Setting up (BSD 4.0) the Fourth Berkeley Software Tape

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This pertains to 4.0 BSD.

       Setting up the Fourth Berkeley Software Tape*
                Draft of: November 15, 1980


                       William N. Joy
                       Ozalp Babaoglu
                       Keith Sklower

                 Computer Science Division
 Department of Electrical Engineering and Computer Science
             University of California, Berkeley
                Berkeley, California  94720





     The basic distribution tape can be used only on  a  DEC
VAX-11/780**  with  RM03,  RM05 or RP06 disks and with TE16,
TU45 or TU77 tape drives.  We have the ability to make tapes
for  systems  with  UNIBUS**  disks,  but  such  tapes   are
inherently rather system-specific, and will not be discussed
here.  The tape consists of some  preliminary  bootstrapping
programs followed by one dump of a filesystem (see  dump(8))
and  one tape archive image (see tar(1)); if needed, indivi-
dual files can be extracted after the  initial  construction
of the filesystems.

     If you are set up to do it, it is a good  idea  immedi-
ately  to make a copy of the tape to guard against disaster.
The tape is 9-track 1600  BPI  and  contains  some  512-byte
records  followed  by  many  10240-byte  records.  There are
interspersed tapemarks; end-of-tape is signalled by a double
end-of-file.

     The tape contains binary images of the system  and  all
the  user  level programs, along with source and manual sec-
tions for them.  There are about 5600 UNIX files altogether.
The  first  tape  file contains bootstrapping programs.  The
second tape file is to be put on one filesystem  called  the
`root  filesystem',  and  contains  essential  binaries  and
__________________________
*Portions of this document are adapted  from  ``Setting
Up  Unix/32V Version 1.0'' by Thomas B. London and John
F. Reiser.
** DEC, VAX, UNIBUS and MASSBUS are trademarks of Digi-
tal Equipment Corporation.
 UNIX is a Trademark of Bell Laboratories.
References of the form X(Y) mean the subsection named X
in section Y of the UNIX programmer's manual.




                      November 15, 1980





                           - 2 -


enough other files to allow the system to  run.   The  third
tape  file  has  all of the source and documentation.  Alto-
gether the files provided on the tape  occupy  approximately
52000 512 byte blocks.

Making a disk from tape

     Before you begin to work on the remainder of this docu-
ment,  be  sure  you have an up to date manual, and that you
have applied all updates to the manual which  were  provided
with it, in the correct order.

     Perform the following bootstrap procedure to  obtain  a
disk with a root filesystem on it.

1.   Mount the magtape on drive 0 at load point, making sure
     that the ring is not inserted.

2.   Mount a disk pack on drive 0.  It  is  preferable  that
     the  pack  be  formatted  (e.g.  using the standard DEC
     standalone utility); we provide programs for formatting
     RM03's  and  RP06's  below,  but  RM05's  must  be pre-
     formatted by the DEC utility.

3.   Key in at location 50000 and execute the following boot
     program:  You  may enter in lower-case, the LSI-11 will
     echo in upper-case.  The machine's printouts are  shown
     in boldface, explanatory comments are within ( ).  Ter-
     minate each line you type by carriage return  or  line-
     feed.







__________________________
UNIX traditionally talks  in  terms  of  512  character
blocks,  and  for consistency across different versions
of UNIX and to avoid mass confusion, user  programs  in
the  Virtual  Vax  version  of  the system also talk in
terms of 512 blocks, despite the  fact  that  the  file
system  allocates  1024 byte blocks of disk space.  All
user progras such as ls(1) and du(1) speak in terms  of
512  byte blocks; only system maintenance programs such
as mkfs(8), fsck(8) dump(8), and df(1), speak  to  1024
byte  blocks.  It is true that i/o is most efficient in
1024 byte quantities, but it is most  natural  for  the
user to think of this as ``2 blocks at a time.'' In any
case, packs remain sectored 512 bytes per  sector,  and
at  the  lowest driver levels the system deals with 512
byte disk records.




                      November 15, 1980





                           - 3 -


        >>>HALT
        >>>UNJAM
        >>>INIT
        >>>D 50000 20009FDE
        >>>D+  D0512001
        >>>D+  3204A101
        >>>D+  C114C08F
        >>>D+  A1D40424
        >>>D+  008FD00C
        >>>D+  C1800000
        >>>D+  8F320800
        >>>D+  10A1FE00
        >>>D+  00C139D0
        >>>D+  00000004
        >>>E 50000/NE:A
        ...                             (machine prints out values, check typing
)
        >>>START 50000


     The tape should move and the CPU should halt  at  loca-
     tion  5002A.   If it doesn't, you probably have entered
     the program incorrectly.  Start  over  and  check  your
     typing.

4.   Start the CPU with

             >>>START 0


5.   The console should type

             =

     If you have an RM-05 you must already have a  formatted
     pack,  and  should skip to step 7.  If the disk pack is
     otherwise already formatted, skip to  step  6.   Other-
     wise, format the pack with:

             (bring in standalone RP06 formatter)
             =rp6fmt
             format : Format RP06/RM03 Disk

             MBA no. : 0             (format spindle on mba # 0)
             unit : 0                (format unit zero)
             (this procedure should take about 20 minutes for an RP06, 10 for an
 RM03)
             (some diagnostic messages may appear here)

             unit : -1               (exit from formatter)
             =                       (back at tape boot level)


6.   Next, verify the readability of the pack via





                      November 15, 1980





                           - 4 -


             (bring in RP06 verifier)
             =rpread
             dread : Read RP06/RM03 Disk

             disk unit : 0                   (specify unit zero)
             start block : 0         (start at block zero)
             no. blocks :                    (default is entire pack)

             (this procedure should take about 10 minutes for a RP06)
             (some diagnostic messages may appear here)
             # Data Check errors : nn        (number of soft errors)
             # Other errors : xx             (number of hard errors)
             disk unit: -1                   (exit from rpread)
             =                               (back to tape boot)

     If the number of `Other errors' is not zero, considera-
     tion  should  be given to obtaining a clean pack before
     proceeding further.

