src/F77/readB.f

*************************************************************************
*     
*     Subroutine read_B.f
*     
*     it calls the subroutines which read the magnetic field maps for
*     the PAMELA spectrometer
*     
*     needs:
*     - ./read_B_inner.f inner map reading subroutine
*     - ./read_B_outer.f outer map reading subroutine
*     
*     to be called before ./inter_B.f (interpolation subroutine)
*     
*************************************************************************

      subroutine readB(cpath)
      include 'common_c2f.f'
      character*80 cpath
      character*80 ppath

      
      b_error=0

      la=80
      do i=1,80
         if(cpath(i:i).eq.'/')la=i
      enddo
      ppath=cpath(1:la)

      b_path    = ppath
      b_pathlen = la

c     FUNZIONAAAAAAAAAAAAAAA!!!!!!!!!!!!!!!!!!

      if(b_debug.eq.1)print*,'Field loaded: ',b_loaded
      if(b_loaded.eq.0)then

c     call the subroutine which reads the maps of the measurements taken
c     inside the magnetic cavity      
         call readBinner(ppath)
         if(b_error.eq.1)return

c     call the subroutine which reads the maps of the measurements taken
c     outside the magnetic cavity
         call readBouter(ppath)   
         if(b_error.eq.1)return

         b_loaded  = 1
      endif

      return
      end

************************************************************


*************************************************************************
*     
*     Subroutine readBinner
*     
*     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_B.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 readBinner(path)

c     implicit double precision (a-h,o-z)
      include 'common_B.f'
      include 'common_c2f.f'
      character*80 path
      
C
      REAL hmemor(10000000)
      integer Iquest(100)    
      COMMON /pawc/hmemor
      save /pawc/
C
      Common /QUEST/ Iquest
      save /quest/
     

c------------------------------------------------------------------------
c     
c     local variables
c     
c------------------------------------------------------------------------

      character*64 Bmap_file    !magnetic field file name
      parameter (lun_Bmap_file=66) !magnetic field map file id number

      parameter (ntpl_Bmap=20)  !ntuple identifier

      REAL 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

      COMMON /PAWCR4/ INDEX,PFX,FX,DFX,PFY,FY,DFY,PFZ,FZ,DFZ

   
      CALL HLIMIT(10000000)
C     - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - -
C     largest RZ file: IQUEST(10) records x LREC words x 4 byte
C     with the following settings: 65000 x 4096 x 4 = 1G
C     - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - 
      
c     permette di ottenere ntuple funzionanti nonostante
c     il messaggio dei 64K di RZOUT
      Iquest(10) = 512000
c------------------------------------------------------------------------
c     
c     *** FIRST MAP ***
c     
c------------------------------------------------------------------------

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

c     print*,' '
c     print*,' '

      Bmap_file='measure_n3_290302.rz'
      
c     opens magnetic field map first file
      if(b_debug.eq.1)print *                 
     $     ,path(1:LNBLNK(path))//Bmap_file
      call HROPEN
     $     (lun_Bmap_file,'Bmap'
     $     ,path(1:LNBLNK(path))//Bmap_file
     $     ,'P',1024,istat) 
      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

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------------------------------------------------------------------------

      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     
c     *** SECOND MAP ***
c     
c------------------------------------------------------------------------

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

c     print*,' '
c     print*,' '

      Bmap_file='measure_n4_110402_corrected.rz'
c     opens magnetic field map first file
      if(b_debug.eq.1)print *                   !,'Opening file: '
     $     ,path(1:LNBLNK(path))//Bmap_file
      call HROPEN
     $     (lun_Bmap_file,'Bmap'
     $     ,path(1:LNBLNK(path))//Bmap_file
     $     ,'P',1024,istat) 
      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

c      print*,'iemax ',iemax

      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 HREND('Bmap')
      close(lun_Bmap_file)

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

      goto 9000                 !happy ending

c------------------------------------------------------------------------
c     
c     magnetic field map file opening error
c     
c------------------------------------------------------------------------
      
 21   continue
      
      b_error = 1
      if(b_debug.eq.1)
     $     print*
     $     ,'read_B_inner: ERROR OPENING MAGNETIC FIELD MAP FILE: '
     $     ,Bmap_file
      
      goto 9000                 !the end


c------------------------------------------------------------------------
c     
c     ntuple event reading error
c     
c------------------------------------------------------------------------
      
