /

      COMMON / CH / CHECK
      SAVE / CH /
C
      COMMON / clevel1 / al_pp,estrip, ispaw,good2,
     &     trkchi2, xalig, yalig, zalig
      SAVE / clevel1 /

      REAL VARFIT(2)
      INTEGER NPFIT(2)
      COMMON/CALOFIT/VARFIT,NPFIT
      SAVE/CALOFIT/

      REAL hmemor(9000000)
      integer Iquest(100)    
      COMMON /pawcd/hmemor
      save /pawcd/
C
      Common /QUESTd/ Iquest
      save /questd/

C
C Begin !
C
      CRCALOL2 = 0;
      RMASS = 0.938
C
C      IF (.not.GOOD2.OR..not.GCRC) goto 9696
c      print *,' good2 ',good2,' al_p(5) ',AL_P(5)
C
      PIANO(1) = 0.
      DO I = 2, 22
         IF ( MOD(I,2).EQ.0 ) THEN 
            PIANO(I) = PIANO(I-1) - 8.09
         ELSE
            PIANO(I) = PIANO(I-1) - 10.09
         ENDIF 
      ENDDO
C
      CALL VZERO(DEXY,2*LENSEV)
      CALL VZERO(BAR,2*NPLA)
      CALL VZERO(IBAR,2*NPLA)
      CALL VZERO(TBAR,2*NPLA)
      CALL VZERO(TIBAR,2*NPLA)
      CALL VZERO(CBAR,2*NPLA)
      CALL VZERO(CIBAR,2*NPLA)
      CALL VZERO(QQ,4)
      CALL VZERO(Y,NPLA)
      CALL VZERO(YY,NPLA)
      CALL VZERO(XOUT,NPLA)
      CALL VZERO(YOUT,NPLA)
      QLOW = 0.
      NLOW = 0.
      NCORE = 0.
      QCORE = 0.
      NSTRIP = 0.
      QTOT = 0.
      NX22 = 0.
      QX22 = 0.
      NINT = 0.
      QCYL = 0.
      NCYL = 0.
      QTR = 0.
      NTR = 0.
      QLAST = 0.
      QTRACK = 0.
      QMAX = 0.
      QPRESH = 0.
      NPRESH = 0.
      QMAX = 0.
      QTRACKX = 0.
      QTRACKY = 0.
      DXTRACK = 0.
      DYTRACK = 0.
      QPRE = 0.
      NPRE = 0.     
      NLAST = 0.
      GTR = 0
C
      IF (GOOD2.EQ.0.AND.TRIGTY.NE.2) goto 9696
C     
      DISTX = 0.
      DISTY = 0.
C
C      print *,'trigty = ',trigty
C
      DO I = 1,22
         DO J = 1,96
C            print *,' i ',i,' j ',j,' x ',ESTRIP(1,I,J)
C            print *,' i ',i,' j ',j,' y ',ESTRIP(2,I,J)
            IF ( MOD(I,2).NE.0 ) THEN
               IF ( ESTRIP(2,I,J).GT.EMIN ) THEN
                  DEXY(2,I,J) = ESTRIP(2,I,J)
                  NSTRIP = NSTRIP + 1.
                  QTOT = QTOT + ESTRIP(2,I,J)
                  IF (I.LT.11) QQ(1) = QQ(1) + ESTRIP(2,I,J)
               ENDIF
               IF ( ESTRIP(1,I,J).GT.EMIN ) THEN
                  DEXY(1,I,J) = ESTRIP(1,I,J)
                  NSTRIP = NSTRIP + 1.
                  QTOT = QTOT + ESTRIP(1,I,J)
                  if (i.lt.11) QQ(2) = QQ(2) + ESTRIP(1,I,J)
               ENDIF
            ENDIF
            IF ( MOD(I,2).EQ.0 ) THEN
               IF (ESTRIP(2,I,J).GT.EMIN) THEN
                  DEXY(2,I,J) = ESTRIP(2,I,J)
                  NSTRIP = NSTRIP + 1.
                  QTOT = QTOT + ESTRIP(2,I,J)
                  if (i.lt.11) QQ(3) = QQ(3) + ESTRIP(2,I,J)
               ENDIF
               IF (ESTRIP(1,I,J).GT.EMIN) THEN
                  DEXY(1,I,J) = ESTRIP(1,I,J)
                  NSTRIP = NSTRIP + 1.
                  QTOT = QTOT + ESTRIP(1,I,J)
                  IF (I.EQ.22) THEN
                     NX22 = NX22 + 1.
                     QX22 = QX22 + ESTRIP(1,I,J)
                  ENDIF
                  IF (I.LT.11) QQ(4) = QQ(4) + ESTRIP(1,I,J)
               ENDIF
            ENDIF
         ENDDO
      ENDDO
C
C     determine variables only if we have a good track
C 
      if (good2.eq.1.or.trigty.eq.2) then
         CALL CLUSTER     
         CALL DIRECTION(TG)
         THEX = TG(1)
         THEY = TG(2)
         varcfit(1) = varfit(1)
         varcfit(2) = varfit(2)
         npcfit(1) = npfit(1)
         npcfit(2) = npfit(2)
         IMPX = CX 
         IMPY = CY 
         SHIFT = -0.5
         CALL LASTRISCIA(CX,II)
         SHIFT = +0.5
         CALL LASTRISCIA(CY,II)
         TANX = TG(1)
         TANY = TG(2)
C     
         DO M = 1,2
            DO I = 1,NPLA     
               NN = 0
               IF (M.EQ.2) NN = 1
               IF (MOD(I,2).EQ.NN) THEN
                  SHIFT = +0.5
               ELSE
                  SHIFT = -0.5
               ENDIF
C     
c               IF (MOD(M,2).EQ.0) THEN
c               ELSE
c               ENDIF
C     
               IF (M.EQ.1) THEN
                  DISTX = PIANO(I) - 5.1
                  Y(I) = DISTX * TG(1) + CX
                  BAR(M,I) = Y(I)
                  CBAR(M,I) = Y(I)         
c                  print *,' cbar ',m,i,cbar(m,i)
C     
               ELSE
                  DISTY = PIANO(I)                 
                  YY(I) = DISTY * TG(2) + CY
                  BAR(M,I) = YY(I)
                  CBAR(M,I) = YY(I)
c                  print *,'cy ',cy,' disty ',disty,' tg ',
c     &                 tg(2),' cbar ',m,i,cbar(m,i)
C     
               ENDIF
               CALL LASTRISCIA(BAR(M,I),IBAR(M,I))
c               CBAR(M,I) = bar(m,i)         
               cibar(M,I) = ibar(m,i)
            ENDDO            
         ENDDO
C
         if (trigty.eq.2) goto 6996
C
         do t = 1,2
            CALL VZERO(BAR,2*NPLA)
            CALL VZERO(IBAR,2*NPLA)
            CALL VZERO(TBAR,2*NPLA)
            CALL VZERO(TIBAR,2*NPLA)
            do m = 1, 5
               al_p(m) = al_pp(t,m)
            enddo
            if (al_p(5).eq.0.) goto 9696
            DO M = 1,2
               DO I = 1,NPLA     
C     if (M.eq.1) then
C     hsh = 1.3
C     else
C     hsh = -1.3
C     endif
C     DISTX = -PIANO * (I - 1.) - AB +HSH -235. ! Z ALIGNEMENT FACTORS               
C     
                  XOUT(I) = 0.
