ground/src/read_B_inner.for

*************************************************************************
*     
*     Subroutine read_B_inner.f
*     
*     it reads from rz files the two magnetic field maps taken inside the
*     spectrometer cavity and fills the variables in common_B_inner.f
*     
*     needs:
*     - ../common/common_B_inner.f common file for the inner magnetic field map
*     - .rz map files in ./ containing coordinates of measured points, Bx, By
*     and Bz components + errors
*     
*     output variables: (see common_B_inner.f)
*     - px#(nx,3)         with #=1,2 for the 2 maps
*     - py#(ny,3)
*     - pz#(nz,3)
*     - b#(nx,ny,nz,3)
*     
*************************************************************************

      subroutine read_B_inner(idata_dir)
      include './common_B_inner.for'
c      implicit double precision (a-h,o-z)
      CHARACTER*250 idata_dir
      parameter(NWPAWC=200000)
      common/pawc/hmem(NWPAWC)
c      save/pawc/
      common/quest/iquest(100)
c      save/quest/


c------------------------------------------------------------------------
c     
c     local variables
c     
c------------------------------------------------------------------------
      integer lastnb
c      integer lung

      character*264 Bmap_file    !magnetic field file name
c      character*120 cmd1
c      character*120 cmd2
      parameter (lun_Bmap_file=66) !magnetic field map file id number

      parameter (ntpl_Bmap=20)  !ntuple identifier

      REAL*4 PFX(3),FX,DFX,       !Bx field component coordinates in m, value and error in T
     $     PFY(3),FY,DFY
     $     ,PFZ(3),FZ,DFZ
      INTEGER INDEX(3)          !point index
      integer ic,iev,iemax,istat

      COMMON /ntplvars/ INDEX,PFX,FX,DFX,PFY,FY,DFY,PFZ,FZ,DFZ
c      save/pawcr4/
      
c------------------------------------------------------------------------
c     
c     *** FIRST MAP ***
c     
c------------------------------------------------------------------------

c------------------------------------------------------------------------
c     
c     initialization and map file opening
c     
c------------------------------------------------------------------------

c      print*,' '
c      print*,' '
c      lastnb = length(idata_dir)
c      idata_dir(lastnb:lastnb+20)='/measure_n3_290302.rz'
c      lung = lastnb+20
      lastnb = length(idata_dir)-1
      Bmap_file = idata_dir(1:lastnb)//'/measure_n3_290302.rz'

c      Bmap_file='measure_n3_290302.rz'

c$$$      cmd1='cp $TRK_GRND/source/magnet/'
c$$$     $     //Bmap_file(1:LNBLNK(Bmap_file))//' .'         
c$$$      call system(cmd1)         
      
c     opens magnetic field map first file
c      print *,'Opening file: -',idata_dir(1:lung),'- '
      print *,'Opening file: ',Bmap_file(1:lastnb+21)
c      call HROPEN(lun_Bmap_file,'Bmap',idata_dir(1:lung),
      call HROPEN(lun_Bmap_file,'Bmap',Bmap_file,
     &     'P',1024,istat) 
c     $     (lun_Bmap_file,'Bmap',idata_dir(1:lung),'P',1024,istat) 
c     $     (lun_Bmap_file,'Bmap',
c     & '/wizard3/pamela/sw/calib/measure_n3_290302.rz',
c     & 'P',1024,istat) 
c     $     (lun_Bmap_file,'Bmap','./bin-aux/'//Bmap_file,'P',1024,istat) 
      if(istat.ne.0) goto 21

c      goto 9000
c      call HCDIR('//Bmap',' ')

c      goto 666


      call HRIN(ntpl_Bmap,9999,0) !puts B map ntuple in memory

c      call HPRNTU(ntpl_Bmap)
      call HBNAME(ntpl_Bmap,' ',0,'$CLEAR')
      call HBNAME(ntpl_Bmap,'INDEX',index,'$SET')
      call HBNAME(ntpl_Bmap,'BX',pfx,'$SET')
      call HBNAME(ntpl_Bmap,'BY',pfy,'$SET')
      call HBNAME(ntpl_Bmap,'BZ',pfz,'$SET')


c------------------------------------------------------------------------
c     
c     reads events and fills variables
c     
c------------------------------------------------------------------------