 22   continue
      
      b_error = 1
      if(b_debug.eq.1)
     $     print*,'read_B_inner: ERROR WHILE READING NTUPLE, at entry
     $     : ',iev
      
      goto 9000                 !the end


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

 9000 continue

      return
      end
*************************************************************************
*     
*     Subroutine readBouter
*     
*     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_B_outer.f common file for the outer magnetic field map
*     - .rz map files in ./ containing coordinates of measured points, Bx, By
*     and Bz components + errors
*     
*     output variables: (see common_B_outer.f)
*     - pxo(nx,3)        
*     - pyo(ny,3)
*     - pzo(nz,3)
*     - bo(nx,ny,nz,3)
*     
*************************************************************************

      subroutine readBouter(path)

c     implicit double precision (a-h,o-z)
      include 'common_B.f'
      include 'common_c2f.f'
C
      character*80 path

      REAL hmemor(10000000)
      integer Iquest(100)    
      COMMON /pawc/hmemor
      save /pawc/
C
      Common /QUEST/ Iquest
      save /quest/
     

c------------------------------------------------------------------------
c     
c     local variables
c     
c------------------------------------------------------------------------

      character*64 Bmap_file    !magnetic field file name
      parameter (lun_Bmap_file=66) !magnetic field map file id number

      parameter (ntpl_Bmap=20)  !ntuple identifier

      REAL 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

      COMMON /PAWCR4/ INDEX,PFX,FX,DFX,PFY,FY,DFY,PFZ,FZ,DFZ

   
c      print*,'Calling HLIMIT'
      CALL HLIMIT(10000000)
C     - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - -
C     largest RZ file: IQUEST(10) records x LREC words x 4 byte
C     with the following settings: 65000 x 4096 x 4 = 1G
C     - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - 
      
c     permette di ottenere ntuple funzionanti nonostante
c     il messaggio dei 64K di RZOUT
      Iquest(10) = 512000
c------------------------------------------------------------------------
c     
c     *** FIRST MAP ***
c     
c------------------------------------------------------------------------

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

c     print*,' '
c     print*,' '

      Bmap_file='External_top_map_n4_150402.rz'
      
c     opens magnetic field map first file
      if(b_debug.eq.1)print *
     $     ,path(1:LNBLNK(path))//Bmap_file
      call HROPEN
     $     (lun_Bmap_file,'Bmap'
     $     ,path(1:LNBLNK(path))//Bmap_file
     $     ,'P',1024,istat) 
      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

c     initializes measurement grid edges
      do ic=1,3
        poxmax(ic)=0.
        poxmin(ic)=0.
        poymax(ic)=0.
        poymin(ic)=0.
        pozmax(ic)=0.
        pozmin(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
        pox(index(1),1) = pfx(1)
        if(pox(index(1),1).lt.poxmin(1)) poxmin(1)=pox(index(1),1)
        if(pox(index(1),1).gt.poxmax(1)) poxmax(1)=pox(index(1),1)
        poy(index(2),1) = pfx(2)
        if(poy(index(2),1).lt.poymin(1)) poymin(1)=poy(index(2),1)
        if(poy(index(2),1).gt.poymax(1)) poymax(1)=poy(index(2),1)
        poz(index(3),1) = pfx(3)
        if(poz(index(3),1).lt.pozmin(1)) pozmin(1)=poz(index(3),1)
        if(poz(index(3),1).gt.pozmax(1)) pozmax(1)=poz(index(3),1)

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


c     By component
        pox(index(1),2) = pfy(1)
        if(pox(index(1),2).lt.poxmin(2)) poxmin(2)=pox(index(1),2)
        if(pox(index(1),2).gt.poxmax(2)) poxmax(2)=pox(index(1),2)
        poy(index(2),2) = pfy(2)
        if(poy(index(2),2).lt.poymin(2)) poymin(2)=poy(index(2),2)
        if(poy(index(2),2).gt.poymax(2)) poymax(2)=poy(index(2),2)
        poz(index(3),2) = pfy(3)
        if(poz(index(3),2).lt.pozmin(2)) pozmin(2)=poz(index(3),2)
        if(poz(index(3),2).gt.pozmax(2)) pozmax(2)=poz(index(3),2)