                  YOUT(I) = 0.
                  IF (MOD(M,2).EQ.0) THEN
                     DISTX = PIANO(I) + ZALIG !  Z ALIGNEMENT FACTOR
                  ELSE
                     DISTX = PIANO(I) - 5.1 + ZALIG !  Z ALIGNEMENT FACTOR               
C     
                  ENDIF               
                  ZIN(I) = distx / 10.
c     print *,' zin ',i,' ',zin(i)
C     
                  TBAR(M,I) = 0.
                  TIBAR(M,I) = 0
C     
               enddo
               IFAIL = 0
c     print *,' al ',al_p(1),al_p(2),al_p(3),al_p(4),al_p(5)
               call TRACK(NPLA,ZIN,XOUT,YOUT,AL_P,IFAIL)
               if(IFAIL.ne.0)then
                  good2 = 0
                  good = 0
                  print *,' Tracking error (ifail not zero)!!!'
c     goto 6996
                  if (t.eq.2) goto 9696
                  goto 969
               endif
               TX = TAN(ASIN(AL_P(3))) * COS(AL_P(4))
               TY = TAN(ASIN(AL_P(3))) * SIN(AL_P(4))
               DO I = 1, NPLA
                  NN = 0
                  IF (M.EQ.2) NN = 1
                  IF (MOD(I,2).EQ.NN) THEN
                     SHIFT = +0.5
                  ELSE
                     SHIFT = -0.5
                  ENDIF
C     
C     CHECK IF XOUT OR YOUT ARE NaN
C     
                  IF (XOUT(I).NE.XOUT(I).OR.YOUT(I).NE.YOUT(I)) THEN
                     print *,' Tracking error (NaN values)!!!'                  
                     GOOD2 = 0
                     GOOD = 0
                     if (t.eq.2) goto 9696
                     goto 969
                  ENDIF
                  CX = XOUT(I)*10. + XALIG !+ 120.4 ! X ALIGNEMENT FACTOR
                  CY = -YOUT(I)*10. + YALIG ! 118.6 ! Y ALIGNEMENT FACTOR
c     
                  IF (I.EQ.1) THEN
                     TIMPX = CX
                     TIMPY = CY
                  ENDIF
                  IF (M.EQ.1) THEN
                     Y(I) = CX
                     BAR(M,I) = Y(I)     
                     TBAR(M,I) = Y(I)     
c     print *,'tbar ',m,i,' ',tbar(m,i),' cx ',cx,' xout '
c     &                 ,xout(i)
                  ELSE
                     YY(I) = CY 
                     BAR(M,I) = YY(I)                   
                     TBAR(M,I) = YY(I)                   
c     print *,'tbar ',m,i,' ',tbar(m,i),' cy ',cy,' yout '
c     &                 ,yout(i)
                  ENDIF
                  CALL LASTRISCIA(BAR(M,I),IBAR(M,I))
                  tibar(M,I) = ibar(m,i)
               ENDDO
            ENDDO 
 969        continue
            if (npfit(2).gt.15.and.varfit(2).lt.1000) then 
               if ( abs(tbar(2,1)-tbar(2,2))<40.) then
                  GTR = t
                  goto 6996
               else
                  if ( t.eq.2 ) goto 9696
               endif
            else
               if (t.eq.trkchi2) goto 6996
               if (t.eq.2) goto 9696
            endif
         enddo
      ELSE
         GOTO 9696
      endif
 6996 CONTINUE
C
C     RIG IS RIGIDITY AS DETERMINED BY THE TRACKER
C     OR by CALORIMETER IF IN SELFTRIGGER MODE
C
      if (trigty.ne.2) then
         IF ( AL_PP(GTR,5).NE.0 ) THEN
            RIG = 1./(AL_PP(GTR,5))
         ELSE
            RIG = 1000.
         ENDIF
      else
         RIG = 1000.
      endif
C     
      RNSS = 0.
      QTOTT = 0.
      PLANEMAX = 1.01*(LOG(ABS(RIG)/0.0081)-1.)
      IPLANE = INT(ANINT(PLANEMAX)) + 5
      IF (IPLANE.GT.NPLA) IPLANE=NPLA
      DO J = 1,IPLANE
         NNX = IBAR(1,J)
         NNY = IBAR(2,J)
         IF (NNX.LT.9) NNX = 9
         IF (NNY.LT.9) NNY = 9
         IF (NNX.GT.88) NNX = 88
         IF (NNY.GT.88) NNY = 88
         INFX = NNX - 8
         INFY = NNY - 8
C     
C     8 STRIPS ARE 2.88 cm , A MOLIERE RADIUS IS ABOUT 0.7 cm .
C     
         ISUPX = NNX + 8
         ISUPY = NNY + 8
         DO I = INFX,ISUPX
            IF (DEXY(1,J,I).GE.EMIN) THEN
               RNSS = RNSS + 1
               QTOTT = QTOTT + DEXY(1,J,I)
            ENDIF
         ENDDO
         DO I = INFY,ISUPY
            IF (DEXY(2,J,I).GE.EMIN) THEN
               RNSS = RNSS + 1
               QTOTT = QTOTT + DEXY(2,J,I)
            ENDIF
         ENDDO
         NCORE = RNSS * FLOAT(J) + NCORE
         QCORE = QTOTT * FLOAT(J) + QCORE
      ENDDO
C     
      QTOTT = 0.
      RNSS = 0.