7.   Create the root file system  with  the  following  pro-
     cedure:

             (bring in a standalone version of the mkfs (8) program)
             =mkfs
             file sys size: 7942             (number of 1024 byte blocks in root
)
             file system: hp(0,0)            (root is on drive zero; first filsy
s there)
             isize = 5072                    (number of inodes in root filesyste
m)
             m/n = 3 500                     (interleave parameters)
             =                               (back at tape boot level)

     You now have a empty UNIX root filesystem.  To  restore
     the data which you need to boot the system, type

             (bring in a standalone restor(8) program)
             =restor
             Tape? ht(0,1)                   (unit 0, second tape file)
             Disk? hp(0,0)                   (into root file system)
             Last chance before scribbling on disk.          (just hit return)
             (30 second pause then tape should move)
             (tape moves for a few minutes)
             End of tape
             =                               (back at tape boot level)

     Now, you are ready to boot up UNIX.

Booting UNIX

     Now boot UNIX:

        (load bootstrap program)
        =boot
        Boot
        : hp(0,0)vmunix                 (bring in vmunix off root system)




                      November 15, 1980





                           - 5 -


The bootstrap should then print out the sizes  of  the  dif-
ferent parts of the system (text, initialized and uninitial-
ized data) and then the system should start with  a  message
which looks (like):

        87844+15464+130300 start 0x530
        VM/UNIX (Berkeley Version 4.1) 11/10/80
        real mem  = xxx
        avail mem = yyy
        WARNING: preposterous time in file system -- CHECK AND RESET THE DATE!
        ERASE IS CONTROL-H!!!
        #

The mem messages give the amount of real  (physical)  memory
and  the  memory  available  to user programs in bytes.  For
example, if your machine has only 512K bytes of memory, then
xxx  will  be  524228,  i.e. exactly 512K.  The ``ERASE-IS''
message is part of /.profile which was executed by the  root
shell  when  it  started.   You will probably want to change
/.profile somewhat.

     UNIX is now running, and the `UNIX Programmer's manual'
applies.   The  `#'  is the prompt from the Shell, and indi-
cates you are the super-user.  You should  first  check  the
integrity of the root file system by giving the command

        # fsck /dev/rrp0a

The output from fsck should look something like:

        /dev/rrp0a
        File System:  Volume:

        ** Checking /dev/rrp0a
        ** Phase 1 - Check Blocks and Sizes
        ** Phase 2 - Check Pathnames
        ** Phase 3 - Check Connectivity
        ** Phase 4 - Check Reference Counts
        ** Phase 5 - Check Free List
        282 files 1766 blocks 5677 free


     If there are inconsistencies in the  file  system,  you
may  be  prompted  as to whether to apply corrective action;
see the document describing fsck for information.

Extracting /usr.

     The next thing to do is to extract the rest of the data
from  the  tape.   Comments  are enclosed in ( ); don't type
these.  The number in the first command is the size  of  the
filesystem  to be created, in 1024 character blocks, just as
given to the standalone version of mkfs above.  (If you have
an  RM-03 rather than an RM-05 or RP-06 use ``41040'' rather



                      November 15, 1980





                           - 6 -


than ``145673'' in the procedure below.)

        #date yymmddhhmm                (set date, see date(1))
        #passwd root                            (set password for super-user)
        New password:                   (password will not echo)
        Retype new password:
        #/etc/mkfs /dev/rrp0g 145673    (create empty user filesystem)
        isize = 65488                           (this is the number of available
 inodes)
        m/n = 3 500                             (freelist interleave parameters)

        (this takes a few minutes)
        #/etc/mount /dev/rp0g /usr      (mount the usr filesystem)
        #cd /usr                                (make /usr the current directory
)
        #cp /dev/rmt12 /dev/null                (skip first tape file (tp format
))
        #cp /dev/rmt12 /dev/null                (skip second tape file (root))
        #tar xpb 20                             (extract the usr filesystem)
        (this takes about 20 minutes)
        #rmdir lost+found
        #/etc/mklost+found              (a directory for fsck)
        #dd if=/usr/mdec/uboot of=/dev/rrp0a bs=1b count=1
        (write boot block so reboot(8) disk boot scheme will work)
        #cd /                                   (back to root)
        #chmod 755  /  /usr
        #/etc/umount /dev/rp0g          (unmount /usr)

All of the data on the tape has  now  been  extracted.   The
tape will rewind automatically.

     You should now check the consistency of the  /usr  file
system by doing

        # fsck /dev/rrp0g

In order to use the /usr file system, you should now remount
it by saying

        # /etc/mount /dev/rp0g /usr


Making a UNIX boot floppy

     The next thing to do is to make a new UNIX boot floppy,
by  adding  some  files  to  a  copy of your current console
floppy, using flcopy and arff(8).

     Place your current floppy in the console, and issue the
following commands:











                      November 15, 1980





                           - 7 -


        # cd /usr/src/sys/floppy
        # mkdir fromdec                 (scratch sub-directory)
        # cd fromdec
        # arff xv                               (extract all files from floppy)
        (list of files prints out)
        # flcopy -t3
        (system reads header information off current floppy)
        Change Floppy, Hit return when done.
        (waits for you to put clean floppy in console)
        (copies header information back out after you hit return)
        # rm floppy                             (don't need copy of old header i
nformation)
        # rm dm* db* vmb.exe            (don't need these files with UNIX)
        # arff cr *                             (add basic files)
        Are you sure you want to clobber the floppy?
        yes                                     (clobbering is, essentially, a m
kfs)
        # cd ..
        # rm -r fromdec                 (remove scratch directory)
        # arff r *                              (add UNIX boot files to floppy)

More copies of this floppy can be made using flcopy.

     You should now be able to reboot using  the  procedures
in  reboot(8).   First  you  should  turn on the auto-reboot
switch on the machine.  Then try a reboot, saying

        # /etc/reboot -s

which you can read about in reboot(8).

Taking the system up and down

     Normally the system reboots itself and no  intervention
is  needed  at the console command level (e.g. to the LSI-11
``>>>'' prompt.) In fact, after such a  reboot,  the  system
normally performs a reboot checking the disks, and then goes
back to multi-user mode.   Such  a  reboot  can  be  stopped
(after it prints the date) with a delete (interrupt).

     If booting from the console command  level  is  needed,
then the command

        >>> B RPS

will boot from unit 0 on mba  0  (RM-03,  RM-05  or  RP-06),
bringing in the file ``hp(0,0)vmunix''.  Other possibilities
are ``B RPM'' which boots and runs the automatic reboot pro-
cedure or ``B ANY'' which boots and asks for the name of the
__________________________
If you are going to make your root device be  something
other  than a MASSBUS disk, you will have to change the
file RESTAR.CMD on the floppy, to pass the block device
index of the major device to be booted from to the sys-
tem in a register after, e.g., a power-fail.