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


c     Bz component
        pox(index(1),3) = pfz(1)
        if(pox(index(1),3).lt.poxmin(3)) poxmin(3)=pox(index(1),3)
        if(pox(index(1),3).gt.poxmax(3)) poxmax(3)=pox(index(1),3)
        poy(index(2),3) = pfz(2)
        if(poy(index(2),3).lt.poymin(3)) poymin(3)=poy(index(2),3)
        if(poy(index(2),3).gt.poymax(3)) poymax(3)=poy(index(2),3)
        poz(index(3),3) = pfz(3)
        if(poz(index(3),3).lt.pozmin(3)) pozmin(3)=poz(index(3),3)
        if(poz(index(3),3).gt.pozmax(3)) pozmax(3)=poz(index(3),3)

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

      enddo


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

      call HREND('Bmap')
      close(lun_Bmap_file)


c------------------------------------------------------------------------
c     
c     no error exit
c     
c------------------------------------------------------------------------
      
      goto 9000                 !happy ending

c------------------------------------------------------------------------
c     
c     magnetic field map file opening error
c     
c------------------------------------------------------------------------
      
 21   continue
      
      b_error = 1
      if(b_debug.eq.1)
     $     print*
     $     ,'read_B_inner: ERROR OPENING MAGNETIC FIELD MAP FILE: '
     $     ,Bmap_file
      
      goto 9000                 !the end


c------------------------------------------------------------------------
c     
c     ntuple event reading error
c     
c------------------------------------------------------------------------
      
 22   continue
      
      b_error = 1
      if(b_debug.eq.1)
     $     print*
     $     ,'read_B_inner: ERROR WHILE READING NTUPLE, at event
     $     : ',iev
      