      DO J = IPLANE,NPLA
         DO I = 1,NCHA
            IF (DEXY(1,J,I).GE.EMIN) THEN
               RNSS = RNSS + 1
               QTOTT = QTOTT + DEXY(1,J,I)
            ENDIF  
            IF (DEXY(2,J,I).GE.EMIN) THEN
               RNSS = RNSS + 1
               QTOTT = QTOTT + DEXY(2,J,I)
            ENDIF
         ENDDO
      ENDDO
      QLOW = QTOTT
      NLOW = RNSS
C
      CALL NOINT(NIN) ! if NINT=1 not interacting particle
      NINT = FLOAT(NIN)
C
C
C     QCYL = DETECTED ENERGY AND NCYL = NUMBER OF HIT STRIPS IN A CYLINDER oF
C     RADIUS 8.5 STRIPS WITH AXIS DEFINED BY THE DIRECTION OF THE INCOMING
C     PARTICLE .
C     
      DO J = 1,NPLA
C     
         NNX = IBAR(1,J)
         NNY = IBAR(2,J)
         IF (NNX.LT.9) NNX = 9
         IF (NNY.LT.9) NNY = 9
         IF (NNX.GT.88) NNX = 88
         IF (NNY.GT.88) NNY = 88
         INFX = NNX - 8
         INFY = NNY - 8
C     
C     8 STRIPS ARE 2.88 cm , A MOLIERE RADIUS IS ABOUT 0.7 cm .
C     
         ISUPX = NNX + 8
         ISUPY = NNY + 8
         DO I = INFX,ISUPX
            IF (DEXY(1,J,I).LT.EMIN) GO TO 710
            NCYL = NCYL + 1
            QCYL = QCYL + DEXY(1,J,I)
 710     ENDDO
         DO I=INFY,ISUPY
            IF (DEXY(2,J,I).LT.EMIN) GO TO 810
            NCYL = NCYL + 1
            QCYL = QCYL + DEXY(2,J,I)
 810     ENDDO
      ENDDO
C     
C     QTR = DETECTED ENERGY AND NTR = NUMBER OF HIT STRIPS IN A CYLINDER oF
C     RADIUS 4.5 STRIPS WITH AXIS DEFINED BY THE DIRECTION OF THE INCOMING
C     PARTICLE .
C     
      DO I = 1,NPLA
C     
         NNX = IBAR(1,I)
         NNY = IBAR(2,I)
         IF (NNX.LT.5) NNX = 5
         IF (NNY.LT.5) NNY = 5
         IF (NNX.GT.92) NNX = 92
         IF (NNY.GT.92) NNY = 92
         INFX = NNX - 4
         INFY = NNY - 4
C     
C     8 STRIPS ARE 2.88 cm , A MOLIERE RADIUS IS ABOUT 0.7 cm .
C     
         ISUPX = NNX + 4
         ISUPY = NNY + 4
         DO J = INFX,ISUPX
            IF (DEXY(1,I,J).GT.EMIN) THEN
               NTR = NTR + 1
               QTR = QTR + DEXY(1,I,J)
            ENDIF
         ENDDO
         DO J = INFY,ISUPY
            IF (DEXY(2,I,J).GT.EMIN) THEN
               NTR = NTR + 1
               QTR = QTR + DEXY(2,I,J)
            ENDIF
         ENDDO
      ENDDO
C
      CALL LATERALE(QTRACK,RQT)
C     
      DO M = 1,2
         DO I = 1,NPLA
            DO J = 1,NCHA
               IF (DEXY(M,I,J).GT.QMAX) QMAX = DEXY(M,I,J)
            ENDDO
         ENDDO
      ENDDO
C     
      
      DO I = 1,4
C     
         NNX = IBAR(1,I)
         NNY = IBAR(2,I)
         IF (NNX.LT.3) NNX = 3
         IF (NNY.LT.3) NNY = 3
         IF (NNX.GT.94) NNX = 94
         IF (NNY.GT.94) NNY = 94
         INFX = NNX - 2
         INFY = NNY - 2
C     
C     8 STRIPS ARE 2.88 cm , A MOLIERE RADIUS IS ABOUT 0.7 cm .
C     
         ISUPX = NNX + 2
         ISUPY = NNY + 2
         DO J = INFX,ISUPX
            IF (DEXY(1,I,J).GE.EMIN) THEN
               NPRESH = NPRESH + 1
               QPRESH = QPRESH + DEXY(1,I,J)
            ENDIF
         ENDDO
         DO J = INFY,ISUPY
            IF (DEXY(2,I,J).GE.EMIN) THEN
               NPRESH = NPRESH + 1
               QPRESH = QPRESH + DEXY(2,I,J)
            ENDIF
         ENDDO
      ENDDO
C     
      DO M = 1,2
         DO I = 1,NPLA
            DO J = 1,NCHA
               IF (DEXY(M,I,J).GT.QMAX) QMAX = DEXY(M,I,J)
            ENDDO
         ENDDO
      ENDDO
C      
      ICONTROL5 = 0
      CALL NSHOWER(ICONTROL5,DXTRACK,DYTRACK,QTRACKX,QTRACKY)
C
      DO J = 1,3
C     
         NNX = IBAR(1,J)
         NNY = IBAR(2,J)
         IF (NNX.LT.9) NNX = 9
         IF (NNY.LT.9) NNY = 9
         IF (NNX.GT.88) NNX = 88
         IF (NNY.GT.88) NNY = 88
         INFX = NNX - 8
         INFY = NNY - 8
         ISUPX = NNX + 8
         ISUPY = NNY + 8
         DO I = INFX,ISUPX
            IF (DEXY(1,J,I).GE.EMIN) THEN
               NPRE = NPRE + 1
               QPRE = QPRE + DEXY(1,J,I)
            ENDIF
         ENDDO
         DO I=INFY,ISUPY
            IF (DEXY(2,J,I).GE.EMIN) THEN
               NPRE = NPRE + 1
               QPRE = QPRE + DEXY(2,J,I)
            ENDIF
         ENDDO
      ENDDO
C     
      DO J = NPLA-4,NPLA
C
         NNX = IBAR(1,J)
         NNY = IBAR(2,J)
         IF (NNX.LT.9) NNX = 9
         IF (NNY.LT.9) NNY = 9
         IF (NNX.GT.88) NNX = 88
         IF (NNY.GT.88) NNY = 88
         INFX = NNX - 8
         INFY = NNY - 8
         ISUPX = NNX + 8
         ISUPY = NNY + 8
         DO I = INFX,ISUPX
            IF (DEXY(1,J,I).GE.EMIN) THEN
               NLAST = NLAST + 1
               QLAST = QLAST + DEXY(1,J,I)
            ENDIF
         ENDDO
         DO I=INFY,ISUPY
            IF (DEXY(2,J,I).GE.EMIN) THEN
               NLAST = NLAST + 1
               QLAST = QLAST + DEXY(2,J,I)
            ENDIF
         ENDDO
      ENDDO
C
      EINF = EMIN
      ESUP = 50.