      call HNOENT(ntpl_Bmap,iemax) !number of events

c     initializes measurement grid edges
      do ic=1,3
        px1max(ic)=0.
        px1min(ic)=0.
        py1max(ic)=0.
        py1min(ic)=0.
        pz1max(ic)=0.
        pz1min(ic)=0.
      enddo


      do iev=1,iemax            !event loop

        call HGNT(ntpl_Bmap,iev,ierr) !reads event
        if(ierr.ne.0) goto 22

c     the output consists of matrices for coordinates, B components values 
c     and errors:
c     e.g. px1(4,2) = X coordinate of the point with index = 4 along X, 
c     in which By (=2) component has been measured
c     e.g. b1(3,23,4,1) = Bx (=1) component value, measured in the point with
c     indexes = 3,23,4 along X, Y and Z

c     Bx component
        px1(index(1),1) = pfx(1)
        if(px1(index(1),1).lt.px1min(1)) px1min(1)=px1(index(1),1)
        if(px1(index(1),1).gt.px1max(1)) px1max(1)=px1(index(1),1)
        py1(index(2),1) = pfx(2)
        if(py1(index(2),1).lt.py1min(1)) py1min(1)=py1(index(2),1)
        if(py1(index(2),1).gt.py1max(1)) py1max(1)=py1(index(2),1)
        pz1(index(3),1) = pfx(3)
        if(pz1(index(3),1).lt.pz1min(1)) pz1min(1)=pz1(index(3),1)
        if(pz1(index(3),1).gt.pz1max(1)) pz1max(1)=pz1(index(3),1)

        b1(index(1),index(2),index(3),1) = fx


c     By component
        px1(index(1),2) = pfy(1)
        if(px1(index(1),2).lt.px1min(2)) px1min(2)=px1(index(1),2)
        if(px1(index(1),2).gt.px1max(2)) px1max(2)=px1(index(1),2)
        py1(index(2),2) = pfy(2)
        if(py1(index(2),2).lt.py1min(2)) py1min(2)=py1(index(2),2)
        if(py1(index(2),2).gt.py1max(2)) py1max(2)=py1(index(2),2)
        pz1(index(3),2) = pfy(3)
        if(pz1(index(3),2).lt.pz1min(2)) pz1min(2)=pz1(index(3),2)
        if(pz1(index(3),2).gt.pz1max(2)) pz1max(2)=pz1(index(3),2)

        b1(index(1),index(2),index(3),2) = fy


c     Bz component
        px1(index(1),3) = pfz(1)
        if(px1(index(1),3).lt.px1min(3)) px1min(3)=px1(index(1),3)
        if(px1(index(1),3).gt.px1max(3)) px1max(3)=px1(index(1),3)
        py1(index(2),3) = pfz(2)
        if(py1(index(2),3).lt.py1min(3)) py1min(3)=py1(index(2),3)
        if(py1(index(2),3).gt.py1max(3)) py1max(3)=py1(index(2),3)
        pz1(index(3),3) = pfz(3)
        if(pz1(index(3),3).lt.pz1min(3)) pz1min(3)=pz1(index(3),3)
        if(pz1(index(3),3).gt.pz1max(3)) pz1max(3)=pz1(index(3),3)

        b1(index(1),index(2),index(3),3) = fz

      enddo


c------------------------------------------------------------------------
c     
c     closes files
c     
c------------------------------------------------------------------------

c 666  continue
      call HCDIR('//Bmap',' ')
      call HREND('Bmap')
      close(lun_Bmap_file)
c$$$      cmd2='rm -f '
c$$$     $     //Bmap_file(1:LNBLNK(Bmap_file))
c$$$      call system(cmd2)
c$$$

c      goto 9000
c------------------------------------------------------------------------
c     
c     *** SECOND MAP ***
c     
c------------------------------------------------------------------------

c------------------------------------------------------------------------
c     
c     initialization and map file opening
c     
c------------------------------------------------------------------------

c      print*,' '
c      print*,' '
      lastnb = length(idata_dir)-1
      Bmap_file = idata_dir(1:lastnb)//'/measure_n4_110402_corrected.rz'
c      lung = lastnb+30

c      Bmap_file='measure_n4_110402_corrected.rz'
c$$$      cmd1='cp $TRK_GRND/source/magnet/'
c$$$     $     //Bmap_file(1:LNBLNK(Bmap_file))//' .'         
c$$$      call system(cmd1)         