      goto 9000                 !the end


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

 9000 continue

      return
      end

1	*************************************************************************
2	*
3	* Subroutine read_B.f
4	*
5	* it calls the subroutines which read the magnetic field maps for
6	* the PAMELA spectrometer
7	*
8	* needs:
9	* - ./read_B_inner.f inner map reading subroutine
10	* - ./read_B_outer.f outer map reading subroutine
11	*
12	* to be called before ./inter_B.f (interpolation subroutine)
13	*
14	*************************************************************************
15
16	subroutine readB(cpath)
17	include 'common_c2f.f'
18	character*80 cpath
19	character*80 ppath
20
21
22	b_error=0
23
24	la=80
25	do i=1,80
26	if(cpath(i:i).eq.'/')la=i
27	enddo
28	ppath=cpath(1:la)
29
30	b_path = ppath
31	b_pathlen = la
32
33	c FUNZIONAAAAAAAAAAAAAAA!!!!!!!!!!!!!!!!!!
34
35	if(b_debug.eq.1)print*,'Field loaded: ',b_loaded
36	if(b_loaded.eq.0)then
37
38	c call the subroutine which reads the maps of the measurements taken
39	c inside the magnetic cavity
40	call readBinner(ppath)
41	if(b_error.eq.1)return
42
43	c call the subroutine which reads the maps of the measurements taken
44	c outside the magnetic cavity
45	call readBouter(ppath)
46	if(b_error.eq.1)return
47
48	b_loaded = 1
49	endif
50
51	return
52	end
53
54	************************************************************
55
56
57	*************************************************************************
58	*
59	* Subroutine readBinner
60	*
61	* it reads from rz files the two magnetic field maps taken inside the
62	* spectrometer cavity and fills the variables in common_B_inner.f
63	*
64	* needs:
65	* - common_B.f common file for the inner magnetic field map
66	* - .rz map files in ./ containing coordinates of measured points, Bx, By
67	* and Bz components + errors
68	*
69	* output variables: (see common_B_inner.f)
70	* - px#(nx,3) with #=1,2 for the 2 maps
71	* - py#(ny,3)
72	* - pz#(nz,3)
73	* - b#(nx,ny,nz,3)
74	*
75	*************************************************************************
76
77	subroutine readBinner(path)
78
79	c implicit double precision (a-h,o-z)
80	include 'common_B.f'
81	include 'common_c2f.f'
82	character*80 path
83
84	C
85	REAL hmemor(10000000)
86	integer Iquest(100)
87	COMMON /pawc/hmemor
88	save /pawc/
89	C
90	Common /QUEST/ Iquest
91	save /quest/
92
93
94	c------------------------------------------------------------------------
95	c
96	c local variables
97	c
98	c------------------------------------------------------------------------
99
100	character*64 Bmap_file !magnetic field file name
101	parameter (lun_Bmap_file=66) !magnetic field map file id number
102
103	parameter (ntpl_Bmap=20) !ntuple identifier
104
105	REAL PFX(3),FX,DFX, !Bx field component coordinates in m, value and error in T
106	$ PFY(3),FY,DFY
107	$ ,PFZ(3),FZ,DFZ
108	INTEGER INDEX(3) !point index
109
110	COMMON /PAWCR4/ INDEX,PFX,FX,DFX,PFY,FY,DFY,PFZ,FZ,DFZ
111
112
113	CALL HLIMIT(10000000)
114	C - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - -
115	C largest RZ file: IQUEST(10) records x LREC words x 4 byte
116	C with the following settings: 65000 x 4096 x 4 = 1G
117	C - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - -
118
119	c permette di ottenere ntuple funzionanti nonostante
120	c il messaggio dei 64K di RZOUT
121	Iquest(10) = 512000
122	c------------------------------------------------------------------------
123	c
124	c * FIRST MAP *
125	c
126	c------------------------------------------------------------------------
127
128	c------------------------------------------------------------------------
129	c
130	c initialization and map file opening
131	c
132	c------------------------------------------------------------------------
133
134	c print*,' '
135	c print*,' '
136
137	Bmap_file='measure_n3_290302.rz'
138
139	c opens magnetic field map first file
