forroutines/tof/tofunpack.for

C--------------------------------------------------------------------
      SUBROUTINE TOFUNPACK(vecta,lung,me)
C                                            D.Campana,  Dec. 04
C---------------------------------------------------------------------

      IMPLICIT NONE

C
C Normal variables definition
C
      integer lung
      integer*1 vecta(lung)
      integer me
      integer check, crctof 
      integer ic0,sup,inf 
      integer i, ic, bit, bi,j 
      integer start,ntdc
      integer tdcid(12),evcount(12)
      integer tdcmask(12),adc(4,12),tdc(4,12)
      integer rawadc(4,12),rawtdc(4,12),grayadc(4,12),graytdc(4,12)
      integer temp1(12),temp2(12)
C 
c      data start,ntdc /150,12/ ! to read data before Christmas 2004
       data start,ntdc /153,12/ ! to read data after Christmas 2004

      COMMON / tofvar /tdcid,evcount,tdcmask,adc,tdc,temp1,temp2
      save / tofvar /
 
C         
C Begin ! 
C

C
C AAA : Bisogna definire un pattern per il tof
C

      ic = start
C
c      print *,'++++++++++ Tof Unpack ++++++++++++++++'

      do j = 1,ntdc
      ic0 = ic      ! primo indice per il calcolo del CRC
      tdcid(j) = 0
      evcount(j) = 0
      do bit = 0, 7
         bi = ibits(vecta(ic),bit,1)
         if (bi.eq.1) tdcid(j) = ibset(tdcid(j),bit)
         bi = ibits(vecta(ic+1),bit,1)
         if (bi.eq.1) evcount(j) = ibset(evcount(j),bit)
      enddo
c      print *,'tdcid(',j,')', 'evcount(',j,')'
c      print *,tdcid(j), evcount(j)
c
      ic=ic+2
      tdcmask(j) = 0
      do bit = 0, 7
         bi = ibits(vecta(ic),bit,1)
         if (bi.eq.1) tdcmask(j) = ibset(tdcmask(j),bit+8)
         bi = ibits(vecta(ic+1),bit,1)
         if (bi.eq.1) tdcmask(j) = ibset(tdcmask(j),bit)
      enddo
c      print *,'tdcmask(',j,')'
c      print *,tdcmask(j)

      ic=ic+2
      do i=1,4
         rawadc(i,j) = 0
         rawtdc(i,j) = 0
         grayadc(i,j) = 0
         graytdc(i,j) = 0
         do bit = 0, 7
           bi = ibits(vecta(ic),bit,1)
           if (bi.eq.1) rawadc(i,j) = ibset(rawadc(i,j),bit+8)
           bi = ibits(vecta(ic+1),bit,1)
           if (bi.eq.1) rawadc(i,j) = ibset(rawadc(i,j),bit)
           bi = ibits(vecta(ic+2),bit,1)
           if (bi.eq.1) rawtdc(i,j) = ibset(rawtdc(i,j),bit+8)
           bi = ibits(vecta(ic+3),bit,1)
           if (bi.eq.1) rawtdc(i,j) = ibset(rawtdc(i,j),bit)
        enddo
c        print *,'rawadc(',i,',',j,')','rawtdc(',i,',',j,')'
c        print *, rawadc(i,j),rawtdc(i,j)
c
c   adc e tdc data have to be translated from Gray code to binary (bit 0-11)
c    bit 12 is added after conversion  (control bit)
c    bit 13 is 1(0) for charge(time) information
c    bits 14-15 give the channel 1-4 on the board.
c
        grayadc(i,j)=ibits(rawadc(i,j),0,12)
        graytdc(i,j)=ibits(rawtdc(i,j),0,12)
c
       call graytobin(grayadc(i,j),adc(i,j),12)
       call graytobin(graytdc(i,j),tdc(i,j),12)
c        print *,'grayadc(',i,',',j,')','graytdc(',i,',',j,')'
c        print *, grayadc(i,j),graytdc(i,j)
c        print *,'adc(',i,',',j,')','tdc(',i,',',j,')','prima del bit 12'
c        print *, adc(i,j),tdc(i,j)
c
       bi = ibits(rawtdc(i,j),12,1)
       if (bi.eq.1) tdc(i,j) = ibset(tdc(i,j),12)
       bi = ibits(rawadc(i,j),12,1)
       if (bi.eq.1) adc(i,j) = ibset(adc(i,j),12)
c 
c        print *,'adc(',i,',',j,')','tdc(',i,',',j,')'
c        print *, adc(i,j),tdc(i,j)
c
        ic=ic+4
      enddo
c
      temp1(j) = 0
      temp2(j) = 0
      do bit = 0, 7
         bi = ibits(vecta(ic),bit,1)
         if (bi.eq.1) temp1(j) = ibset(temp1(j),bit)
         bi = ibits(vecta(ic+1),bit,1)
         if (bi.eq.1) temp2(j) = ibset(temp2(j),bit)
       enddo
c      print *,'temp1(',j,')', 'temp2(',j,')'
c      print *,temp1(j), temp2(j)