C
      DO M = 1,2
        RPIANO(M) = 0.
        NTOT(M) = 0
      ENDDO
      NPIANI = 5
      QMEAN = 0.
      INDEX = 0
      CALL ELIO(RPIANO,NPIANI,QMEAN,NTOT,INDEX)
      PLANETOT = RPIANO(1) + RPIANO(2)  
C
C
C
c      print *,'prima hfnt '
c      print *,' trigty ',trigty
c      print *,' qtot ',qtot
c      print *,' nstrip ',nstrip
c      print *,' ncore ',ncore
c      print *,' qcore ',qcore
c      print *,' impx ',impx
c      print *,' impy ',impy
c      print *,' tany ',tany
c      print *,' tanx ',tanx
c      print *,' nint ',nint
c      print *,' ncyl ',ncyl
c      print *,' qcyl ',qcyl
c      print *,' qtrack ',qtrack
c      print *,' qmax ',qmax
c      print *,' qx22 ',qx22
c      print *,' nx22 ',nx22
c      print *,' qq(1) ',qq(1)
c      print *,' qq(1) ',qq(2)
c      print *,' qq(1) ',qq(3)
c      print *,' qq(1) ',qq(4)
c      print *,' qtrackx ',qtrackx
c      print *,' qtrackx ',qtracky
c      print *,' dxtrack ',dxtrack
c      print *,' dxtrack ',dytrack
c      print *,' qlast ',qlast
c      print *,' nlast ',nlast
c      print *,' qpre ',qpre
c      print *,' npre ',npre
c      print *,' qpresh ',qpresh
c      print *,' npresh ',npresh
c      print *,' qlow ',qlow
c      print *,' nlow ',nlow
c      print *,' qtr ',qtr
c      print *,' ntr ',ntr
c      print *,' planetot ',planetot
c      print *,' qmean ',qmean
c      do i = 1, 2
c         do j = 1, 22
c            print *,' cibar ',i,j,cibar(i,j)
c            print *,' tibar ',i,j,tibar(i,j)
c            print *,' cbar ',i,j,cbar(i,j)
c            print *,' tbar ',i,j,tbar(i,j)
c         enddo
c      enddo

 9696 CONTINUE
C
      IF (ispaw.eq.1.) call hfnt(1)
c      print *,'dopo hfnt '
C

 45   continue

 50   continue

      return
      END

      
C
C---------------------------------------------------------------------
      SUBROUTINE LATERALE(RQT1,RQT2)
C---------------------------------------------------------------------
C RQT1 (IT WILL BE CALLED QTRACK IN THE N-TUPLE) IS THE SUM OF THE DETECTED
C ENERGY IN THE STRIP ALONG THE TRACK AND THE TWO CLOSEST STRIPS . FOR ALL THE
C LAYERS . RQT2 (IS NOT USED IN THE N-TUPLA) IS THE TOTAL ENERGY MINUS RQT1 .
C
      INCLUDE 'INTEST.TXT'
      REAL RQT1
      INTEGER A,B
      REAL BAR(2,NPLA)
      REAL Q(0:NPLA)
      INTEGER IBAR(2,NPLA)
      COMMON/ANGOLO/BAR,IBAR

      RQT2=0.

      INPIA = 1
C
      QQQ=0
      MAX=0
      Q(MAX)=0
C
      DO I = INPIA,NPLA
        A = IBAR(1,I)
        B = IBAR(2,I)
        IF (A.LE.2) A = 3
        IF (B.LE.2) B = 3
        IF (A.GE.(NCHA-1)) A = NCHA - 2
        IF (B.GE.(NCHA-1)) B = NCHA - 2

        DO J = A-1,A+1
          IF (DEXY(1,I,J).GE.EMIN) RQT1 = RQT1 + DEXY(1,I,J)
  600   ENDDO
C
        DO J = B-1,B+1
          IF (DEXY(2,I,J).GE.EMIN) RQT1 = RQT1 + DEXY(2,I,J)
        ENDDO
C
        DO J=1,A-2
          PXY = DEXY(1,I,J)
          IF (PXY.GE.EMIN) RQT2 = RQT2 + PXY
  650   ENDDO
C
        DO J=A+2,NCHA
          PXY = DEXY(1,I,J)
          IF (PXY.GE.EMIN) RQT2 = RQT2 + PXY
  700   ENDDO
C
        DO J=1,B-2
          PXY = DEXY(2,I,J)
          IF (PXY.GE.EMIN) RQT2 = RQT2 + PXY
  750   ENDDO
C
        DO J=B+2,NCHA
          PXY = DEXY(2,I,J)
          IF (PXY.GE.EMIN) RQT2 = RQT2 + PXY
  800   ENDDO
C
      ENDDO
C
C
  400 RETURN
      END


1	*****************************************************************************
2	INTEGER FUNCTION CRCALOL2()
3	c
4	IMPLICIT NONE
5	C
6	INCLUDE 'INTEST.TXT'
7	C
8	integer ICONTROL5
9	INTEGER j, m, ii, nn
10	INTEGER i
11	INTEGER IPLANE, NNX, NNY, INFX, INFY, ISUPX, ISUPY
12	INTEGER IBAR(2,NPLA)
13	integer ifail
14	INTEGER nin
15	INTEGER good2
16	c LOGICAL good2
17	c REAL hsh
18	double precision al_pp(2,5), al_p(5)
19	& , xout(npla),yout(npla),zin(npla)
20	REAL PIANO(22)
21	C
22	REAL TX, TY
23	REAL timpx, timpy
24	REAL TG(2)
25	REAL SHIFT
26	REAL BAR(2,NPLA)
27	REAL DISTX, DISTY, Y(NPLA), YY(NPLA)
28	REAL CX, CY
29	REAL RIG, PLANEMAX, RMASS
30	REAL RNSS, QTOTT, RQT
31	REAL CHECK
32	REAL ENER
33	c
34	integer INDEX, NTOT(2), NPIANI,gtr,t
35	integer trkchi2
36	c
37	REAL EINF, ESUP, RPIANO(2)
38
39	COMMON/TAGLIOEN/EINF,ESUP,ENER(2)
40	SAVE /TAGLIOEN/
41	C
42	REAL estrip(2,22,96), ispaw
43	c real ab
44	C parameter(AB=25.)
45	c parameter(AB=260.)