140	if(b_debug.eq.1)print *
141	$ ,path(1:LNBLNK(path))//Bmap_file
142	call HROPEN
143	$ (lun_Bmap_file,'Bmap'
144	$ ,path(1:LNBLNK(path))//Bmap_file
145	$ ,'P',1024,istat)
146	if(istat.ne.0) goto 21
147
148
149	call HRIN(ntpl_Bmap,9999,0) !puts B map ntuple in memory
150
151	c call HPRNTU(ntpl_Bmap)
152	call HBNAME(ntpl_Bmap,' ',0,'$CLEAR')
153	call HBNAME(ntpl_Bmap,'INDEX',index,'$SET')
154	call HBNAME(ntpl_Bmap,'BX',pfx,'$SET')
155	call HBNAME(ntpl_Bmap,'BY',pfy,'$SET')
156	call HBNAME(ntpl_Bmap,'BZ',pfz,'$SET')
157
158
159	c------------------------------------------------------------------------
160	c
161	c reads events and fills variables
162	c
163	c------------------------------------------------------------------------
164
165	call HNOENT(ntpl_Bmap,iemax) !number of events
166
167	c initializes measurement grid edges
168	do ic=1,3
169	px1max(ic)=0.
170	px1min(ic)=0.
171	py1max(ic)=0.
172	py1min(ic)=0.
173	pz1max(ic)=0.
174	pz1min(ic)=0.
175	enddo
176
177
178	do iev=1,iemax !event loop
179
180	call HGNT(ntpl_Bmap,iev,ierr) !reads event
181	if(ierr.ne.0) goto 22
182
183	c the output consists of matrices for coordinates, B components values
184	c and errors:
185	c e.g. px1(4,2) = X coordinate of the point with index = 4 along X,
186	c in which By (=2) component has been measured
187	c e.g. b1(3,23,4,1) = Bx (=1) component value, measured in the point with
188	c indexes = 3,23,4 along X, Y and Z
189
190	c Bx component
191	px1(index(1),1) = pfx(1)
192	if(px1(index(1),1).lt.px1min(1)) px1min(1)=px1(index(1),1)
193	if(px1(index(1),1).gt.px1max(1)) px1max(1)=px1(index(1),1)
194	py1(index(2),1) = pfx(2)
195	if(py1(index(2),1).lt.py1min(1)) py1min(1)=py1(index(2),1)
196	if(py1(index(2),1).gt.py1max(1)) py1max(1)=py1(index(2),1)
197	pz1(index(3),1) = pfx(3)
198	if(pz1(index(3),1).lt.pz1min(1)) pz1min(1)=pz1(index(3),1)
199	if(pz1(index(3),1).gt.pz1max(1)) pz1max(1)=pz1(index(3),1)
200
201	b1(index(1),index(2),index(3),1) = fx
202
203
204	c By component
205	px1(index(1),2) = pfy(1)
206	if(px1(index(1),2).lt.px1min(2)) px1min(2)=px1(index(1),2)
207	if(px1(index(1),2).gt.px1max(2)) px1max(2)=px1(index(1),2)
208	py1(index(2),2) = pfy(2)
209	if(py1(index(2),2).lt.py1min(2)) py1min(2)=py1(index(2),2)
210	if(py1(index(2),2).gt.py1max(2)) py1max(2)=py1(index(2),2)
211	pz1(index(3),2) = pfy(3)
212	if(pz1(index(3),2).lt.pz1min(2)) pz1min(2)=pz1(index(3),2)
213	if(pz1(index(3),2).gt.pz1max(2)) pz1max(2)=pz1(index(3),2)
214
215	b1(index(1),index(2),index(3),2) = fy
216
217
218	c Bz component
219	px1(index(1),3) = pfz(1)
220	if(px1(index(1),3).lt.px1min(3)) px1min(3)=px1(index(1),3)
221	if(px1(index(1),3).gt.px1max(3)) px1max(3)=px1(index(1),3)
222	py1(index(2),3) = pfz(2)
223	if(py1(index(2),3).lt.py1min(3)) py1min(3)=py1(index(2),3)
224	if(py1(index(2),3).gt.py1max(3)) py1max(3)=py1(index(2),3)
225	pz1(index(3),3) = pfz(3)
226	if(pz1(index(3),3).lt.pz1min(3)) pz1min(3)=pz1(index(3),3)
227	if(pz1(index(3),3).gt.pz1max(3)) pz1max(3)=pz1(index(3),3)
228
229	b1(index(1),index(2),index(3),3) = fz
230
231	enddo
232
233	c------------------------------------------------------------------------
234	c
235	c closes files
236	c
237	c------------------------------------------------------------------------
238
239	call HREND('Bmap')
240	close(lun_Bmap_file)
241	c$$$ cmd2='rm -f '
242	c$$$ $ //Bmap_file(1:LNBLNK(Bmap_file))
243	c$$$ call system(cmd2)
244	c$$$
245
246
247	c------------------------------------------------------------------------
248	c
249	c * SECOND MAP *
250	c
251	c------------------------------------------------------------------------
252
253	c------------------------------------------------------------------------
254	c
255	c initialization and map file opening
256	c
257	c------------------------------------------------------------------------
258
259	c print*,' '
260	c print*,' '
261
262	Bmap_file='measure_n4_110402_corrected.rz'