c     opens magnetic field map first file
      print *,'Opening file: ',Bmap_file(1:lastnb+31)
c      print *,'Opening file: -',idata_dir(1:lung),'- '
      call HROPEN
     $     (lun_Bmap_file,'Bmap',Bmap_file,'P',1024,istat) 
c     $     (lun_Bmap_file,'Bmap',idata_dir(1:lung),'P',1024,istat) 
c     $     (lun_Bmap_file,'Bmap','./bin-aux/'//Bmap_file,'P',1024,istat) 

c      idata_dir(lastnb:lastnb+1)='./'

      if(istat.ne.0) goto 21


      call HRIN(ntpl_Bmap,9999,0) !puts B map ntuple in memory

c      call HPRNTU(ntpl_Bmap)
      call HBNAME(ntpl_Bmap,' ',0,'$CLEAR')
      call HBNAME(ntpl_Bmap,'INDEX',index,'$SET')
      call HBNAME(ntpl_Bmap,'BX',pfx,'$SET')
      call HBNAME(ntpl_Bmap,'BY',pfy,'$SET')
      call HBNAME(ntpl_Bmap,'BZ',pfz,'$SET')


c------------------------------------------------------------------------
c     
c     reads events and fills variables
c     
c------------------------------------------------------------------------

      call HNOENT(ntpl_Bmap,iemax) !number of events

      do ic=1,3                  !grid edges
        px2max(ic)=0.
        px2min(ic)=0.
        py2max(ic)=0.
        py2min(ic)=0.
        pz2max(ic)=0.
        pz2min(ic)=0.
      enddo


      do iev=1,iemax            !event loop

        call HGNT(ntpl_Bmap,iev,ierr) !reads event
        if(ierr.ne.0) goto 22

c     the output consists of matrices for coordinates, B components values 
c     and errors:
c     e.g. px(4,2) = X coordinate of the point with index = 4 along X, 
c     in which By (=2) component has been measured
c     e.g. b(3,23,4,1) = Bx (=1) component value, measured in the point with
c     indexes = 3,23,4 along X, Y and Z

c     Bx component
        px2(index(1),1) = pfx(1)
        if(px2(index(1),1).lt.px2min(1)) px2min(1)=px2(index(1),1)
        if(px2(index(1),1).gt.px2max(1)) px2max(1)=px2(index(1),1)
        py2(index(2),1) = pfx(2)
        if(py2(index(2),1).lt.py2min(1)) py2min(1)=py2(index(2),1)
        if(py2(index(2),1).gt.py2max(1)) py2max(1)=py2(index(2),1)
        pz2(index(3),1) = pfx(3)
        if(pz2(index(3),1).lt.pz2min(1)) pz2min(1)=pz2(index(3),1)
        if(pz2(index(3),1).gt.pz2max(1)) pz2max(1)=pz2(index(3),1)

        b2(index(1),index(2),index(3),1) = fx


c     By component
        px2(index(1),2) = pfy(1)
        if(px2(index(1),2).lt.px2min(2)) px2min(2)=px2(index(1),2)
        if(px2(index(1),2).gt.px2max(2)) px2max(2)=px2(index(1),2)
        py2(index(2),2) = pfy(2)
        if(py2(index(2),2).lt.py2min(2)) py2min(2)=py2(index(2),2)
        if(py2(index(2),2).gt.py2max(2)) py2max(2)=py2(index(2),2)
        pz2(index(3),2) = pfy(3)
        if(pz2(index(3),2).lt.pz2min(2)) pz2min(2)=pz2(index(3),2)
        if(pz2(index(3),2).gt.pz2max(2)) pz2max(2)=pz2(index(3),2)

        b2(index(1),index(2),index(3),2) = fy


c     Bz component
        px2(index(1),3) = pfz(1)
        if(px2(index(1),3).lt.px2min(3)) px2min(3)=px2(index(1),3)
        if(px2(index(1),3).gt.px2max(3)) px2max(3)=px2(index(1),3)
        py2(index(2),3) = pfz(2)
        if(py2(index(2),3).lt.py2min(3)) py2min(3)=py2(index(2),3)
        if(py2(index(2),3).gt.py2max(3)) py2max(3)=py2(index(2),3)
        pz2(index(3),3) = pfz(3)
        if(pz2(index(3),3).lt.pz2min(3)) pz2min(3)=pz2(index(3),3)
        if(pz2(index(3),3).gt.pz2max(3)) pz2max(3)=pz2(index(3),3)