       ic=ic+2

c
c    vecta(ic) is the CRC
c Check consistency of CRC.
c
      if(vecta(ic).lt.0)vecta(ic)=vecta(ic)+256
      check = 0
      inf = ic0
      sup = ic - 1
      do i = inf,sup
         check=crctof(check,vecta(i))
      enddo
      if (check.ne.vecta(ic)) then
c         print *,'crc sbagliato ',vecta(ic), check
         me = 1
      else
c         print *,'crc corretto ',vecta(ic)
      endif

c
c        print *,'---------> ic, j' ,ic,j
        ic=ic+1

      enddo       !  j = 1,ntdc

   
      RETURN
      END


1	kusanagi	1.1	C--------------------------------------------------------------------
2			SUBROUTINE TOFUNPACK(vecta,lung,me)
3			C D.Campana, Dec. 04
4			C---------------------------------------------------------------------
5
6			IMPLICIT NONE
7
8			C
9			C Normal variables definition
10			C
11			integer lung
12			integer*1 vecta(lung)
13			integer me
14			integer check, crctof
15			integer ic0,sup,inf
16			integer i, ic, bit, bi,j
17			integer start,ntdc
18			integer tdcid(12),evcount(12)
19			integer tdcmask(12),adc(4,12),tdc(4,12)
20			integer rawadc(4,12),rawtdc(4,12),grayadc(4,12),graytdc(4,12)
21			integer temp1(12),temp2(12)
22			C
23			c data start,ntdc /150,12/ ! to read data before Christmas 2004
24			data start,ntdc /153,12/ ! to read data after Christmas 2004
25
26			COMMON / tofvar /tdcid,evcount,tdcmask,adc,tdc,temp1,temp2
27			save / tofvar /
28
29			C
30			C Begin !
31			C
32
33			C
34			C AAA : Bisogna definire un pattern per il tof
35			C
36
37			ic = start
38			C
39			c print *,'++++++++++ Tof Unpack ++++++++++++++++'
40
41			do j = 1,ntdc
42			ic0 = ic ! primo indice per il calcolo del CRC
43			tdcid(j) = 0
44			evcount(j) = 0
45			do bit = 0, 7
46			bi = ibits(vecta(ic),bit,1)
47			if (bi.eq.1) tdcid(j) = ibset(tdcid(j),bit)
48			bi = ibits(vecta(ic+1),bit,1)
49			if (bi.eq.1) evcount(j) = ibset(evcount(j),bit)
50			enddo
51			c print *,'tdcid(',j,')', 'evcount(',j,')'
52			c print *,tdcid(j), evcount(j)
53			c
54			ic=ic+2
55			tdcmask(j) = 0
56			do bit = 0, 7
57			bi = ibits(vecta(ic),bit,1)
58			if (bi.eq.1) tdcmask(j) = ibset(tdcmask(j),bit+8)
59			bi = ibits(vecta(ic+1),bit,1)
60			if (bi.eq.1) tdcmask(j) = ibset(tdcmask(j),bit)
61			enddo
62			c print *,'tdcmask(',j,')'
63			c print *,tdcmask(j)
64
65			ic=ic+2
66			do i=1,4
67			rawadc(i,j) = 0
68			rawtdc(i,j) = 0
