dnl $OpenBSD: install,v 1.17 2004/03/17 09:25:10 jmc Exp $ OpenBSDInstallPrelude There are several ways to install OpenBSD onto a disk. The easiest way in terms of preliminary setup is to use the OpenBSD ramdisk kernel that can be booted from tape. Alternatively, if the MACHINE is hooked up to a network, it is possible to set up another machine as a server for diskless setup, which is a convenient way to install on a machine whose disk does not currently hold a usable operating system. This is difficult to get set up correctly the first time, but easy to use afterwards. (See ``Installing using a diskless setup'' below). Boot device restrictions: The BUG firmware will not necessarily be able to boot from any device in the system. The following limitations apply: - bootable SCSI tapes must have device ID 4 or 5. - bootable SCSI disks must have device ID 0, 1, 2 or 3. - only the first two MVME328 cards in a system (CLUN 6 and 7) can be used as the boot controller. Booting from the Installation Media: Prior to attempting an installation, everything of value on the target system should be backed up. While installing OpenBSD does not necessarily wipe out all the partitions on the hard disk, errors during the install process can have unforeseen consequences and will probably leave the system unbootable if the installation process is not completed. Availability of the installation media for the prior installation, such as a Motorola SystemV/MACHINE tape is always a good insurance, should it be necessary to "go back" for some reason. After taking care of all that, the system should be brought down gracefully using the shutdown(8) and/or halt(8) commands, which will eventually go back to the ``BUG>'' prompt (it may be necessary to send a break if the system is completely halted). Booting from SCSI tape: Bootable tapes can be booted with the following command at the prompt: 187-Bug> BO xx yy Where `xx' is the SCSI controller number (00 for the built-in SCSI controller on MVME187), and `yy' is the encoding for the SCSI device ID, which varies between controllers. Recent BUG can list the available disk and tape controllers, using the "IOT;H" command: 187-Bug>IOT;H I/O Controllers Available: CLUN CNTRL-TYPE CNTRL-Address N-Devices 0 VME187 $FFF47000 * 6 VME328 $FFFF9000 * In this example, the built-in controller, as well as an external MVME328 controller, are available. The encoding for the drive ID is as follows: - MVME187 built-in controller and MVME327 SCSI controller: 'yy' is ten times the device ID. - MVME328 SCSI controller: 'yy' is eight times the device ID, written in hexadecimal - MVME350 tape controller: 'yy' is always zero, as this controller only supports one tape drive. For example, booting from a tape drive using SCSI ID #5 will be done with: 187-Bug> BO 00 50 using the MVME187 built-in controller, but with: 187-Bug> BO 06 28 using an MVME328 board. Note that OpenBSD/MACHINE can boot off any tape drive supported by the BUG, even if its controller is not supported by OpenBSD. Booting from Network: OpenBSD/MACHINE can boot off any network card supported by the BUG, even if the card itself is not supported by OpenBSD. Two network boot loaders are provided: one for Sun-compatible diskless setup (bootparams and NFS root), and a simpler version limited to TFTP support. The Sun-compatible network bootloader currently only supports the MVME187 on-board interface, and will not be able to boot from any other Ethernet controller. The tftp bootloader does not have this limitation and will boot from any BUG-supported Ethernet controller. If you plan to use the Sun-compatible bootloader, "netboot", it will be necessary to set up a complete diskless client configuration on a server. If the boot server is an OpenBSD system, the diskless(8) manual page will provide detailed information on the process. If the server runs another operating system, the setup instructions will likely be available as part of the documentation that came with it (on SunOS systems, add_client(8) and the Sun System/Networks administrators guide constitute a good start; on Solaris systems, share(1M) is a good starting point as well). Using the TFTP-compatible bootloader, "tftpboot", only requires a TFTP server to be installed on the network, with both the tftpboot file and the kernel image (usually bsd.rd) available from it. The list of BUG-supported Ethernet controllers is available with the "NIOT;A" command. For example: 187-Bug> NIOT;A Network Controllers/Nodes Supported CLUN DLUN Name Address 0 0 VME187 $FFF46000 2 0 VME376 $FFFF1200 3 0 VME376 $FFFF1400 4 0 VME376 $FFFF1600 5 0 VME376 $FFFF5400 6 0 VME376 $FFFF5600 7 0 VME376 $FFFFA400 10 0 VME374 $FF000000 11 0 VME374 $FF100000 12 0 VME374 $FF200000 13 0 VME374 $FF300000 14 0 VME374 $FF400000 15 0 VME374 $FF500000 The "NIOT;H" lists only the available controllers in the machine. For example, on an MVME187 system with no external network card: 187-Bug> NIOT;A Network Controllers/Nodes Available CLUN DLUN Name Address 0 0 VME187 $FFF46000 If the BUG does not support the NIOT command (MVME187 BUG prior to version 1.3 doesn't), then it has no support for netbooting. Before netbooting, enter "NIOT" and fill the parameters. Be sure to provide the correct values for Controller LUN and Device LUN (as listed in the "NIOT;A" output); also the "Boot File Load Address" and "Boot File Execution Address" need to be set to 00AF0000. The "Boot File Name" must match the name of the netboot file on the server (copying it as "netboot.mvme88k" or "tftpboot.mvme88k" is usually a wise choice). Finally, "Argument File Name" needs to be set to "bsd.rd" in order to boot the installation miniroot, rather than the regular kernel. Here are acceptable values for a 187 card using the built-in controller: 187-Bug> NIOT Controller LUN =00? Device LUN =00? Node Control Memory Address =01FF0000? Client IP Address =0.0.0.0? Server IP Address =0.0.0.0? Subnet IP Address Mask =255.255.255.0? Broadcast IP Address =255.255.255.255? Gateway IP Address =0.0.0.0? Boot File Name ("NULL" for None) =? netboot.mvme88k Argument File Name ("NULL" for None) =? bsd.rd Boot File Load Address =001F0000? 