        b2(index(1),index(2),index(3),3) = fz

      enddo


c------------------------------------------------------------------------
c     
c     closes files
c     
c------------------------------------------------------------------------
      call HCDIR('//Bmap',' ')
      call HREND('Bmap')
      close(lun_Bmap_file)
c$$$      cmd2='rm -f '
c$$$     $     //Bmap_file(1:LNBLNK(Bmap_file))
c$$$      call system(cmd2)


c------------------------------------------------------------------------
c     
c     no error exit
c     
c------------------------------------------------------------------------

c$$$      print*,' '
c$$$      print*,'MAGNETIC FIELD SUCCESSFULLY READ'
c$$$      print*,' '
c$$$      print*,' '
      
      goto 9000                 !happy ending

c------------------------------------------------------------------------
c     
c     magnetic field map file opening error
c     
c------------------------------------------------------------------------
      
 21   continue
      
      print*,' '
      print*,'read_B_inner: ERROR OPENING MAGNETIC FIELD MAP FILE: '
     $     ,Bmap_file
      print*,' '
      print*,' '
      
      goto 9000                 !the end


c------------------------------------------------------------------------
c     
c     ntuple event reading error
c     
c------------------------------------------------------------------------
      
 22   continue
      
      print*,' '
      print*,'read_B_inner: ERROR WHILE READING NTUPLE, AT EVENT
     $     : ',iev
      print*,' '
      print*,' '
      
      goto 9000                 !the end


c------------------------------------------------------------------------
c     
c     exit
c     
c------------------------------------------------------------------------