46	real zalig, xalig, yalig
47	C
48	COMMON /SHIFT/ SHIFT
49	SAVE / SHIFT /
50	C
51	COMMON/ANGOLO/BAR,IBAR
52	SAVE / ANGOLO /
53	C
54	COMMON/WHERE/CX,CY,PIANO
55	SAVE / WHERE /
56	C
57	COMMON/GENERAL/RIG,RMASS
58	SAVE / GENERAL /
59
60	COMMON / CH / CHECK
61	SAVE / CH /
62	C
63	COMMON / clevel1 / al_pp,estrip, ispaw,good2,
64	& trkchi2, xalig, yalig, zalig
65	SAVE / clevel1 /
66
67	REAL VARFIT(2)
68	INTEGER NPFIT(2)
69	COMMON/CALOFIT/VARFIT,NPFIT
70	SAVE/CALOFIT/
71
72	REAL hmemor(9000000)
73	integer Iquest(100)
74	COMMON /pawcd/hmemor
75	save /pawcd/
76	C
77	Common /QUESTd/ Iquest
78	save /questd/
79
80	C
81	C Begin !
82	C
83	CRCALOL2 = 0;
84	RMASS = 0.938
85	C
86	C IF (.not.GOOD2.OR..not.GCRC) goto 9696
87	c print *,' good2 ',good2,' al_p(5) ',AL_P(5)
88	C
89	PIANO(1) = 0.
90	DO I = 2, 22
91	IF ( MOD(I,2).EQ.0 ) THEN
92	PIANO(I) = PIANO(I-1) - 8.09
93	ELSE
94	PIANO(I) = PIANO(I-1) - 10.09
95	ENDIF
96	ENDDO
97	C
98	CALL VZERO(DEXY,2*LENSEV)
99	CALL VZERO(BAR,2*NPLA)
100	CALL VZERO(IBAR,2*NPLA)
101	CALL VZERO(TBAR,2*NPLA)
102	CALL VZERO(TIBAR,2*NPLA)
103	CALL VZERO(CBAR,2*NPLA)
104	CALL VZERO(CIBAR,2*NPLA)
105	CALL VZERO(QQ,4)
106	CALL VZERO(Y,NPLA)
107	CALL VZERO(YY,NPLA)
108	CALL VZERO(XOUT,NPLA)
109	CALL VZERO(YOUT,NPLA)
110	QLOW = 0.
111	NLOW = 0.
112	NCORE = 0.
113	QCORE = 0.
114	NSTRIP = 0.
115	QTOT = 0.
116	NX22 = 0.
117	QX22 = 0.
118	NINT = 0.
119	QCYL = 0.
120	NCYL = 0.
121	QTR = 0.
122	NTR = 0.
123	QLAST = 0.
124	QTRACK = 0.
125	QMAX = 0.
126	QPRESH = 0.
127	NPRESH = 0.
128	QMAX = 0.
129	QTRACKX = 0.
130	QTRACKY = 0.
131	DXTRACK = 0.
132	DYTRACK = 0.
133	QPRE = 0.
134	NPRE = 0.
135	NLAST = 0.
136	GTR = 0
137	C
138	IF (GOOD2.EQ.0.AND.TRIGTY.NE.2) goto 9696
139	C
140	DISTX = 0.
141	DISTY = 0.
142	C
143	C print *,'trigty = ',trigty
144	C
145	DO I = 1,22
146	DO J = 1,96
147	C print *,' i ',i,' j ',j,' x ',ESTRIP(1,I,J)
148	C print *,' i ',i,' j ',j,' y ',ESTRIP(2,I,J)
149	IF ( MOD(I,2).NE.0 ) THEN
150	IF ( ESTRIP(2,I,J).GT.EMIN ) THEN
151	DEXY(2,I,J) = ESTRIP(2,I,J)
152	NSTRIP = NSTRIP + 1.
153	QTOT = QTOT + ESTRIP(2,I,J)
154	IF (I.LT.11) QQ(1) = QQ(1) + ESTRIP(2,I,J)
155	ENDIF
156	IF ( ESTRIP(1,I,J).GT.EMIN ) THEN
157	DEXY(1,I,J) = ESTRIP(1,I,J)
158	NSTRIP = NSTRIP + 1.
159	QTOT = QTOT + ESTRIP(1,I,J)
160	if (i.lt.11) QQ(2) = QQ(2) + ESTRIP(1,I,J)
161	ENDIF
162	ENDIF
163	IF ( MOD(I,2).EQ.0 ) THEN
164	IF (ESTRIP(2,I,J).GT.EMIN) THEN
165	DEXY(2,I,J) = ESTRIP(2,I,J)
166	NSTRIP = NSTRIP + 1.
167	QTOT = QTOT + ESTRIP(2,I,J)
168	if (i.lt.11) QQ(3) = QQ(3) + ESTRIP(2,I,J)
169	ENDIF
170	IF (ESTRIP(1,I,J).GT.EMIN) THEN
171	DEXY(1,I,J) = ESTRIP(1,I,J)
172	NSTRIP = NSTRIP + 1.
173	QTOT = QTOT + ESTRIP(1,I,J)
174	IF (I.EQ.22) THEN
175	NX22 = NX22 + 1.
176	QX22 = QX22 + ESTRIP(1,I,J)
177	ENDIF
178	IF (I.LT.11) QQ(4) = QQ(4) + ESTRIP(1,I,J)
179	ENDIF
180	ENDIF
181	ENDDO
182	ENDDO
183	C
184	C determine variables only if we have a good track
185	C
186	if (good2.eq.1.or.trigty.eq.2) then
187	CALL CLUSTER
188	CALL DIRECTION(TG)
189	THEX = TG(1)
190	THEY = TG(2)
191	varcfit(1) = varfit(1)
192	varcfit(2) = varfit(2)
193	npcfit(1) = npfit(1)
194	npcfit(2) = npfit(2)
195	IMPX = CX
196	IMPY = CY
197	SHIFT = -0.5
198	CALL LASTRISCIA(CX,II)
199	SHIFT = +0.5
200	CALL LASTRISCIA(CY,II)
201	TANX = TG(1)
202	TANY = TG(2)
203	C
204	DO M = 1,2
205	DO I = 1,NPLA
206	NN = 0
207	IF (M.EQ.2) NN = 1
208	IF (MOD(I,2).EQ.NN) THEN
209	SHIFT = +0.5
210	ELSE
211	SHIFT = -0.5
212	ENDIF
213	C
214	c IF (MOD(M,2).EQ.0) THEN
215	c ELSE
216	c ENDIF
217	C
218	IF (M.EQ.1) THEN
219	DISTX = PIANO(I) - 5.1
220	Y(I) = DISTX * TG(1) + CX
221	BAR(M,I) = Y(I)
222	CBAR(M,I) = Y(I)
223	c print *,' cbar ',m,i,cbar(m,i)
224	C
225	ELSE
226	DISTY = PIANO(I)
227	YY(I) = DISTY * TG(2) + CY
228	BAR(M,I) = YY(I)
229	CBAR(M,I) = YY(I)
230	c print *,'cy ',cy,' disty ',disty,' tg ',
231	c & tg(2),' cbar ',m,i,cbar(m,i)
232	C
233	ENDIF
234	CALL LASTRISCIA(BAR(M,I),IBAR(M,I))
235	c CBAR(M,I) = bar(m,i)
236	cibar(M,I) = ibar(m,i)
237	ENDDO
238	ENDDO
239	C
240	if (trigty.eq.2) goto 6996
241	C
242	do t = 1,2
243	CALL VZERO(BAR,2*NPLA)
244	CALL VZERO(IBAR,2*NPLA)
245	CALL VZERO(TBAR,2*NPLA)
246	CALL VZERO(TIBAR,2*NPLA)
247	do m = 1, 5
248	al_p(m) = al_pp(t,m)