69			grayadc(i,j) = 0
70			graytdc(i,j) = 0
71			do bit = 0, 7
72			bi = ibits(vecta(ic),bit,1)
73			if (bi.eq.1) rawadc(i,j) = ibset(rawadc(i,j),bit+8)
74			bi = ibits(vecta(ic+1),bit,1)
75			if (bi.eq.1) rawadc(i,j) = ibset(rawadc(i,j),bit)
76			bi = ibits(vecta(ic+2),bit,1)
77			if (bi.eq.1) rawtdc(i,j) = ibset(rawtdc(i,j),bit+8)
78			bi = ibits(vecta(ic+3),bit,1)
79			if (bi.eq.1) rawtdc(i,j) = ibset(rawtdc(i,j),bit)
80			enddo
81			c print *,'rawadc(',i,',',j,')','rawtdc(',i,',',j,')'
82			c print *, rawadc(i,j),rawtdc(i,j)
83			c
84			c adc e tdc data have to be translated from Gray code to binary (bit 0-11)
85			c bit 12 is added after conversion (control bit)
86			c bit 13 is 1(0) for charge(time) information
87			c bits 14-15 give the channel 1-4 on the board.
88			c
89			grayadc(i,j)=ibits(rawadc(i,j),0,12)
90			graytdc(i,j)=ibits(rawtdc(i,j),0,12)
91			c
92			call graytobin(grayadc(i,j),adc(i,j),12)
93			call graytobin(graytdc(i,j),tdc(i,j),12)
94			c print *,'grayadc(',i,',',j,')','graytdc(',i,',',j,')'
95			c print *, grayadc(i,j),graytdc(i,j)
96			c print *,'adc(',i,',',j,')','tdc(',i,',',j,')','prima del bit 12'
97			c print *, adc(i,j),tdc(i,j)
98			c
99			bi = ibits(rawtdc(i,j),12,1)
100			if (bi.eq.1) tdc(i,j) = ibset(tdc(i,j),12)
101			bi = ibits(rawadc(i,j),12,1)
102			if (bi.eq.1) adc(i,j) = ibset(adc(i,j),12)
103			c
104			c print *,'adc(',i,',',j,')','tdc(',i,',',j,')'
105			c print *, adc(i,j),tdc(i,j)
106			c
107			ic=ic+4
108			enddo
109			c
110			temp1(j) = 0
111			temp2(j) = 0
112			do bit = 0, 7
113			bi = ibits(vecta(ic),bit,1)
114			if (bi.eq.1) temp1(j) = ibset(temp1(j),bit)
115			bi = ibits(vecta(ic+1),bit,1)
116			if (bi.eq.1) temp2(j) = ibset(temp2(j),bit)
117			enddo
118			c print *,'temp1(',j,')', 'temp2(',j,')'
119			c print *,temp1(j), temp2(j)
120
121			ic=ic+2
122
123			c
124			c vecta(ic) is the CRC
125			c Check consistency of CRC.
126			c
127			if(vecta(ic).lt.0)vecta(ic)=vecta(ic)+256
128			check = 0
129			inf = ic0
130			sup = ic - 1
131			do i = inf,sup
132			check=crctof(check,vecta(i))
133			enddo
134			if (check.ne.vecta(ic)) then
135			c print *,'crc sbagliato ',vecta(ic), check
136			me = 1
137			else
138			c print *,'crc corretto ',vecta(ic)
139			endif
140
141			c
142			c print *,'---------> ic, j' ,ic,j
143			ic=ic+1
144
145			enddo ! j = 1,ntdc
146
147
148			RETURN
149			END
150
151
152