263	c opens magnetic field map first file
264	if(b_debug.eq.1)print * !,'Opening file: '
265	$ ,path(1:LNBLNK(path))//Bmap_file
266	call HROPEN
267	$ (lun_Bmap_file,'Bmap'
268	$ ,path(1:LNBLNK(path))//Bmap_file
269	$ ,'P',1024,istat)
270	if(istat.ne.0) goto 21
271
272
273	call HRIN(ntpl_Bmap,9999,0) !puts B map ntuple in memory
274
275	c call HPRNTU(ntpl_Bmap)
276	call HBNAME(ntpl_Bmap,' ',0,'$CLEAR')
277	call HBNAME(ntpl_Bmap,'INDEX',index,'$SET')
278	call HBNAME(ntpl_Bmap,'BX',pfx,'$SET')
279	call HBNAME(ntpl_Bmap,'BY',pfy,'$SET')
280	call HBNAME(ntpl_Bmap,'BZ',pfz,'$SET')
281
282
283	c------------------------------------------------------------------------
284	c
285	c reads events and fills variables
286	c
287	c------------------------------------------------------------------------
288
289	call HNOENT(ntpl_Bmap,iemax) !number of events
290
291	c print*,'iemax ',iemax
292
293	do ic=1,3 !grid edges
294	px2max(ic)=0.
295	px2min(ic)=0.
296	py2max(ic)=0.
297	py2min(ic)=0.
298	pz2max(ic)=0.
299	pz2min(ic)=0.
300	enddo
301
302
303	do iev=1,iemax !event loop
304
305	call HGNT(ntpl_Bmap,iev,ierr) !reads event
306	if(ierr.ne.0) goto 22
307
308	c the output consists of matrices for coordinates, B components values
309	c and errors:
310	c e.g. px(4,2) = X coordinate of the point with index = 4 along X,
311	c in which By (=2) component has been measured
312	c e.g. b(3,23,4,1) = Bx (=1) component value, measured in the point with
313	c indexes = 3,23,4 along X, Y and Z
314
315	c Bx component
316	px2(index(1),1) = pfx(1)
317	if(px2(index(1),1).lt.px2min(1)) px2min(1)=px2(index(1),1)
318	if(px2(index(1),1).gt.px2max(1)) px2max(1)=px2(index(1),1)
319	py2(index(2),1) = pfx(2)
320	if(py2(index(2),1).lt.py2min(1)) py2min(1)=py2(index(2),1)
321	if(py2(index(2),1).gt.py2max(1)) py2max(1)=py2(index(2),1)
322	pz2(index(3),1) = pfx(3)
323	if(pz2(index(3),1).lt.pz2min(1)) pz2min(1)=pz2(index(3),1)
324	if(pz2(index(3),1).gt.pz2max(1)) pz2max(1)=pz2(index(3),1)
325
326	b2(index(1),index(2),index(3),1) = fx
327
328
329	c By component
330	px2(index(1),2) = pfy(1)
331	if(px2(index(1),2).lt.px2min(2)) px2min(2)=px2(index(1),2)
332	if(px2(index(1),2).gt.px2max(2)) px2max(2)=px2(index(1),2)
333	py2(index(2),2) = pfy(2)
334	if(py2(index(2),2).lt.py2min(2)) py2min(2)=py2(index(2),2)
335	if(py2(index(2),2).gt.py2max(2)) py2max(2)=py2(index(2),2)
336	pz2(index(3),2) = pfy(3)
337	if(pz2(index(3),2).lt.pz2min(2)) pz2min(2)=pz2(index(3),2)
338	if(pz2(index(3),2).gt.pz2max(2)) pz2max(2)=pz2(index(3),2)
339
340	b2(index(1),index(2),index(3),2) = fy
341
342
343	c Bz component
344	px2(index(1),3) = pfz(1)
345	if(px2(index(1),3).lt.px2min(3)) px2min(3)=px2(index(1),3)
346	if(px2(index(1),3).gt.px2max(3)) px2max(3)=px2(index(1),3)
347	py2(index(2),3) = pfz(2)
348	if(py2(index(2),3).lt.py2min(3)) py2min(3)=py2(index(2),3)
349	if(py2(index(2),3).gt.py2max(3)) py2max(3)=py2(index(2),3)
350	pz2(index(3),3) = pfz(3)
351	if(pz2(index(3),3).lt.pz2min(3)) pz2min(3)=pz2(index(3),3)
352	if(pz2(index(3),3).gt.pz2max(3)) pz2max(3)=pz2(index(3),3)
353
354	b2(index(1),index(2),index(3),3) = fz
355
356	enddo
357
358	c------------------------------------------------------------------------
359	c
360	c closes files
361	c
362	c------------------------------------------------------------------------
363
364	call HREND('Bmap')
365	close(lun_Bmap_file)
366
367	c------------------------------------------------------------------------
368	c
369	c no error exit
370	c
371	c------------------------------------------------------------------------
372
373	goto 9000 !happy ending
374
375	c------------------------------------------------------------------------
376	c
377	c magnetic field map file opening error
378	c
379	c------------------------------------------------------------------------
380
381	21 continue
382
383	b_error = 1
384	if(b_debug.eq.1)
385	$ print*