249	enddo
250	if (al_p(5).eq.0.) goto 9696
251	DO M = 1,2
252	DO I = 1,NPLA
253	C if (M.eq.1) then
254	C hsh = 1.3
255	C else
256	C hsh = -1.3
257	C endif
258	C DISTX = -PIANO * (I - 1.) - AB +HSH -235. ! Z ALIGNEMENT FACTORS
259	C
260	XOUT(I) = 0.
261	YOUT(I) = 0.
262	IF (MOD(M,2).EQ.0) THEN
263	DISTX = PIANO(I) + ZALIG ! Z ALIGNEMENT FACTOR
264	ELSE
265	DISTX = PIANO(I) - 5.1 + ZALIG ! Z ALIGNEMENT FACTOR
266	C
267	ENDIF
268	ZIN(I) = distx / 10.
269	c print *,' zin ',i,' ',zin(i)
270	C
271	TBAR(M,I) = 0.
272	TIBAR(M,I) = 0
273	C
274	enddo
275	IFAIL = 0
276	c print *,' al ',al_p(1),al_p(2),al_p(3),al_p(4),al_p(5)
277	call TRACK(NPLA,ZIN,XOUT,YOUT,AL_P,IFAIL)
278	if(IFAIL.ne.0)then
279	good2 = 0
280	good = 0
281	print *,' Tracking error (ifail not zero)!!!'
282	c goto 6996
283	if (t.eq.2) goto 9696
284	goto 969
285	endif
286	TX = TAN(ASIN(AL_P(3))) * COS(AL_P(4))
287	TY = TAN(ASIN(AL_P(3))) * SIN(AL_P(4))
288	DO I = 1, NPLA
289	NN = 0
290	IF (M.EQ.2) NN = 1
291	IF (MOD(I,2).EQ.NN) THEN
292	SHIFT = +0.5
293	ELSE
294	SHIFT = -0.5
295	ENDIF
296	C
297	C CHECK IF XOUT OR YOUT ARE NaN
298	C
299	IF (XOUT(I).NE.XOUT(I).OR.YOUT(I).NE.YOUT(I)) THEN
300	print *,' Tracking error (NaN values)!!!'
301	GOOD2 = 0
302	GOOD = 0
303	if (t.eq.2) goto 9696
304	goto 969
305	ENDIF
306	CX = XOUT(I)*10. + XALIG !+ 120.4 ! X ALIGNEMENT FACTOR
307	CY = -YOUT(I)*10. + YALIG ! 118.6 ! Y ALIGNEMENT FACTOR
308	c
309	IF (I.EQ.1) THEN
310	TIMPX = CX
311	TIMPY = CY
312	ENDIF
313	IF (M.EQ.1) THEN
314	Y(I) = CX
315	BAR(M,I) = Y(I)
316	TBAR(M,I) = Y(I)
317	c print *,'tbar ',m,i,' ',tbar(m,i),' cx ',cx,' xout '
318	c & ,xout(i)
319	ELSE
320	YY(I) = CY
321	BAR(M,I) = YY(I)
322	TBAR(M,I) = YY(I)
323	c print *,'tbar ',m,i,' ',tbar(m,i),' cy ',cy,' yout '
324	c & ,yout(i)
325	ENDIF
326	CALL LASTRISCIA(BAR(M,I),IBAR(M,I))
327	tibar(M,I) = ibar(m,i)