                      November 15, 1980





                           - 8 -


file to be booted.  Note that ``B''  with  no  arguments  is
used internally by the reboot code, and shouldn't be used.

     To bring the system up to  a  multi-user  configuration
from the single-user status after, e.g., a ``B RPS'' all you
have to do is hit control-d on the console.  The system will
then  perform /etc/rc, a multi-user restart script, and come
up on the terminals which are indicated in  /etc/ttys.   See
init(8)  and  ttys(5).   Note,  however,  that this does not
cause a file system check to be performed.  Unless the  sys-
tem  was  taken  down cleanly, you should run ``fsck -p'' or
force a reboot with reboot(8) to have the disks checked.

     To take the system down to a single user state you  can
use

        # kill 1

when you are up multi-user.  This will  kill  all  processes
and  give  you  a  shell  on the console, as if you had just
booted.

     If you wish to change  the  terminal  lines  which  are
active  you  can edit the file /etc/ttys, changing the first
characters of lines, and then do

        # kill -1 1

See init(8) and getty(8) for more information.

Backing up the system

     Before you change the source for the kernel it is  wise
to make a backup.  The following will do this:
        # cd /usr/src
        # mkdir distsys distsys/h distsys/sys distsys/dev distsys/conf distsys/s
tand
        # cd sys/sys
        # cp * /usr/src/distsys/sys
        # cd ../h
        # cp * /usr/src/distsys/h
        # cd ../dev
        # cp * /usr/src/distsys/dev
        # cd ../conf
        # cp * /usr/src/distsys/conf
        # cd ../stand
        # cp * /usr/src/distsys/stand

This allows you to find out what you have done to  the  dis-
tribution  system by later running the command diff(1), com-
paring these directories.







                      November 15, 1980





                           - 9 -


Organization

     The system source is  kept  in  the  subdirectories  of
/usr/src/sys.   The directory sys contains the mainline ker-
nel code, implementing system calls, the file  system,  vir-
tual memory, etc.  The directory dev contains device drivers
and other low-level routines.  The directory  conf  contains
CPU-dependent  information  on  physical  and logical device
configuration.  The directory  h  contains  all  the  header
files,  defining structures and system constants.  N.B.: The
system header files in  /usr/src/sys/h  are  copies  of  the
files  in  /usr/include/sys.  Since programs which depend on
constants in /usr/include/sys/param.h must correspond to the
running  system,  you  should  be careful to make new header
files available whenever you resize the system or  otherwise
change the header files.

     You should expect to have to make some changes  to  the
conf  directory  and  perhaps to some of the header files in
the h directory to resize some things.

     The conf, sys and dev directories each have  their  own
makefile controlling recompilation.  The sys makefile is the
master makefile; new versions of the kernel are  created  as
``vmunix''  in  the  sys  directory.  If changes are made in
other directories, then the following commands:

        # cd ../sys
        # rm vmunix
        # make

will cause all needed recompilations  to  be  done.   It  is
often  convenient when making changes in dev or conf to just
run make there first.

     Finally note that the directory stand which is not part
of  the  system  proper.  If you add new peripherals such as
tapes or disks you will want to extend the standalone system
to be able to deal with these.  It too, has a makefile which
you can look at.

Isolating local changes conditionally

     You will notice that the system,  as  distributed,  has
conditional  code  in  it.   The current Berkeley system, on
``Ernie Co-vax'' is made by defining IDENT in the  makefiles
to be

        IDENT= -DERNIE -DUCB

This enables the conditional code both for Berkeley and  for
this  particular  machine.  It is traditional to pick a mon-
icker for your machine, and change IDENT to reflect it,  and
to  then  put  in  changes conditionally whenever this makes



                      November 15, 1980





                           - 10 -


sense.  You can be guided by  the  ERNIE  conditional  code,
which you will probably want to disable.

Device drivers

     The UNIX system running is configured to run  with  the
given  disk  and  tape,  a  console,  32 DZ11 lines, 32 DH11
lines, a Varian printer/plotter, a Versatec printer/plotter,
and  2  AMPEX  9300  disks  on  an  EMULEX controller on the
UNIBUS.  This is probably not the correct configuration.  It
is  easy to correct the configuration information to reflect
the true state of your  machine.   For  each  device  driver
there  there  are  certain  magic  numbers and configuration
parameters kept in header files (suffixed .h)  in  the  conf
directory that you can change.  The device addresses of each
device are defined there, as are other  specifications  such
as  the  number of devices.  You should edit each .h file in
conf change them as appropriate for your machine.

     If you have any  non-standard  device  addresses,  just
change  the  address and recompile.  If the devices's inter-
rupt vector address(es) are different from  those  currently
known  to  the  system  (this  is  likely),  then  the  file
/usr/src/sys/conf/univec.c must be  modified  appropriately:
namely,  the  proper  interrupt  routine  addresses  must be
placed in the table `UNIvec'.  Now, make sure  you  add  any
new  drivers  which  you  have to the list of DRIVERS in the
makefile in dev, and to the FILES and  CFILES  variables  in
this makefile and FILES3 and CFILES3 in ../sys/makefile.

     As describe in ``Basics of  disk  layout''  below,  the
first line of the makefile in the sys directory controls the
root device and swap disk  layout  by  picking  one  of  the
confhp.c,  confup.c, etc. files of the conf directory.  This
should be chosed to reflect the desired disk  layout  before
the system is recompiled.

Non-integrated device drivers

     As of this date,  several  device  drivers  which  were
available at various times have not been integrated into the
conditional compilation of the  dev  and  conf  directories.
The  source  for  these  device  drivers is in the directory
/usr/src/sys/newdev.  These device drivers will be made part
of  /usr/src/sys/dev and /usr/src/sys/conf as we have oppor-
tunity to test them.  It should  not  be  hard  for  you  to
integrate  these drivers; if you wish, you can contact us as
we will be able to supply  integrated  versions  very  soon.
Here  is  a list of the drivers which are currently awaiting
integration:







                      November 15, 1980





                           - 11 -


        dhdm    DM11 modem control driver
        kl      KL/DL-11 communications driver
        lp      LP11 line printer driver
        rk7     RK07 driver
        tm      TM11 unibus tape driver

In addition, there is another rk07 driver (hk.c).   Code  to
allow  mixing  of  tapes  and disks among and across several
MBA's is also in the works, but  is  not  supplied  on  this
tape.  Contact us if you have need for this code.