 9000 continue

      return
      end
1	*************************************************************************
2	*
3	* Subroutine read_B_inner.f
4	*
5	* it reads from rz files the two magnetic field maps taken inside the
6	* spectrometer cavity and fills the variables in common_B_inner.f
7	*
8	* needs:
9	* - ../common/common_B_inner.f common file for the inner magnetic field map
10	* - .rz map files in ./ containing coordinates of measured points, Bx, By
11	* and Bz components + errors
12	*
13	* output variables: (see common_B_inner.f)
14	* - px#(nx,3) with #=1,2 for the 2 maps
15	* - py#(ny,3)
16	* - pz#(nz,3)
17	* - b#(nx,ny,nz,3)
18	*
19	*************************************************************************
20
21	subroutine read_B_inner(idata_dir)
22	include './common_B_inner.for'
23	c implicit double precision (a-h,o-z)
24	CHARACTER*250 idata_dir
25	parameter(NWPAWC=200000)
26	common/pawc/hmem(NWPAWC)
27	c save/pawc/
28	common/quest/iquest(100)
29	c save/quest/
30
31
32	c------------------------------------------------------------------------
33	c
34	c local variables
35	c
36	c------------------------------------------------------------------------
37	integer lastnb
38	c integer lung
39
40	character*264 Bmap_file !magnetic field file name
41	c character*120 cmd1
42	c character*120 cmd2
43	parameter (lun_Bmap_file=66) !magnetic field map file id number
44
45	parameter (ntpl_Bmap=20) !ntuple identifier
46
47	REAL*4 PFX(3),FX,DFX, !Bx field component coordinates in m, value and error in T
48	$ PFY(3),FY,DFY
49	$ ,PFZ(3),FZ,DFZ
50	INTEGER INDEX(3) !point index
51	integer ic,iev,iemax,istat
52
53	COMMON /ntplvars/ INDEX,PFX,FX,DFX,PFY,FY,DFY,PFZ,FZ,DFZ
54	c save/pawcr4/
55
56	c------------------------------------------------------------------------
57	c
58	c * FIRST MAP *
59	c
60	c------------------------------------------------------------------------
61
62	c------------------------------------------------------------------------
63	c
64	c initialization and map file opening
65	c
66	c------------------------------------------------------------------------
67
68	c print*,' '
69	c print*,' '
70	c lastnb = length(idata_dir)
71	c idata_dir(lastnb:lastnb+20)='/measure_n3_290302.rz'
72	c lung = lastnb+20
73	lastnb = length(idata_dir)-1
74	Bmap_file = idata_dir(1:lastnb)//'/measure_n3_290302.rz'
75
76	c Bmap_file='measure_n3_290302.rz'
77
78	c$$$ cmd1='cp $TRK_GRND/source/magnet/'
79	c$$$ $ //Bmap_file(1:LNBLNK(Bmap_file))//' .'
80	c$$$ call system(cmd1)
81
82	c opens magnetic field map first file
83	c print *,'Opening file: -',idata_dir(1:lung),'- '
84	print *,'Opening file: ',Bmap_file(1:lastnb+21)
85	c call HROPEN(lun_Bmap_file,'Bmap',idata_dir(1:lung),
86	call HROPEN(lun_Bmap_file,'Bmap',Bmap_file,
87	& 'P',1024,istat)
88	c $ (lun_Bmap_file,'Bmap',idata_dir(1:lung),'P',1024,istat)
89	c $ (lun_Bmap_file,'Bmap',
90	c & '/wizard3/pamela/sw/calib/measure_n3_290302.rz',
91	c & 'P',1024,istat)
92	c $ (lun_Bmap_file,'Bmap','./bin-aux/'//Bmap_file,'P',1024,istat)
93	if(istat.ne.0) goto 21
94
95	c goto 9000
96	c call HCDIR('//Bmap',' ')
97
98	c goto 666
99
100
101	call HRIN(ntpl_Bmap,9999,0) !puts B map ntuple in memory
102
103	c call HPRNTU(ntpl_Bmap)
104	call HBNAME(ntpl_Bmap,' ',0,'$CLEAR')
105	call HBNAME(ntpl_Bmap,'INDEX',index,'$SET')
106	call HBNAME(ntpl_Bmap,'BX',pfx,'$SET')
107	call HBNAME(ntpl_Bmap,'BY',pfy,'$SET')
108	call HBNAME(ntpl_Bmap,'BZ',pfz,'$SET')
109
110
111	c------------------------------------------------------------------------
112	c
113	c reads events and fills variables
114	c
115	c------------------------------------------------------------------------
116
117	call HNOENT(ntpl_Bmap,iemax) !number of events
118
119	c initializes measurement grid edges
120	do ic=1,3
121	px1max(ic)=0.
122	px1min(ic)=0.
123	py1max(ic)=0.
124	py1min(ic)=0.
125	pz1max(ic)=0.
126	pz1min(ic)=0.
127	enddo
128
129
130	do iev=1,iemax !event loop
131
132	call HGNT(ntpl_Bmap,iev,ierr) !reads event
133	if(ierr.ne.0) goto 22
134
