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diff --git a/usr.sbin/config/SMM.doc/5.t b/usr.sbin/config/SMM.doc/5.t deleted file mode 100644 index 81f2a52..0000000 --- a/usr.sbin/config/SMM.doc/5.t +++ /dev/null @@ -1,271 +0,0 @@ -.\" Copyright (c) 1983, 1993 -.\" The Regents of the University of California. All rights reserved. -.\" -.\" Redistribution and use in source and binary forms, with or without -.\" modification, are permitted provided that the following conditions -.\" are met: -.\" 1. Redistributions of source code must retain the above copyright -.\" notice, this list of conditions and the following disclaimer. -.\" 2. Redistributions in binary form must reproduce the above copyright -.\" notice, this list of conditions and the following disclaimer in the -.\" documentation and/or other materials provided with the distribution. -.\" 3. All advertising materials mentioning features or use of this software -.\" must display the following acknowledgement: -.\" This product includes software developed by the University of -.\" California, Berkeley and its contributors. -.\" 4. Neither the name of the University nor the names of its contributors -.\" may be used to endorse or promote products derived from this software -.\" without specific prior written permission. -.\" -.\" THIS SOFTWARE IS PROVIDED BY THE REGENTS AND CONTRIBUTORS ``AS IS'' AND -.\" ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE -.\" IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE -.\" ARE DISCLAIMED. IN NO EVENT SHALL THE REGENTS OR CONTRIBUTORS BE LIABLE -.\" FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL -.\" DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS -.\" OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) -.\" HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT -.\" LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY -.\" OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF -.\" SUCH DAMAGE. -.\" -.\" @(#)5.t 8.1 (Berkeley) 6/8/93 -.\" -.\".ds RH "Sample Configuration Files -.ne 2i -.NH -SAMPLE CONFIGURATION FILES -.PP -In this section we will consider how to configure a -sample VAX-11/780 system on which the hardware can be -reconfigured to guard against various hardware mishaps. -We then study the rules needed to configure a VAX-11/750 -to run in a networking environment. -.NH 2 -VAX-11/780 System -.PP -Our VAX-11/780 is configured with hardware -recommended in the document ``Hints on Configuring a VAX for 4.2BSD'' -(this is one of the high-end configurations). -Table 1 lists the pertinent hardware to be configured. -.DS B -.TS -box; -l | l | l | l | l -l | l | l | l | l. -Item Vendor Connection Name Reference -_ -cpu DEC VAX780 -MASSBUS controller Emulex nexus ? mba0 hp(4) -disk Fujitsu mba0 hp0 -disk Fujitsu mba0 hp1 -MASSBUS controller Emulex nexus ? mba1 -disk Fujitsu mba1 hp2 -disk Fujitsu mba1 hp3 -UNIBUS adapter DEC nexus ? -tape controller Emulex uba0 tm0 tm(4) -tape drive Kennedy tm0 te0 -tape drive Kennedy tm0 te1 -terminal multiplexor Emulex uba0 dh0 dh(4) -terminal multiplexor Emulex uba0 dh1 -terminal multiplexor Emulex uba0 dh2 -.TE -.DE -.ce -Table 1. VAX-11/780 Hardware support. -.LP -We will call this machine ANSEL and construct a configuration -file one step at a time. -.PP -The first step is to fill in the global configuration parameters. -The machine is a VAX, so the -.I "machine type" -is ``vax''. We will assume this system will -run only on this one processor, so the -.I "cpu type" -is ``VAX780''. The options are empty since this is going to -be a ``vanilla'' VAX. The system identifier, as mentioned before, -is ``ANSEL,'' and the maximum number of users we plan to support is -about 40. Thus the beginning of the configuration file looks like -this: -.DS -.ta 1.5i 2.5i 4.0i -# -# ANSEL VAX (a picture perfect machine) -# -machine vax -cpu VAX780 -timezone 8 dst -ident ANSEL -maxusers 40 -.DE -.PP -To this we must then add the specifications for three -system images. The first will be our standard system with the -root on ``hp0'' and swapping on the same drive as the root. -The second will have the root file system in the same location, -but swap space interleaved among drives on each controller. -Finally, the third will be a generic system, -to allow us to boot off any of the four disk drives. -.DS -.ta 1.5i 2.5i -config kernel root on hp0 -config hpkernel root on hp0 swap on hp0 and hp2 -config genkernel swap generic -.DE -.PP -Finally, the hardware must be specified. Let us first just try -transcribing the information from Table 1. -.DS -.ta 1.5i 2.5i 4.0i -controller mba0 at nexus ? -disk hp0 at mba0 disk 0 -disk hp1 at mba0 disk 1 -controller mba1 at nexus ? -disk hp2 at mba1 disk 2 -disk hp3 at mba1 disk 3 -controller uba0 at nexus ? -controller tm0 at uba0 csr 0172520 vector tmintr -tape te0 at tm0 drive 0 -tape te1 at tm0 drive 1 -device dh0 at uba0 csr 0160020 vector dhrint dhxint -device dm0 at uba0 csr 0170500 vector dmintr -device dh1 at uba0 csr 0160040 vector dhrint dhxint -device dh2 at uba0 csr 0160060 vector dhrint dhxint -.DE -.LP -(Oh, I forgot to mention one panel of the terminal multiplexor -has modem control, thus the ``dm0'' device.) -.PP -This will suffice, but leaves us with little flexibility. Suppose -our first disk controller were to break. We would like to recable the -drives normally on the second controller so that all our disks could -still be used without reconfiguring the system. To do this we wildcard -the MASSBUS adapter connections and also the slave numbers. Further, -we wildcard the UNIBUS adapter connections in case we decide some time -in the future to purchase another adapter to offload the single UNIBUS -we currently have. The revised device specifications would then be: -.DS -.ta 1.5i 2.5i 4.0i -controller mba0 at nexus ? -disk hp0 at mba? disk ? -disk hp1 at mba? disk ? -controller mba1 at nexus ? -disk hp2 at mba? disk ? -disk hp3 at mba? disk ? -controller uba0 at nexus ? -controller tm0 at uba? csr 0172520 vector tmintr -tape te0 at tm0 drive 0 -tape te1 at tm0 drive 1 -device dh0 at uba? csr 0160020 vector dhrint dhxint -device dm0 at uba? csr 0170500 vector dmintr -device dh1 at uba? csr 0160040 vector dhrint dhxint -device dh2 at uba? csr 0160060 vector dhrint dhxint -.DE -.LP -The completed configuration file for ANSEL is shown in Appendix C. -.NH 2 -VAX-11/750 with network support -.PP -Our VAX-11/750 system will be located on two 10Mb/s Ethernet -local area networks and also the DARPA Internet. The system -will have a MASSBUS drive for the root file system and two -UNIBUS drives. Paging is interleaved among all three drives. -We have sold our standard DEC terminal multiplexors since this -machine will be accessed solely through the network. This -machine is not intended to have a large user community, it -does not have a great deal of memory. First the global parameters: -.DS -.ta 1.5i 2.5i 4.0i -# -# UCBVAX (Gateway to the world) -# -machine vax -cpu "VAX780" -cpu "VAX750" -ident UCBVAX -timezone 8 dst -maxusers 32 -options INET -options NS -.DE -.PP -The multiple cpu types allow us to replace UCBVAX with a -more powerful cpu without reconfiguring the system. The -value of 32 given for the maximum number of users is done to -force the system data structures to be over-allocated. That -is desirable on this machine because, while it is not expected -to support many users, it is expected to perform a great deal -of work. -The ``INET'' indicates that we plan to use the -DARPA standard Internet protocols on this machine, -and ``NS'' also includes support for Xerox NS protocols. -Note that unlike 4.2BSD configuration files, -the network protocol options do not require corresponding pseudo devices. -.PP -The system images and disks are configured next. -.DS -.ta 1.5i 2.5i 4.0i -config kernel root on hp swap on hp and rk0 and rk1 -config upkernel root on up -config hkkernel root on hk swap on rk0 and rk1 - -controller mba0 at nexus ? -controller uba0 at nexus ? -disk hp0 at mba? drive 0 -disk hp1 at mba? drive 1 -controller sc0 at uba? csr 0176700 vector upintr -disk up0 at sc0 drive 0 -disk up1 at sc0 drive 1 -controller hk0 at uba? csr 0177440 vector rkintr -disk rk0 at hk0 drive 0 -disk rk1 at hk0 drive 1 -.DE -.PP -UCBVAX requires heavy interleaving of its paging area to keep up -with all the mail traffic it handles. The limiting factor on this -system's performance is usually the number of disk arms, as opposed -to memory or cpu cycles. The extra UNIBUS controller, ``sc0'', -is in case the MASSBUS controller breaks and a spare controller -must be installed (most of our old UNIBUS controllers have been -replaced with the newer MASSBUS controllers, so we have a number -of these around as spares). -.PP -Finally, we add in the network devices. -Pseudo terminals are needed to allow users to -log in across the network (remember the only hardwired terminal -is the console). -The software loopback device is used for on-machine communications. -The connection to the Internet is through -an IMP, this requires yet another -.I pseudo-device -(in addition to the actual hardware device used by the -IMP software). And, finally, there are the two Ethernet devices. -These use a special protocol, the Address Resolution Protocol (ARP), -to map between Internet and Ethernet addresses. Thus, yet another -.I pseudo-device -is needed. The additional device specifications are show below. -.DS -.ta 1.5i 2.5i 4.0i -pseudo-device pty -pseudo-device loop -pseudo-device imp -device acc0 at uba? csr 0167600 vector accrint accxint -pseudo-device ether -device ec0 at uba? csr 0164330 vector ecrint eccollide ecxint -device il0 at uba? csr 0164000 vector ilrint ilcint -.DE -.LP -The completed configuration file for UCBVAX is shown in Appendix C. -.NH 2 -Miscellaneous comments -.PP -It should be noted in these examples that neither system was -configured to use disk quotas or the 4.1BSD compatibility mode. -To use these optional facilities, and others, we would probably -clean out our current configuration, reconfigure the system, then -recompile and relink the system image(s). This could, of course, -be avoided by figuring out which relocatable object files are -affected by the reconfiguration, then reconfiguring and recompiling -only those files affected by the configuration change. This technique -should be used carefully. |