328	ENDDO
329	ENDDO
330	969 continue
331	if (npfit(2).gt.15.and.varfit(2).lt.1000) then
332	if ( abs(tbar(2,1)-tbar(2,2))<40.) then
333	GTR = t
334	goto 6996
335	else
336	if ( t.eq.2 ) goto 9696
337	endif
338	else
339	if (t.eq.trkchi2) goto 6996
340	if (t.eq.2) goto 9696
341	endif
342	enddo
343	ELSE
344	GOTO 9696
345	endif
346	6996 CONTINUE
347	C
348	C RIG IS RIGIDITY AS DETERMINED BY THE TRACKER
349	C OR by CALORIMETER IF IN SELFTRIGGER MODE
350	C
351	if (trigty.ne.2) then
352	IF ( AL_PP(GTR,5).NE.0 ) THEN
353	RIG = 1./(AL_PP(GTR,5))
354	ELSE
355	RIG = 1000.
356	ENDIF
357	else
358	RIG = 1000.
359	endif
360	C
361	RNSS = 0.
362	QTOTT = 0.
363	PLANEMAX = 1.01*(LOG(ABS(RIG)/0.0081)-1.)
364	IPLANE = INT(ANINT(PLANEMAX)) + 5
365	IF (IPLANE.GT.NPLA) IPLANE=NPLA
366	DO J = 1,IPLANE
367	NNX = IBAR(1,J)
368	NNY = IBAR(2,J)
369	IF (NNX.LT.9) NNX = 9
370	IF (NNY.LT.9) NNY = 9
371	IF (NNX.GT.88) NNX = 88
372	IF (NNY.GT.88) NNY = 88
373	INFX = NNX - 8
374	INFY = NNY - 8
375	C
376	C 8 STRIPS ARE 2.88 cm , A MOLIERE RADIUS IS ABOUT 0.7 cm .
377	C
378	ISUPX = NNX + 8
379	ISUPY = NNY + 8
380	DO I = INFX,ISUPX
381	IF (DEXY(1,J,I).GE.EMIN) THEN
382	RNSS = RNSS + 1
383	QTOTT = QTOTT + DEXY(1,J,I)
384	ENDIF
385	ENDDO
386	DO I = INFY,ISUPY
387	IF (DEXY(2,J,I).GE.EMIN) THEN
388	RNSS = RNSS + 1
389	QTOTT = QTOTT + DEXY(2,J,I)
390	ENDIF
391	ENDDO
392	NCORE = RNSS * FLOAT(J) + NCORE
393	QCORE = QTOTT * FLOAT(J) + QCORE
394	ENDDO
395	C
396	QTOTT = 0.
397	RNSS = 0.
398	DO J = IPLANE,NPLA
399	DO I = 1,NCHA
400	IF (DEXY(1,J,I).GE.EMIN) THEN
401	RNSS = RNSS + 1
402	QTOTT = QTOTT + DEXY(1,J,I)
403	ENDIF
404	IF (DEXY(2,J,I).GE.EMIN) THEN
405	RNSS = RNSS + 1
406	QTOTT = QTOTT + DEXY(2,J,I)
407	ENDIF
408	ENDDO
409	ENDDO
410	QLOW = QTOTT
411	NLOW = RNSS
412	C
413	CALL NOINT(NIN) ! if NINT=1 not interacting particle
414	NINT = FLOAT(NIN)
415	C
416	C
417	C QCYL = DETECTED ENERGY AND NCYL = NUMBER OF HIT STRIPS IN A CYLINDER oF
418	C RADIUS 8.5 STRIPS WITH AXIS DEFINED BY THE DIRECTION OF THE INCOMING
419	C PARTICLE .
420	C
421	DO J = 1,NPLA
422	C
423	NNX = IBAR(1,J)
424	NNY = IBAR(2,J)
425	IF (NNX.LT.9) NNX = 9
426	IF (NNY.LT.9) NNY = 9
427	IF (NNX.GT.88) NNX = 88
428	IF (NNY.GT.88) NNY = 88
429	INFX = NNX - 8
430	INFY = NNY - 8
431	C
432	C 8 STRIPS ARE 2.88 cm , A MOLIERE RADIUS IS ABOUT 0.7 cm .
433	C
434	ISUPX = NNX + 8
435	ISUPY = NNY + 8
436	DO I = INFX,ISUPX
437	IF (DEXY(1,J,I).LT.EMIN) GO TO 710
438	NCYL = NCYL + 1
439	QCYL = QCYL + DEXY(1,J,I)
440	710 ENDDO
441	DO I=INFY,ISUPY
442	IF (DEXY(2,J,I).LT.EMIN) GO TO 810
443	NCYL = NCYL + 1
444	QCYL = QCYL + DEXY(2,J,I)
445	810 ENDDO
446	ENDDO
447	C
448	C QTR = DETECTED ENERGY AND NTR = NUMBER OF HIT STRIPS IN A CYLINDER oF
449	C RADIUS 4.5 STRIPS WITH AXIS DEFINED BY THE DIRECTION OF THE INCOMING
450	C PARTICLE .
451	C
452	DO I = 1,NPLA
453	C
454	NNX = IBAR(1,I)
455	NNY = IBAR(2,I)
456	IF (NNX.LT.5) NNX = 5
457	IF (NNY.LT.5) NNY = 5
458	IF (NNX.GT.92) NNX = 92
459	IF (NNY.GT.92) NNY = 92
460	INFX = NNX - 4
461	INFY = NNY - 4
462	C
463	C 8 STRIPS ARE 2.88 cm , A MOLIERE RADIUS IS ABOUT 0.7 cm .
464	C
465	ISUPX = NNX + 4
466	ISUPY = NNY + 4
467	DO J = INFX,ISUPX
468	IF (DEXY(1,I,J).GT.EMIN) THEN
469	NTR = NTR + 1
470	QTR = QTR + DEXY(1,I,J)
471	ENDIF
472	ENDDO
473	DO J = INFY,ISUPY
474	IF (DEXY(2,I,J).GT.EMIN) THEN
475	NTR = NTR + 1
476	QTR = QTR + DEXY(2,I,J)
477	ENDIF
478	ENDDO
479	ENDDO
480	C
481	CALL LATERALE(QTRACK,RQT)
482	C
483	DO M = 1,2
484	DO I = 1,NPLA
485	DO J = 1,NCHA
486	IF (DEXY(M,I,J).GT.QMAX) QMAX = DEXY(M,I,J)
487	ENDDO
488	ENDDO
489	ENDDO
490	C
491
492	DO I = 1,4
493	C
494	NNX = IBAR(1,I)
495	NNY = IBAR(2,I)
496	IF (NNX.LT.3) NNX = 3
497	IF (NNY.LT.3) NNY = 3
498	IF (NNX.GT.94) NNX = 94
499	IF (NNY.GT.94) NNY = 94
500	INFX = NNX - 2
501	INFY = NNY - 2
502	C
503	C 8 STRIPS ARE 2.88 cm , A MOLIERE RADIUS IS ABOUT 0.7 cm .
504	C
505	ISUPX = NNX + 2
506	ISUPY = NNY + 2
507	DO J = INFX,ISUPX
508	IF (DEXY(1,I,J).GE.EMIN) THEN
509	NPRESH = NPRESH + 1
510	QPRESH = QPRESH + DEXY(1,I,J)
511	ENDIF
512	ENDDO
513	DO J = INFY,ISUPY
514	IF (DEXY(2,I,J).GE.EMIN) THEN
515	NPRESH = NPRESH + 1
516	QPRESH = QPRESH + DEXY(2,I,J)
517	ENDIF
518	ENDDO
519	ENDDO
520	C
521	DO M = 1,2
522	DO I = 1,NPLA
523	DO J = 1,NCHA
524	IF (DEXY(M,I,J).GT.QMAX) QMAX = DEXY(M,I,J)
525	ENDDO
526	ENDDO
527	ENDDO
528	C
529	ICONTROL5 = 0