386	$ ,'read_B_inner: ERROR OPENING MAGNETIC FIELD MAP FILE: '
387	$ ,Bmap_file
388
389	goto 9000 !the end
390
391
392	c------------------------------------------------------------------------
393	c
394	c ntuple event reading error
395	c
396	c------------------------------------------------------------------------
397
398	22 continue
399
400	b_error = 1
401	if(b_debug.eq.1)
402	$ print*,'read_B_inner: ERROR WHILE READING NTUPLE, at entry
403	$ : ',iev
404
405	goto 9000 !the end
406
407
408	c------------------------------------------------------------------------
409	c
410	c exit
411	c
412	c------------------------------------------------------------------------
413
414	9000 continue
415
416	return
417	end
418	*************************************************************************
419	*
420	* Subroutine readBouter
421	*
422	* it reads from rz files the two magnetic field maps taken inside the
423	* spectrometer cavity and fills the variables in common_B_inner.f
424	*
425	* needs:
426	* - common_B_outer.f common file for the outer magnetic field map
427	* - .rz map files in ./ containing coordinates of measured points, Bx, By
428	* and Bz components + errors
429	*
430	* output variables: (see common_B_outer.f)
431	* - pxo(nx,3)
432	* - pyo(ny,3)
433	* - pzo(nz,3)
434	* - bo(nx,ny,nz,3)
435	*
436	*************************************************************************
437
438	subroutine readBouter(path)
439
440	c implicit double precision (a-h,o-z)
441	include 'common_B.f'
442	include 'common_c2f.f'
443	C
444	character*80 path
445
446	REAL hmemor(10000000)
447	integer Iquest(100)
448	COMMON /pawc/hmemor
449	save /pawc/
450	C
451	Common /QUEST/ Iquest
452	save /quest/
453
454
455
456	c------------------------------------------------------------------------
457	c
458	c local variables
459	c
460	c------------------------------------------------------------------------
461
462	character*64 Bmap_file !magnetic field file name
463	parameter (lun_Bmap_file=66) !magnetic field map file id number
464
465	parameter (ntpl_Bmap=20) !ntuple identifier
466
467	REAL PFX(3),FX,DFX, !Bx field component coordinates in m, value and error in T
468	$ PFY(3),FY,DFY
469	$ ,PFZ(3),FZ,DFZ
470	INTEGER INDEX(3) !point index
471
472	COMMON /PAWCR4/ INDEX,PFX,FX,DFX,PFY,FY,DFY,PFZ,FZ,DFZ
473
474
475	c print*,'Calling HLIMIT'
476	CALL HLIMIT(10000000)
477	C - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - -
478	C largest RZ file: IQUEST(10) records x LREC words x 4 byte
479	C with the following settings: 65000 x 4096 x 4 = 1G
480	C - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - -
481
482	c permette di ottenere ntuple funzionanti nonostante
483	c il messaggio dei 64K di RZOUT
484	Iquest(10) = 512000
485	c------------------------------------------------------------------------
486	c
487	c * FIRST MAP *
488	c
489	c------------------------------------------------------------------------
490
491	c------------------------------------------------------------------------
492	c
493	c initialization and map file opening
494	c
495	c------------------------------------------------------------------------
496
497	c print*,' '
498	c print*,' '
499
500	Bmap_file='External_top_map_n4_150402.rz'
501
502	c opens magnetic field map first file
503	if(b_debug.eq.1)print *
504	$ ,path(1:LNBLNK(path))//Bmap_file
505	call HROPEN
506	$ (lun_Bmap_file,'Bmap'
507	$ ,path(1:LNBLNK(path))//Bmap_file
508	$ ,'P',1024,istat)
509	if(istat.ne.0) goto 21
510
511
512	call HRIN(ntpl_Bmap,9999,0) !puts B map ntuple in memory
513
514	c call HPRNTU(ntpl_Bmap)
515	call HBNAME(ntpl_Bmap,' ',0,'$CLEAR')
516	call HBNAME(ntpl_Bmap,'INDEX',index,'$SET')
517	call HBNAME(ntpl_Bmap,'BX',pfx,'$SET')
518	call HBNAME(ntpl_Bmap,'BY',pfy,'$SET')
519	call HBNAME(ntpl_Bmap,'BZ',pfz,'$SET')
520
521
522	c------------------------------------------------------------------------
523	c
524	c reads events and fills variables