     If you integrate these or other drivers we would appre-
ciate  receiving  a  copy  in  the mail so that we can avoid
duplication of effort.  (Other comments  on  the  system  or
these instructions are, of course, also welcomed.)

Makefile entry points

     The makefiles  have  several  additional  useful  entry
points:

clean          Cleans out the directory, removing  .o  files
               and the like.

lint           (In sys) Runs lint on the system.

depend         Creates a new makefile  indicating  dependen-
               cies  on  header  files  by  running a search
               through .c  files  looking  for  ``#include''
               lines.   Make  sure you format your code like
               the rest of the  system  so  that  this  will
               work.

print          (In sys) Produces  a  nice  listing  of  most
               everything  in  the  system  directory  in  a
               canonical order.

symbols.sort   (In sys) Creates a new file for sorting  sym-
               bols  in  the  system  namelist.  If you have
               locally written programs which use the system
               namelist  you  can put the symbols which they
               reference in symbols.raw  and  they  will  be
               moved  at  system  generation to the front of
               the system namelist for quicker access.

tags           Creates a tags file for ex, to  make  editing
               of the system much easier.

Basic constants

     Before running make, you should check the definition of
the  constants in /usr/src/sys/h/param.h The constants NBUF,
NINODE, NFILE, NPROC, and NTEXT can  be  changed,  and  also
TIMEZONE and perhaps HZ if you run on 50 cycles.  There  are
__________________________
 If you change NINODE, NFILE, NPROC or NTEXT, then  the

                      November 15, 1980





                           - 12 -


also tunable constants in the  file  /usr/src/sys/h/vmtune.h
but  ignore  them  for  the time being.  As distributed, the
system is tuned for a fairly large machine  (i.e.  2+  Mega-
bytes of memory and 2-3 disk arms).

     To generate a completely recompiled UNIX do

        # cd /usr/src/sys/sys
        # make clean ; cd ../dev ; make clean ; cd ../conf ; make clean
        # cd ../sys
        # make depend ; cd ../dev ; make depend ; cd ../conf ; make depend
        # cd ../sys
        # make -k > ERRS 2>& 1 &
        (compilation will finish about 15 minutes later leaving output in ERRS)


     The final object file (vmunix) should be moved  to  the
root,  and then booted to try it out.  It is best to name it
/newvmunix so as not to destroy  the  working  system  until
you're  sure  it  does work.  It is also a good idea to keep
the old working version around under  some  other  name.   A
systematic  scheme  for numbering and saving old versions of
the system is best.  Be sure to always have the current sys-
tem  in  /vmunix when you are running multi-user or commands
such as ps(1) and w(1) will not work.

Special Files

     Next you should remove any unnecessary  device  entries
from  the  directory  /dev, as devices were provided for all
the things initially configured into the  system.   See  how
the  devices were made using MAKE in the directory /dev, and
make another directory /newdev, copy MAKE into it, edit MAKE
to  provide  an  entry for local needs, and rerun it to gen-
erate a /newdev directory.  You can then do

        # cd /
        # mv dev olddev ; mv newdev dev

If you prefer, you can just whittle away at /dev  using  rm,
mv  and  mknod(8)  to make what you need, but if you do this
stuff manually you may have to do it manually again someday,
and the devices will appear much more ``magic'' to those who
follow you.

Notes on the configuration file and device names

     Print the configuration file  /usr/src/sys/conf/conf.c.
This  is the major device switch of each device class (block
__________________________
programs analyze(1), ps(1), pstat(1) and w(1) will have
to be recompiled.  A procedure for doing this is  given
below.




                      November 15, 1980





                           - 13 -


and character).  There is one line for each  device  config-
ured  in  your  system and a null line for place holding for
those devices not configured.  The essential  block  special
files  were  installed above; for any new devices, the major
device number is selected by counting the line number  (from
zero)  of  the  device's  entry  in  the block configuration
table.  Thus the first entry in the table  bdevsw  would  be
major device zero.  This number is also printed in the table
along the right margin.

     The minor device is the drive number,  unit  number  or
partition  as described under each device in section 4.  For
tapes where the unit is dial selectable, a special file  may
be  made  for  each  possible  selection.   You can also add
entries for other devices.

     Each device is typically given several special files in
/dev.   The name is made from the name of the device driver,
sometimes varying for historical reasons.  Thus  the  ``up''
disk  driver  has disks ``up0a'', ``up0b'', etc., the parti-
tions of drive 0 being given letters a-h.

     The tape drives are given names not  dependent  on  the
tape  driver  hardware,  since  they  are used directly by a
number of programs.  The file mt0 is  a  1024  byte  blocked
tape  drive at 800 bpi; mt8 is 1600 bpi.  By adding 4 to the
unit number you get non-rewinding tapes.

     The disk and magtape drivers provide a `raw'  interface
to the device which provides direct transmission between the
user's core and the device and  allows  reading  or  writing
large records.  The raw device counts as a character device,
and conventionally has the name of the  corresponding  stan-
dard  block  special  file with `r' prepended.  Thus the raw
magtape files are called /dev/rmtX.

     The names for  terminals  should  be  named  /dev/ttyX,
where  X  is  some  string (as in `0' or `d0').  While it is
possible to use truly arbitrary strings here, the accounting
and  noticeably  the ps(1) command make good use of the fact
that tty names (at Berkeley) are  distinct  in  the  last  2
characters.   In  fact,  we  use  the  following convention:
``ttyN'', with N the  minor  device  number  for  normal  DZ
ports; ``ttydX'' with X a single hex digit (starting from 0)
for dialups, ``ttyhX'' and ``ttyiX'' with X a hex digit  for
dh  ports,  and ``console'' (abbrev ``co'') for the console.
This works out well and ps(1)  uses  a  heuristic  algorithm
based  on  these  conventions to speed up name determination
from device numbers it otherwise obtains.

     Whenever special files  are  created,  care  should  be
taken  to  change the access modes (chmod(8)) on these files
to appropriate values.




                      November 15, 1980





                           - 14 -


Basics of Disk Layout

     If there are to be more filesystems mounted  than  just
the root and /usr, use mkfs(8) and mklost+found(8) to create
any new filesystem and put the information about it into the
file  /etc/fstab  (see  fstab(5)).   You should look also at
/etc/rc to see what commands are executed there and investi-
gate how fstab is used.