530	CALL NSHOWER(ICONTROL5,DXTRACK,DYTRACK,QTRACKX,QTRACKY)
531	C
532	DO J = 1,3
533	C
534	NNX = IBAR(1,J)
535	NNY = IBAR(2,J)
536	IF (NNX.LT.9) NNX = 9
537	IF (NNY.LT.9) NNY = 9
538	IF (NNX.GT.88) NNX = 88
539	IF (NNY.GT.88) NNY = 88
540	INFX = NNX - 8
541	INFY = NNY - 8
542	ISUPX = NNX + 8
543	ISUPY = NNY + 8
544	DO I = INFX,ISUPX
545	IF (DEXY(1,J,I).GE.EMIN) THEN
546	NPRE = NPRE + 1
547	QPRE = QPRE + DEXY(1,J,I)
548	ENDIF
549	ENDDO
550	DO I=INFY,ISUPY
551	IF (DEXY(2,J,I).GE.EMIN) THEN
552	NPRE = NPRE + 1
553	QPRE = QPRE + DEXY(2,J,I)
554	ENDIF
555	ENDDO
556	ENDDO
557	C
558	DO J = NPLA-4,NPLA
559	C
560	NNX = IBAR(1,J)
561	NNY = IBAR(2,J)
562	IF (NNX.LT.9) NNX = 9
563	IF (NNY.LT.9) NNY = 9
564	IF (NNX.GT.88) NNX = 88
565	IF (NNY.GT.88) NNY = 88
566	INFX = NNX - 8
567	INFY = NNY - 8
568	ISUPX = NNX + 8
569	ISUPY = NNY + 8
570	DO I = INFX,ISUPX
571	IF (DEXY(1,J,I).GE.EMIN) THEN
572	NLAST = NLAST + 1
573	QLAST = QLAST + DEXY(1,J,I)
574	ENDIF
575	ENDDO
576	DO I=INFY,ISUPY
577	IF (DEXY(2,J,I).GE.EMIN) THEN
578	NLAST = NLAST + 1
579	QLAST = QLAST + DEXY(2,J,I)
580	ENDIF
581	ENDDO
582	ENDDO
583	C
584	EINF = EMIN
585	ESUP = 50.
586	C
587	DO M = 1,2
588	RPIANO(M) = 0.
589	NTOT(M) = 0
590	ENDDO
591	NPIANI = 5
592	QMEAN = 0.
593	INDEX = 0
594	CALL ELIO(RPIANO,NPIANI,QMEAN,NTOT,INDEX)
595	PLANETOT = RPIANO(1) + RPIANO(2)
596	C
597	C
598	C
599	c print *,'prima hfnt '
600	c print *,' trigty ',trigty
601	c print *,' qtot ',qtot
602	c print *,' nstrip ',nstrip
603	c print *,' ncore ',ncore
604	c print *,' qcore ',qcore
605	c print *,' impx ',impx
606	c print *,' impy ',impy
607	c print *,' tany ',tany
608	c print *,' tanx ',tanx
609	c print *,' nint ',nint
610	c print *,' ncyl ',ncyl
611	c print *,' qcyl ',qcyl
612	c print *,' qtrack ',qtrack
613	c print *,' qmax ',qmax
614	c print *,' qx22 ',qx22
615	c print *,' nx22 ',nx22
616	c print *,' qq(1) ',qq(1)
617	c print *,' qq(1) ',qq(2)
618	c print *,' qq(1) ',qq(3)
619	c print *,' qq(1) ',qq(4)
620	c print *,' qtrackx ',qtrackx
621	c print *,' qtrackx ',qtracky
622	c print *,' dxtrack ',dxtrack
623	c print *,' dxtrack ',dytrack
624	c print *,' qlast ',qlast
625	c print *,' nlast ',nlast
626	c print *,' qpre ',qpre
627	c print *,' npre ',npre
628	c print *,' qpresh ',qpresh
629	c print *,' npresh ',npresh
630	c print *,' qlow ',qlow
631	c print *,' nlow ',nlow
632	c print *,' qtr ',qtr
633	c print *,' ntr ',ntr
634	c print *,' planetot ',planetot
635	c print *,' qmean ',qmean
636	c do i = 1, 2
637	c do j = 1, 22
638	c print *,' cibar ',i,j,cibar(i,j)
639	c print *,' tibar ',i,j,tibar(i,j)
640	c print *,' cbar ',i,j,cbar(i,j)
641	c print *,' tbar ',i,j,tbar(i,j)
642	c enddo
643	c enddo
644
645	9696 CONTINUE
646	C
647	IF (ispaw.eq.1.) call hfnt(1)
648	c print *,'dopo hfnt '
649	C
650
651	45 continue
652
653	50 continue
654
655	return
656	END
657
658
659	C
660	C---------------------------------------------------------------------
661	SUBROUTINE LATERALE(RQT1,RQT2)
662	C---------------------------------------------------------------------
663	C RQT1 (IT WILL BE CALLED QTRACK IN THE N-TUPLE) IS THE SUM OF THE DETECTED
664	C ENERGY IN THE STRIP ALONG THE TRACK AND THE TWO CLOSEST STRIPS . FOR ALL THE
665	C LAYERS . RQT2 (IS NOT USED IN THE N-TUPLA) IS THE TOTAL ENERGY MINUS RQT1 .
666	C
667	INCLUDE 'INTEST.TXT'
668	REAL RQT1
669	INTEGER A,B
670	REAL BAR(2,NPLA)
671	REAL Q(0:NPLA)
672	INTEGER IBAR(2,NPLA)
673	COMMON/ANGOLO/BAR,IBAR
674
675	RQT2=0.
676
677	INPIA = 1
678	C
679	QQQ=0
680	MAX=0
681	Q(MAX)=0
682	C
683	DO I = INPIA,NPLA
684	A = IBAR(1,I)
685	B = IBAR(2,I)
686	IF (A.LE.2) A = 3
687	IF (B.LE.2) B = 3
688	IF (A.GE.(NCHA-1)) A = NCHA - 2
689	IF (B.GE.(NCHA-1)) B = NCHA - 2
690
691	DO J = A-1,A+1
692	IF (DEXY(1,I,J).GE.EMIN) RQT1 = RQT1 + DEXY(1,I,J)
693	600 ENDDO
694	C
695	DO J = B-1,B+1
696	IF (DEXY(2,I,J).GE.EMIN) RQT1 = RQT1 + DEXY(2,I,J)
697	ENDDO
698	C
699	DO J=1,A-2
700	PXY = DEXY(1,I,J)
701	IF (PXY.GE.EMIN) RQT2 = RQT2 + PXY
702	650 ENDDO
703	C
704	DO J=A+2,NCHA
705	PXY = DEXY(1,I,J)
706	IF (PXY.GE.EMIN) RQT2 = RQT2 + PXY
707	700 ENDDO
708	C
709	DO J=1,B-2
710	PXY = DEXY(2,I,J)
711	IF (PXY.GE.EMIN) RQT2 = RQT2 + PXY
712	750 ENDDO
713	C
714	DO J=B+2,NCHA
715	PXY = DEXY(2,I,J)
716	IF (PXY.GE.EMIN) RQT2 = RQT2 + PXY
717	800 ENDDO
718	C
719	ENDDO
720	C
721	C
722	400 RETURN
723	END
724
725