135	c the output consists of matrices for coordinates, B components values
136	c and errors:
137	c e.g. px1(4,2) = X coordinate of the point with index = 4 along X,
138	c in which By (=2) component has been measured
139	c e.g. b1(3,23,4,1) = Bx (=1) component value, measured in the point with
140	c indexes = 3,23,4 along X, Y and Z
141
142	c Bx component
143	px1(index(1),1) = pfx(1)
144	if(px1(index(1),1).lt.px1min(1)) px1min(1)=px1(index(1),1)
145	if(px1(index(1),1).gt.px1max(1)) px1max(1)=px1(index(1),1)
146	py1(index(2),1) = pfx(2)
147	if(py1(index(2),1).lt.py1min(1)) py1min(1)=py1(index(2),1)
148	if(py1(index(2),1).gt.py1max(1)) py1max(1)=py1(index(2),1)
149	pz1(index(3),1) = pfx(3)
150	if(pz1(index(3),1).lt.pz1min(1)) pz1min(1)=pz1(index(3),1)
151	if(pz1(index(3),1).gt.pz1max(1)) pz1max(1)=pz1(index(3),1)
152
153	b1(index(1),index(2),index(3),1) = fx
154
155
156	c By component
157	px1(index(1),2) = pfy(1)
158	if(px1(index(1),2).lt.px1min(2)) px1min(2)=px1(index(1),2)
159	if(px1(index(1),2).gt.px1max(2)) px1max(2)=px1(index(1),2)
160	py1(index(2),2) = pfy(2)
161	if(py1(index(2),2).lt.py1min(2)) py1min(2)=py1(index(2),2)
162	if(py1(index(2),2).gt.py1max(2)) py1max(2)=py1(index(2),2)
163	pz1(index(3),2) = pfy(3)
164	if(pz1(index(3),2).lt.pz1min(2)) pz1min(2)=pz1(index(3),2)
165	if(pz1(index(3),2).gt.pz1max(2)) pz1max(2)=pz1(index(3),2)
166
167	b1(index(1),index(2),index(3),2) = fy
168
169
170	c Bz component
171	px1(index(1),3) = pfz(1)
172	if(px1(index(1),3).lt.px1min(3)) px1min(3)=px1(index(1),3)
173	if(px1(index(1),3).gt.px1max(3)) px1max(3)=px1(index(1),3)
174	py1(index(2),3) = pfz(2)
175	if(py1(index(2),3).lt.py1min(3)) py1min(3)=py1(index(2),3)
176	if(py1(index(2),3).gt.py1max(3)) py1max(3)=py1(index(2),3)
177	pz1(index(3),3) = pfz(3)
178	if(pz1(index(3),3).lt.pz1min(3)) pz1min(3)=pz1(index(3),3)
179	if(pz1(index(3),3).gt.pz1max(3)) pz1max(3)=pz1(index(3),3)
180
181	b1(index(1),index(2),index(3),3) = fz
182
183	enddo
184
185
186	c------------------------------------------------------------------------
187	c
188	c closes files
189	c
190	c------------------------------------------------------------------------
191
192	c 666 continue
193	call HCDIR('//Bmap',' ')
194	call HREND('Bmap')
195	close(lun_Bmap_file)
196	c$$$ cmd2='rm -f '
197	c$$$ $ //Bmap_file(1:LNBLNK(Bmap_file))
198	c$$$ call system(cmd2)
199	c$$$
200
201	c goto 9000
202	c------------------------------------------------------------------------
203	c
204	c * SECOND MAP *
205	c
206	c------------------------------------------------------------------------
207
208	c------------------------------------------------------------------------
209	c
210	c initialization and map file opening
211	c
212	c------------------------------------------------------------------------
213
214	c print*,' '
215	c print*,' '
216	lastnb = length(idata_dir)-1
217	Bmap_file = idata_dir(1:lastnb)//'/measure_n4_110402_corrected.rz'
218	c lung = lastnb+30
219
220	c Bmap_file='measure_n4_110402_corrected.rz'
221	c$$$ cmd1='cp $TRK_GRND/source/magnet/'
222	c$$$ $ //Bmap_file(1:LNBLNK(Bmap_file))//' .'
223	c$$$ call system(cmd1)
224
225	c opens magnetic field map first file
226	print *,'Opening file: ',Bmap_file(1:lastnb+31)
227	c print *,'Opening file: -',idata_dir(1:lung),'- '
228	call HROPEN
229	$ (lun_Bmap_file,'Bmap',Bmap_file,'P',1024,istat)
230	c $ (lun_Bmap_file,'Bmap',idata_dir(1:lung),'P',1024,istat)
231	c $ (lun_Bmap_file,'Bmap','./bin-aux/'//Bmap_file,'P',1024,istat)
232
233	c idata_dir(lastnb:lastnb+1)='./'
234
235	if(istat.ne.0) goto 21
236
237
238	call HRIN(ntpl_Bmap,9999,0) !puts B map ntuple in memory
239
240	c call HPRNTU(ntpl_Bmap)
241	call HBNAME(ntpl_Bmap,' ',0,'$CLEAR')
242	call HBNAME(ntpl_Bmap,'INDEX',index,'$SET')
243	call HBNAME(ntpl_Bmap,'BX',pfx,'$SET')
244	call HBNAME(ntpl_Bmap,'BY',pfy,'$SET')
245	call HBNAME(ntpl_Bmap,'BZ',pfz,'$SET')
246
247
248	c------------------------------------------------------------------------
249	c
250	c reads events and fills variables
251	c
252	c------------------------------------------------------------------------