     Each physical disk drive can be  divided  into  upto  8
partitions; we typically use only 3 partitions (or 4 on 300M
drives).  The first partition, e.g.  rp0a is used for a root
file  system,  a backup thereof, or a small file system like
/tmp.  The second partition rp0b  is  used  for  paging  and
swapping.   The  third partition rp0g is used to hold a user
file system.  We partition our 300M disks so that almost all
of a large disk will fit onto a 200M disk, just dropping the
last partition.  This makes it easier to deal with  hardware
failures by just copying data.

     There are several considerations  in  deciding  how  to
adjust  the  arrangement  of  things on your disks: the most
important is making sure there is adequate space for what is
required; secondarily, throughput should be maximized.  Pag-
ing space is an important parameter.  The system as  distri-
buted  has  33440  (512 byte) blocks in which to page on the
primary device; additional devices may be provided, with the
paging  interleaved  between  them.   This  is controlled by
entries in /etc/fstab and in a  configuration  file  in  the
conf directory.

     The first line of the makefile  in  the  sys  directory
selects  one  a file such as confrp.c in the conf directory.
This file specifies the root and pipe devices and  the  dev-
ices  which  are  to  be used for swapping and paging.  Each
device which is to be used for paging  (except  the  primary
one) should be specified as a ``sw'' device in fstab.

     Many common system programs (C, the editor, the  assem-
bler  etc.) create intermediate files in the /tmp directory,
so the filesystem where this is stored also should  be  made
large  enough  to  accommodate most high-water marks; if you
have several disks, it makes sense to mount this in  one  of
the other ``root'' (i.e. first partition) file systems.  The
root filesystem as distributed is  quite  large,  and  there
should be no problem.  All the programs that create files in
/tmp take care to delete them, but most are  not  immune  to
events  like  being  hung up upon, and can leave dregs.  The
directory should be examined every  so  often  and  the  old
files deleted.

     Exhaustion of user-file space is certain to  occur  now
and   then;   the   only  mechanisms  for  controlling  this
phenomenon are occasional  use  of  du(1),  df(1),  quot(8),



                      November 15, 1980





                           - 15 -


threatening messages of the day, and personal letters.

     The efficiency with which UNIX is able to use  the  CPU
is often strongly affected by the configuration of disk con-
trollers.  For general time-sharing applications,  the  best
strategy  is to try to split the root filesystem (/), system
binaries (/usr), the temporary files (/tmp),  and  the  user
files  among several disk arms, and to interleave the paging
activity among a number of arms.  We will discuss such  con-
siderations more below.

Moving filesystem data

     Once you have decided how to  make  best  use  of  your
hardware, the question is how to initialize it.  If you have
the equipment, the best way to move a filesystem is to  dump
it   to   magtape   using   dump(8),   to  use  mkfs(8)  and
mklost+found(8) to create the new  filesystem,  and  restore
(restor(8))  the tape.  If for some reason you don't want to
use magtape, dump accepts an argument telling where  to  put
the  dump; you might use another disk.  Sometimes a filesys-
tem has to be increased in  logical  size  without  copying.
The  super-block of the device has a word giving the highest
address  which  can  be  allocated.   For  relatively  small
increases,  this  word  can  be  patched  using the debugger
(adb(1)) and the free list reconstructed using fsck(8).  The
size should not be increased very greatly by this technique,
however, since although the allocatable space will  increase
the  maximum  number  of files will not (that is, the i-list
size can't be changed).  Read and understand the description
given in filsys(5) before playing around in this way.

     If you have to merge a filesystem into another,  exist-
ing  one, the best bet is to use tar(1).  If you must shrink
a filesystem, the best bet is to dump the original and  res-
tor it onto the new filesystem.  However, this will not work
if the i-list on the smaller filesystem is smaller than  the
maximum allocated inode on the larger.  If this is the case,
reconstruct the filesystem from scratch on another  filesys-
tem  (perhaps  using  tar(1))  and then dump it.  If you are
playing with the root filesystem and only have one drive the
procedure  is  more complicated.  What you do is the follow-
ing:

1.   GET A SECOND PACK!!!!

2.   Dump the root filesystem to tape using dump(8).

3.   Bring the system down and mount the new pack.

4.   Load the standalone versions of mkfs(8)  and  restor(8)
     from the floppy with a procedure like:





                      November 15, 1980





                           - 16 -


             >>>UNJAM
             >>>INIT
             >>>LOAD MKFS
                  LOAD DONE, xxxx BYTES LOADED
             >>>ST 2

             ...

             >>>H
                  HALTED AT yyyy
             >>>U
             >>>I
             >>>LOAD RESTOR
                  LOAD DONE, zzzz BYTES LOADED

             ... etc


5.   Boot normally using the newly created disk filesystem.

     Note that if you change the disk  partition  tables  or
add  new disk drivers they should also be added to the stan-
dalone system in /usr/src/sys/stand.

System Identification

     You should edit the files:

        /usr/include/ident.h
        /usr/include/whoami.h
        /usr/include/whoami
        /usr/src/cmd/uucp/uucp.h

to correspond to your system, and then recompile and install
getty(8), binmail(1), who(1) and uucp(1) via:

        # cd /usr/src/cmd
        # DESTDIR=/
        # export DESTDIR
        # MAKE getty.c mail.c who.c uucp

This will arrange for an appropriate banner to be printed on
terminals  before  users  log in, and also arrange that uucp
knows what site you are.

     The program delivermail(8) needs to know  the  topology
of  your  network  configuration  to be able to forward mail
properly; if you are on any networks other than uucp be sure
to print the file /usr/src/cmd/delivermail/READ_ME, edit the
appropriate tables, and recompile and install delivermail as
you did uucp above.

     If you run the  Berkeley  network  net(1)  be  sure  to
change the constant LOCAL in /usr/src/cmd/ucbmail/v7.local.h



                      November 15, 1980





                           - 17 -


and recompile when you bring up a network machine.

Adding New Users

     See adduser(8); local needs will undoubtedly dictate  a
somewhat different procedure.

Multiple Users

     If UNIX is to support  simultaneous  access  from  more
than just the console terminal, the file /etc/ttys (ttys(5))
has to be edited.  To add a new terminal be sure the  device
is  configured  and  the  special  file exists, then set the
first character of the appropriate line of  /etc/ttys  to  1
(or  add  a  new  line).   You  should  also  edit  the file
/etc/ttytype placing the type of the new terminal there (see
ttytype(5)).  The file /etc/ttywhere is also a useful one to
keep up to date.