00AF0000 Boot File Execution Address =001F0000? 00AF0000 Boot File Execution Delay =00000000? Boot File Length =00000000? Boot File Byte Offset =00000000? BOOTP/RARP Request Retry =00? TFTP/ARP Request Retry =00? Trace Character Buffer Address =00000000? BOOTP/RARP Request Control: Always/When-Needed (A/W)=W? BOOTP/RARP Reply Update Control: Yes/No (Y/N) =Y? If you change the NIOT configuration, you will be asked whether you want to make these changes permanent. Do not answer Y unless you plan to netboot this board very often; be sure to have the ENV settings use a correct address for the NIOT parameters block in this case. A valid setting is: Network Auto Boot Configuration Parameters Pointer (NVRAM) = 00000000? FFFC0080 for example. Once the NIOT parameters are set, it should be possible to boot the machine from the server with the NBO command: 187-Bug> NBO 00 00 or if you know the IP address for the MACHINE and the TFTP server, you can directly provide the boot loader's filename and the kernel name on the commandline: 187-Bug> NBO 00 00 192.168.0.68 192.168.0.1 tftpboot.mvme88k bsd.rd where, in this example, 192.168.0.68 is the address of the MACHINE computer, and 192.168.0.1 the address of the diskless server. If the BUG version does not understand the NIOT and NBO commands (most MVME187 don't), there is currently no way to netboot. Installing using the tape or netboot procedure: OpenBSDInstallPart2 Boot your machine from the installation media as described above. It will take a while to load the kernel especially from a slow network connection, most likely more than a minute. If some action doesn't eventually happen, or the spinning cursor has stopped and nothing further has happened, either your boot media is bad, your diskless setup isn't correct, or you may have a hardware or configuration problem. OpenBSDBootMsgs You will next be asked for your terminal type. You should choose the terminal type from amongst those listed. (If your terminal type is xterm, just use vt100). OpenBSDInstallPart3 OpenBSDInstallPart4 OpenBSDInstallPart5(sd0) OpenBSDInstallNet({:-CD-ROM, NFS, -:}) OpenBSDFTPInstall OpenBSDHTTPInstall OpenBSDTAPEInstall(4) OpenBSDCDROMInstall OpenBSDNFSInstall OpenBSDDISKInstall(,{:-only -:}) OpenBSDCommonFS(NFS) OpenBSDCommonURL OpenBSDCongratulations Net Boot or Diskless Setup Information: The set up is similar to SunOS diskless setup, but not identical, because the Sun setup assumes that the bootblocks load a kernel image, which then uses NFS to access the exported root partition, while the OpenBSD bootblocks use internal NFS routines to load the kernel image directly from the exported root partition. Please understand that no one gets this right the first try, since there is a lot of setup and all the host daemons must be running and configured correctly. If you have problems, extract the diskless(8) manpage, find someone who's been through it before and use the host syslog and tcpdump(8) to get visibility of what's happening (or not). Your MACHINE expects to be able to download a second stage bootstrap program via TFTP after having acquired its IP address through RevARP when instructed to boot "over the net". It will look for the filename specified on the NBO commandline, or via the NIOT parameters. Normally, this file is a symbolic link to an appropriate second-stage boot program, which should be located in a place where the TFTP daemon can find it (remember, many TFTP daemons run in a chroot'ed environment). You can find the boot program in `/usr/mdec/netboot' in the OpenBSD/MACHINE distribution. After the boot program has been loaded into memory and given control by the BUG, it starts locating the machine's remote root directory through the BOOTPARAM protocol. First a BOOTPARAM WHOAMI request is broadcast on the local net. The answer to this request (if it comes in) contains the client's name. This name is used in the next step, a BOOTPARAM GETFILE request -- sent to the server that responded to the WHOAMI request -- requesting the name and address of the machine that will serve the client's root directory, as well as the path of the client's root on that server. Finally, this information (if it comes in) is used to issue a REMOTE MOUNT request to the client's root filesystem server, asking for an NFS file handle corresponding to the root filesystem. If successful, the boot program starts reading from the remote root filesystem in search of the kernel which is then read into memory. Unpack `base{:--:}OSrev.tgz' and `etc{:--:}OSrev.tgz' on the server in the root directory for your target machine. If you elect to use a separately NFS-mounted filesystem for `/usr' with your diskless setup, make sure the "./usr" base files in base{:--:}OSrev.tgz end up in the correct location. One way to do this is to temporarily use a loopback mount on the server, re-routing /usr to your server's exported OpenBSD "/usr" directory. Also put the kernel and the install/upgrade scripts into the root directory. A few configuration files need to be edited: /etc/hosts Add the IP addresses of both server and client. /etc/myname This files contains the client's hostname; use the same name as in /etc/hosts. /etc/fstab Enter the entries for the remotely mounted filesystems. For example: server:/export/root/client / nfs rw 0 0 server:/export/exec/MACHINE.OpenBSD /usr nfs rw 0 0 OpenBSDInstNFS