253
254	call HNOENT(ntpl_Bmap,iemax) !number of events
255
256	do ic=1,3 !grid edges
257	px2max(ic)=0.
258	px2min(ic)=0.
259	py2max(ic)=0.
260	py2min(ic)=0.
261	pz2max(ic)=0.
262	pz2min(ic)=0.
263	enddo
264
265
266	do iev=1,iemax !event loop
267
268	call HGNT(ntpl_Bmap,iev,ierr) !reads event
269	if(ierr.ne.0) goto 22
270
271	c the output consists of matrices for coordinates, B components values
272	c and errors:
273	c e.g. px(4,2) = X coordinate of the point with index = 4 along X,
274	c in which By (=2) component has been measured
275	c e.g. b(3,23,4,1) = Bx (=1) component value, measured in the point with
276	c indexes = 3,23,4 along X, Y and Z
277
278	c Bx component
279	px2(index(1),1) = pfx(1)
280	if(px2(index(1),1).lt.px2min(1)) px2min(1)=px2(index(1),1)
281	if(px2(index(1),1).gt.px2max(1)) px2max(1)=px2(index(1),1)
282	py2(index(2),1) = pfx(2)
283	if(py2(index(2),1).lt.py2min(1)) py2min(1)=py2(index(2),1)
284	if(py2(index(2),1).gt.py2max(1)) py2max(1)=py2(index(2),1)
285	pz2(index(3),1) = pfx(3)
286	if(pz2(index(3),1).lt.pz2min(1)) pz2min(1)=pz2(index(3),1)
287	if(pz2(index(3),1).gt.pz2max(1)) pz2max(1)=pz2(index(3),1)
288
289	b2(index(1),index(2),index(3),1) = fx
290
291
292	c By component
293	px2(index(1),2) = pfy(1)
294	if(px2(index(1),2).lt.px2min(2)) px2min(2)=px2(index(1),2)
295	if(px2(index(1),2).gt.px2max(2)) px2max(2)=px2(index(1),2)
296	py2(index(2),2) = pfy(2)
297	if(py2(index(2),2).lt.py2min(2)) py2min(2)=py2(index(2),2)
298	if(py2(index(2),2).gt.py2max(2)) py2max(2)=py2(index(2),2)
299	pz2(index(3),2) = pfy(3)
300	if(pz2(index(3),2).lt.pz2min(2)) pz2min(2)=pz2(index(3),2)
301	if(pz2(index(3),2).gt.pz2max(2)) pz2max(2)=pz2(index(3),2)
302
303	b2(index(1),index(2),index(3),2) = fy
304
305
306	c Bz component
307	px2(index(1),3) = pfz(1)
308	if(px2(index(1),3).lt.px2min(3)) px2min(3)=px2(index(1),3)
309	if(px2(index(1),3).gt.px2max(3)) px2max(3)=px2(index(1),3)
310	py2(index(2),3) = pfz(2)
311	if(py2(index(2),3).lt.py2min(3)) py2min(3)=py2(index(2),3)
312	if(py2(index(2),3).gt.py2max(3)) py2max(3)=py2(index(2),3)
313	pz2(index(3),3) = pfz(3)
314	if(pz2(index(3),3).lt.pz2min(3)) pz2min(3)=pz2(index(3),3)
315	if(pz2(index(3),3).gt.pz2max(3)) pz2max(3)=pz2(index(3),3)
316
317	b2(index(1),index(2),index(3),3) = fz
318
319	enddo
320
321
322	c------------------------------------------------------------------------
323	c
324	c closes files
325	c
326	c------------------------------------------------------------------------
327	call HCDIR('//Bmap',' ')
328	call HREND('Bmap')
329	close(lun_Bmap_file)
330	c$$$ cmd2='rm -f '
331	c$$$ $ //Bmap_file(1:LNBLNK(Bmap_file))
332	c$$$ call system(cmd2)
333
334
335	c------------------------------------------------------------------------
336	c
337	c no error exit
338	c
339	c------------------------------------------------------------------------
340
341	c$$$ print*,' '
342	c$$$ print*,'MAGNETIC FIELD SUCCESSFULLY READ'
343	c$$$ print*,' '
344	c$$$ print*,' '
345
346	goto 9000 !happy ending
347
348	c------------------------------------------------------------------------
349	c
350	c magnetic field map file opening error
351	c
352	c------------------------------------------------------------------------
353
354	21 continue
355
356	print*,' '
357	print*,'read_B_inner: ERROR OPENING MAGNETIC FIELD MAP FILE: '
358	$ ,Bmap_file
359	print*,' '
360	print*,' '
361
362	goto 9000 !the end
363
364
365	c------------------------------------------------------------------------
366	c
367	c ntuple event reading error
368	c
369	c------------------------------------------------------------------------
370
371	22 continue
372
373	print*,' '
374	print*,'read_B_inner: ERROR WHILE READING NTUPLE, AT EVENT
375	$ : ',iev
376	print*,' '
377	print*,' '
378
379	goto 9000 !the end
380
381
382	c------------------------------------------------------------------------
383	c
384	c exit
385	c
386	c------------------------------------------------------------------------
387
388	9000 continue
389
390	return
391	end