     Note that /usr/src/cmd/init.c and /usr/src/cmd/comsat.c
will  have to be recompiled if there are to be more than 100
terminals.  Also note that if the special file is inaccessi-
ble  when  init tries to create a process for it, the system
will thrash trying and retrying to open it.

File System Health

     Periodically (say every week or so in  the  absence  of
any  problems)  and  always  (usually automatically) after a
crash, all the filesystems should be checked for consistency
by  fsck(1).   The procedures of reboot(8) should be used to
get the system to a state where a file system check  can  be
performed manually or automatically.

     Dumping of the filesystems should  be  done  regularly,
since  once  the  system  is going it is very easy to become
complacent.  Complete and incremental dumps are easily  done
with  dump(8).   You  should arrange to do a towers-of-hanoi
dump sequence; we tune ours so that  almost  all  files  are
dumped  on  two  tapes  and kept for at least a week in most
every case.  We take full dumps every month (and keep  these
indefinitely).   Operators  can  execute ``dump w'' at login
which will tell them what needs to be dumped (based  on  the
fstab  information).   Be sure to create a group operator in
the file /etc/group so that dump can notify logged-in opera-
tors when it needs help.
__________________________
 More precisely, we have three sets of dump  tapes:  10
daily  tapes,  5 weekly sets of 2 tapes, and fresh sets
of three tapes monthly.  We do daily  dumps  circularly
on the daily tapes with sequence `3 2 5 4 7 6 9 8 9 9 9
quence  level  restarts  after  each weekly dump.  Full
dumps are level 0 and the daily sequence restarts after
each  full  dump  also.   Thus  a typical dump sequence



                      November 15, 1980





                           - 18 -


     Dumping of files by name is best done by tar(1) but the
number  of  files is somewhat limited.  Finally if there are
enough drives entire disks can be copied  with  dd(1)  using
the raw special files and an appropriate block size.

Converting 32/V Filesystems

     The best way to convert filesystems from  32/V  to  the
new  format  is  to  use  tar(1).  After converting, you can
still restore files from your old-format dump tapes (yes the
dump  format  is  different,  sorry  about  that),  by using
``512restor'' instead of ``restor''.  If you wish,  you  can
move whole file systems from 32/V to the new system by using
``dump'' and then ``512restor''.

Regenerating the system

     It is quite easy to regenerate the system, and it is  a
good  idea  to try this once right away to build confidence.
The system consists of three major parts: the kernel  itself
(/usr/src/sys/sys), the user programs (/usr/src/cmd and sub-
directories), and the libraries (/usr/src/lib*).  The  major
part of this is /usr/src/cmd.

     We have  already  seen  how  to  recompile  the  system
itself.   The  three  major  libraries  are the C library in
/usr/src/libc and the FORTRAN libraries /usr/src/libI77  and
__________________________
would be:

number    date    opr     size _
c  c  c  c  c  n  n  n  l  l.   tape   name       level
FULL    0       Nov      24,       1979    jkf     137K
D1      3       Nov       28,       1979    jkf     29K
D2      2       Nov       29,       1979    rrh     34K
D3      5       Nov       30,       1979    rrh     19K
D4      4       Dec       1,       1979     rrh     22K
W1      1       Dec       2,       1979     etc     40K
D5      3       Dec       4,       1979     rrh     15K
D6      2       Dec       5,       1979     jkf     25K
D7      5       Dec       6,       1979     jkf     15K
D8      4       Dec       7,       1979     rrh     19K
W2      1       Dec      9,       1979     etc     118K
D9      3       Dec       11,       1979    rrh     15K
D10     2       Dec       12,       1979    rrh     26K
D1      5       Dec       15,       1979    rrh     14K
W3      1       Dec       17,       1979    etc     71K
D2      3       Dec       18,       1979    etc     13K
FULL    0       Dec 22, 1979    etc     135K

We do weekly's often enough that daily's always fit  on
one  tape  and in fact never get to the sequence of 9's
in the daily level numbers.




                      November 15, 1980





                           - 19 -


/usr/src/libF77.  In each case  the  library  is  remade  by
changing into the corresponding directory and doing

        # make

and then installed by

        # make install

Similar to the system,

        # make clean

cleans up.  The source for all other libraries  is  kept  in
subdirectories  of /usr/src/lib; each has a makefile and can
be recompiled by the above recipe.

     Recompiling all user programs in /usr/src/cmd is accom-
plished  by  using the MAKE shell script which resides there
and its associated  file  DESTINATIONS.   For  instance,  to
recompile ``date.c'', all one has to do is

        # cd /usr/src/cmd
        # MAKE date.c

this will place a stripped version of the binary of ``date''
in  /4bsd/bin/date, since date normally resides in /bin, and
Admin is building a file-system like tree  rooted  at  /4bsd
You  will  have to make the directory 4bsd for this to work.
It is possible to use any directory for the destination,  it
isn't  necessary  to  use the default /4bsd; just change the
instance of ``4bsd'' at the front of MAKE.

     You can also override the default target by doing:

        # DESTDIR=pathname
        # export DESTDIR


     To regenerate all the system source you can do

        # DESTDIR=/usr/newsys
        # export DESTDIR
        # cd /usr
        # rm -r newsys
        # mkdir newsys
        # cd /usr/src/cmd
        # MAKE * > ERRS 2>& 1 &

This will take about 4  hours  on  a  reasonably  configured
machine.   When  it finished you can move the hierarchy into
the normal places using mv(1) and cp(1), and then execute





                      November 15, 1980





                           - 20 -


        # DESTDIR=/
        # export DESTDIR
        # cd /usr/src/cmd
        # MAKE ALIASES
        # MAKE MODES

to link files together as necessary and to set all the right
set-user-id bits.

Making orderly changes

     In order to keep track of changes to system  source  we
migrate  changed  versions  of  commands  in /usr/src/cmd in
through the directory /usr/src/new and out  of  /usr/src/cmd
into  /usr/src/old for a time before removing them.  Locally
written  commands  which  aren't  distributed  are  kept  in
/usr/src/local  and  their  binaries are kept in /usr/local.
This allows /usr/bin /usr/ucb and /bin to correspond to  the
distribution  tape (and to the manuals that people can buy).
People wishing to use /usr/local  commands  are  made  aware
that  they  aren't  in  the  base manual.  As manual updates
incorporate these commands they are moved to /usr/ucb.