525	c
526	c------------------------------------------------------------------------
527
528	call HNOENT(ntpl_Bmap,iemax) !number of events
529
530	c initializes measurement grid edges
531	do ic=1,3
532	poxmax(ic)=0.
533	poxmin(ic)=0.
534	poymax(ic)=0.
535	poymin(ic)=0.
536	pozmax(ic)=0.
537	pozmin(ic)=0.
538	enddo
539
540
541	do iev=1,iemax !event loop
542
543	call HGNT(ntpl_Bmap,iev,ierr) !reads event
544	if(ierr.ne.0) goto 22
545
546	c the output consists of matrices for coordinates, B components values
547	c and errors:
548	c e.g. px1(4,2) = X coordinate of the point with index = 4 along X,
549	c in which By (=2) component has been measured
550	c e.g. b1(3,23,4,1) = Bx (=1) component value, measured in the point with
551	c indexes = 3,23,4 along X, Y and Z
552
553	c Bx component
554	pox(index(1),1) = pfx(1)
555	if(pox(index(1),1).lt.poxmin(1)) poxmin(1)=pox(index(1),1)
556	if(pox(index(1),1).gt.poxmax(1)) poxmax(1)=pox(index(1),1)
557	poy(index(2),1) = pfx(2)
558	if(poy(index(2),1).lt.poymin(1)) poymin(1)=poy(index(2),1)
559	if(poy(index(2),1).gt.poymax(1)) poymax(1)=poy(index(2),1)
560	poz(index(3),1) = pfx(3)
561	if(poz(index(3),1).lt.pozmin(1)) pozmin(1)=poz(index(3),1)
562	if(poz(index(3),1).gt.pozmax(1)) pozmax(1)=poz(index(3),1)
563
564	bo(index(1),index(2),index(3),1) = fx
565
566
567	c By component
568	pox(index(1),2) = pfy(1)
569	if(pox(index(1),2).lt.poxmin(2)) poxmin(2)=pox(index(1),2)
570	if(pox(index(1),2).gt.poxmax(2)) poxmax(2)=pox(index(1),2)
571	poy(index(2),2) = pfy(2)
572	if(poy(index(2),2).lt.poymin(2)) poymin(2)=poy(index(2),2)
573	if(poy(index(2),2).gt.poymax(2)) poymax(2)=poy(index(2),2)
574	poz(index(3),2) = pfy(3)
575	if(poz(index(3),2).lt.pozmin(2)) pozmin(2)=poz(index(3),2)
576	if(poz(index(3),2).gt.pozmax(2)) pozmax(2)=poz(index(3),2)
577
578	bo(index(1),index(2),index(3),2) = fy
579
580
581	c Bz component
582	pox(index(1),3) = pfz(1)
583	if(pox(index(1),3).lt.poxmin(3)) poxmin(3)=pox(index(1),3)
584	if(pox(index(1),3).gt.poxmax(3)) poxmax(3)=pox(index(1),3)
585	poy(index(2),3) = pfz(2)
586	if(poy(index(2),3).lt.poymin(3)) poymin(3)=poy(index(2),3)
587	if(poy(index(2),3).gt.poymax(3)) poymax(3)=poy(index(2),3)
588	poz(index(3),3) = pfz(3)
589	if(poz(index(3),3).lt.pozmin(3)) pozmin(3)=poz(index(3),3)
590	if(poz(index(3),3).gt.pozmax(3)) pozmax(3)=poz(index(3),3)
591
592	bo(index(1),index(2),index(3),3) = fz
593
594	enddo
595
596
597	c------------------------------------------------------------------------
598	c
599	c closes files
600	c
601	c------------------------------------------------------------------------
602
603	call HREND('Bmap')
604	close(lun_Bmap_file)
605
606
607	c------------------------------------------------------------------------
608	c
609	c no error exit
610	c
611	c------------------------------------------------------------------------
612
613	goto 9000 !happy ending
614
615	c------------------------------------------------------------------------
616	c
617	c magnetic field map file opening error
618	c
619	c------------------------------------------------------------------------
620
621	21 continue
622
623	b_error = 1
624	if(b_debug.eq.1)
625	$ print*
626	$ ,'read_B_inner: ERROR OPENING MAGNETIC FIELD MAP FILE: '
627	$ ,Bmap_file
628
629	goto 9000 !the end
630
631
632	c------------------------------------------------------------------------
633	c
634	c ntuple event reading error
635	c
636	c------------------------------------------------------------------------
637
638	22 continue
639
640	b_error = 1
641	if(b_debug.eq.1)
642	$ print*
643	$ ,'read_B_inner: ERROR WHILE READING NTUPLE, at event
644	$ : ',iev
645
646	goto 9000 !the end
647
648
649	c------------------------------------------------------------------------
650	c
651	c exit
652	c
653	c------------------------------------------------------------------------
654
655	9000 continue
656
657	return
658	end
659