     A directory /usr/junk to throw garbage into, as well as
binary  directories  /usr/old  and /usr/new are very useful.
The  man  command  supports  manual  directories   such   as
/usr/man/manj  for  junk and /usr/man/manl for local to make
this or something similar practical.

Interpreting system activity

     The vmstat program provided with the system is designed
to  be  an  aid to monitoring systemwide activity.  Together
with the ps(1) command (as in ``ps av''), it can be used  to
investigate  systemwide virtual activity.  By running vmstat
when the system is active you can judge the system  activity
in  several  dimensions:  job  distribution,  virtual memory
load, paging and swapping activity, disk  and  cpu  utiliza-
tion.   Ideally, there should be few blocked (B) jobs, there
should be little paging or swapping activity,  there  should
be available bandwidth on the disk devices (most single arms
peak out at about 30-35 tps in practice), and the  user  cpu
utilization (US) should be high (above 60%).

     If the system is busy, then the number of  active  jobs
may be large, and several of these jobs may often be blocked
(B).  If the virtual memory is very active, then the  paging
demon  may  be running (SR will be non-zero).  It is healthy
for the paging demon to free pages when the  virtual  memory
gets  active;  it  is triggered by the amount of free memory
dropping below a threshold and increases its  pace  as  free
memory goes to zero.

     If you run vmstat when the system is busy  (a  ``vmstat



                      November 15, 1980





                           - 21 -


5'' is best, since that is how often most of the numbers are
recomputed by the system), you can find imbalances by noting
abnormal  job  distributions.  If a large number of jobs are
blocked (B), then the disk subsystem is overloaded or imbal-
anced.   If  you  have  a large number of non-dma devices or
open teletype lines which are ``ringing'', or user  programs
which  are  doing high-speed non-buffered input/output, then
the system time may go very high (60-70% or higher).  It  is
often  possible to pin down the cause of high system time by
looking to see if there is excessive context switching (CS),
interrupt activity (IN) or system call activity (SY).  Cumu-
latively on one of our large machines we  average  about  60
context switches and interrupts per second and about 90 sys-
tem calls per second.

     If the system is very heavily loaded, or  if  you  have
very  little  memory  relative to your load (1M is little in
most any case), then the system may be forced to swap.  This
is  likely  to  be  accompanied by a noticeable reduction in
system performance as the system  does  not  swap  ``working
sets'',   but  rather  forces  jobs  to  reinitialize  their
resident sets by demand paging.  If you expect to  be  in  a
memory-poor  environment  for  an  extended period you might
consider administratively limiting system load,  and  should
be sure to downsize the system.

Tunable constants

     There is a modicum of tuning available in  the  virtual
memrory management mechanism if it appears to be badly tuned
for your configuration.  The page replacement (clock)  algo-
rithm is run whenever there are not LOTSFREE pages available
(this and all other constants discussed here are defined  in
the  system header file /usr/src/sys/h/vmtune.h).  This sets
up resistance to consumption of the remaining free memory at
a  minimal  rate SLOWSCAN, which gives the desired number of
seconds between successive examinations of each  page.   The
rate  at which the clock algorithm is run increases linearly
to a desired rate of FASTSCAN when there is no free  memory.
Thus as the available free memory decreases, the clock algo-
rithm works harder to hold on to what is left.  If less than
DESFREE  pages  are  available  and the paging rate is high,
then the system will begin to swap processes out.   If  less
than  MINFREE pages are available then the system will begin
to swap, regardless of the paging rate.

     When it has to swap, the system first tries to  find  a
process  which  has been blocked for a long time and swap it
out first.  If there are no jobs of  this  flavor,  then  it
will  choose  among  the 4 largest jobs in-core which it can
swap, picking the one of these which has been core  resident
longest.   It  attempts to guarantee (during periods of very
heavy load) enough core residency to a process to  allow  it
to  at  least rebuild its set of active pages (since it must



                      November 15, 1980





                           - 22 -


do so by demand paging).  Processes which  are  swapped  out
with  large  numbers of active pages similarly receive lower
priority for swapin, favoring small jobs to  return  to  the
core resident set quickly.

     It is very desirable that the system run under  reason-
ably heavy load with little swapping, with the memory parti-
tioning being  done  by  the  clock  replacement  algorithm,
rather than by the swapping algorithm.  The costs associated
with paging activity are the time spent in the paging demon,
the  overhead  associated with reclaim page faults (RE), and
the extra disk activity associated with pagins and pageouts.
We  will  discuss  disk  considerations  later; when kept to
about 40 reclaim faults per second, the cost of reclaims  is
less  than  1% of total processor time.  The cpu time (shown
by ``ps u2'') accumulated by the pageout demon will show how
much overhead it is generating.

     The system, as distributed, runs the replacement  algo-
rithm  whenever  less  than  1/4 of the total user memory is
free.  This is done starting with  a  25  second  revolution
time  of  the  clock algorithm and increasing to a 15 second
revolution time when there is no free memory.  The goal here
is  to  use  as  much memory as possible (i.e. have the free
list short) but to not have the system run out and start  to
swap.   You can experiment with changing the writable copies
of these variables (e.g. ``lotsfree'' is the  writable  copy
of LOTSFREE) using adb, as in:

        # adb -w /vmunix /dev/kmem
        lotsfree/D
        ---adb prints value of lotsfree---
        /W 0t100

Here the ``/W 0t100'' command changed the value of  lotsfree
to be 100 (decimal).

     One final constant which can be changed is  klin  which
controls  the  page-in clustering in the system.  As distri-
buted, it is set to 2, which allows the system to pre-page a
even  numbered  (1k  byte) page when an odd numbered page is
faulted and vice-versa.  In extreme circumstances, for  spe-
cial  purpose applications which cause heavy paging activity
you might try setting it to 4  to  increase  the  amount  of
pre-paging, allowing the system to pre-page up to 3 adjacent
pages.  This will increase the rate at which memory is  con-
sumed  on an active system, so you should be aware that this
can overload the  page  replacement  mechanisms  ability  to
maintain  enough  free  memory  and can thus cause swapping.
With this volume of page traffic it may be necessary to  set
the  global  constant  fifo  to 1 in the system, causing the
paging algorithm to  ignore  page-referencing  behavior  and
favoring, rather, circular replacement.




                      November 15, 1980





                           - 23 -


     Klin should be changed only experimentally  on  systems
with  abnormal  amounts  of  paging  activity.   This is not
necessary or appropriate for  most  any  normal  timesharing
load.

Balancing disk load

     It is critical for good  performance  to  balance  disk
load.   There  are at least five components of the disk load
which you can divide between the available disks:

        1. The root file system.
        2. The /tmp file system.
        3. The /usr file system.
        4. The user files.
        5. The paging activity.

The following possibilities are ones we have  actually  used
at times when we had 2, 3 and 4 disks:

center doublebox; l | c s s l  |  lw(5)  |  lw(5)  |  lw(5).
     disks      what 2    3    4      _     /    1    2    2
tmp  1    3    4 usr  1    1    1  paging    1+2  1+3  1+3+4
users     2    2+3  2+3 archive   x    x    4


     Splits such as these should get you  going.   The  most
important  things  to remember are to even out the disk load
as much as possible, and to do this by decoupling file  sys-
tems  (on separate arms) between which heavy copying occurs.
Note that a long term average balanced load  is  not  impor-
tant...  it  is  much more important to have instantaneously
balanced load when the system is busy.

     Intelligent experimentation  with  a  few  file  system
arrangements  can  pay off in much improved performance.  It
is particularly easy to move the root, the /tmp file  system
and  the  paging  areas.   Place the user files and the /usr
directory as space needs dictate  and  experiment  with  the
other, more easily moved file systems.

Process size limitations

     As distributed, the system provides for  a  maximum  of
64M  bytes of resident user virtual address space.  The size
of the text, and data  segments  of  a  single  process  are
currently  limited  to  6M bytes each, and the stack segment
size is limited to 512K bytes  as  a  soft,  user-changeable
limit,  and may be increased to 6M by calling vlimit(2).  If
these are insufficient, they can be  increased  by  changing
the  constants  MAXTSIZ,  MAXDSIZ  and  MAXSSIZ  in the file
/usr/src/sys/h/vm.h,  while  changing  the  definitions   in
/usr/src/sys/h/dmap.h  and  /usr/src/sys/h/text.h.  You must
be careful in doing  this  that  you  have  adequate  paging



                      November 15, 1980





                           - 24 -


space.   As  configured above, the system has only 16M bytes
of paging area, since there is only one  paging  area.   The
best  way  to get more space is to provide multiple, thereby
interleaved,  paging  areas  by  using  a  file  other  than
confhp.c;  see  the  first  line  of the makefile in the sys
directory and the disk layout section above.

     To increase the amount of resident virtual space possi-
ble,    you   can   alter   the   constant   USRPTSIZE   (in
/usr/src/sys/h/vm.h)  and  by  correspondingly  change   the
definitions of Usrptmap in /usr/src/sys/sys/locore.s Thus to
allow 128 megabytes of  resident  virtual  space  one  would
declare

        _Usrptmap:      .space  16*NBPG


     The  system  has  6  pages  of  page  tables  for   its
text+data+bss  areas  and  the  per-page system information.
This limits this part of the system to 6*64K =  384K  bytes.
The per-page system information uses 12 bytes per 1024 bytes
of user available physical  memory.   This  (conservatively)
takes  55K  bytes  on  a  4  megabyte  machine, limiting the
``size'' of  the  system  to  about  330K  bytes.   You  can
increase  the size of the system page table to, for example,
8 pages by defining, in locore.s:

        _Sysmap:        .space  8*NBPG

You will then also have to change  the  definitions  of  the
constants  UBA0,  MBA0,  and  MBA1 in the files uba.h mba.h,
mba.m, and uba.m.  The 6 in the numbers here is the  6  from
the  number  of  pages  in  Sysmap  thus  UBA0 would then be
defined by

        #define UBA0 0x80080000


     You should  also  change  the  constant  RELOC  in  the
bootstrap  programs in /usr/src/sys/stand to be large enough
to relocate past the end of the system.  Grep(1)  for  RELOC
in  this  directory  and change the constants, recompile the
bootstrap programs and replace them on the floppy.

Other limitations

     Due to the fact that the file system block numbers  are
stored in page table pg_blkno entries, the maximum size of a
file system is limited to 2^20 1024 byte  blocks.   Thus  no
file system can be larger than 1024M bytes.

     The number of mountable file systems is limited  to  15
(which should be enough; if you have a lot of disks it makes
sense to make some of them  single  file  systems,  and  the



                      November 15, 1980





                           - 25 -


paging  areas dont count in this total.) To increase this it
will    be    necessary    to    change     the     core-map
/usr/src/sys/h/cmap.h  since  there  is  a  4 bit field used
here.  The size of the core-map will then expand to 16 bytes
per    1024    byte    page    and    you    should   change
/usr/src/sys/h/cmap.m also.  (Don't forget to change  MSWAPX
and NMOUNT in /usr/src/sys/h/param.h also.)

     The maximum value NOFILE (number of open files per pro-
cess)  can  be raised to is 30 because of a bit field in the
page table entry in /usr/src/sys/h/pte.h.

Scaling down

     If you have 1.5M byte of memory or less you may wish to
scale  the  paging system down, by reducing some fixed table
sizes not  directly  related  to  the  paging  system.   For
instance,  you could reduce NBUF from 128 to 40, NCLIST from
500 to 150, NPROC from 250 to 125, NINODE from 400  to  200,
NFILE  from  350 to 175, NMOUNT from 15 to 8, and NTEXT from
60 to 40.  You can use pstat(8) with the -T option  to  find
out  how  much  of  these  structures  are typically in use.
Although the document is somewhat outdated for the VAX,  you
can   see  the  last  few  pages  of  ``Regenerating  System
Software'' in Volume 2B of the programmers manual for  hints
on setting some of these constants.

Files which need attention

     The following files require periodic attention  or  are
system specific

center; lb a.  /etc/fstab     how disk partitions  are  used
/etc/group     group  memberships  /etc/motd message  of the
day /etc/passwd    password file; each account  has  a  line
/etc/rc   system restart script; runs reboot; starts daemons
/etc/ttys enables/disables   ports   /etc/ttytype   terminal
types corrected to ports /etc/ttywhere  lists physical loca-
tions of terminals  /usr/lib/crontab    commands  which  are
run  periodically  /usr/lib/mailaliases     mail  forwarding
and distribution groups /usr/adm/acct  raw  process  account
data   /usr/adm/dnacct     raw   autodialer   account   data
/usr/adm/messages   system  error  log  /usr/adm/wtmp  login
session accounting


Thats all for now.

     Good luck.


                                        William N. Joy
                                        Ozalp Babaoglu
                                        Keith Sklower



                      November 15, 1980