593 lines
22 KiB
Plaintext
593 lines
22 KiB
Plaintext
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This HOWTO contains instructions for using LinuxBIOSv2 on the VIA EPIA-M and MII
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mini-itx based motherboards.
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Version 1.0 initial write for LinuxBIOSv2 by Nick Barker
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Using materials and inspiration from
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- EPIA HOWTO for freebios/linuxbios by Mark Wilkinson
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- Based on the K7SEM HOWTO by Brenden Bixler,
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- which is based on the Sis 630 HOWTO by Ron Minnich.
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- Getting Started with freebios2 - a mail posting by Jay Miller
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Unfortunately, there is a step in this HOWTO that could be hazardous. The
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hazards include (but are not limited to)
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1) destroying your motherboard
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2) hurting yourself
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3) killing yourself
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Because of these hazards, you must take full responsibility if you
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decide to install LinuxBIOSv2 following these procedures. Neither the
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author of this HOWTO or any organisation or individual associated with
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the LinuxBIOSv2 project can be held responsible for any adverse consequences
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of your attempt to follow these procedures.
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WARNING: We assume you've built kernels, know how to open up your PC,
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and how to yank the flash part out while power is on and put in a
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different part. There is NO WARRANTY, express or implied, with this
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software. In fact, if you don't know what you're doing, and you get
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careless, you're going to end up with a nice paperweight instead of a
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motherboard, an emergency room bill, or a funeral service.
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YOU HAVE BEEN WARNED.
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Additional information available at: http://www.linuxbios.org/
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Linux distribution: Most modern distributions are supported.
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Other software notes: You MUST have 'as' version 2.9.5 or later.
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You MUST have 'gcc' version other than 2.96.
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Pre-requisites
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--------------
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Before you start there are a few things which you need to arrange:
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Since you are going to be re-programming the flash rom on the mainboard, and
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it is likely that you first few attempts / images will not be right, then
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you need a way of restoring a known working bios onto a board which is otherwise
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dead.
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Recommended: you might want to get a Bios Saviour (RD1-PL) - this is
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a handy little piggy-back flash chip that saves you destroying the original
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flash image. This howto assumes that you have this device, though other methods
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and devices exist for programming flash roms.
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LinuxBIOSv2 sends debugging output through the first serial port. You might want
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to arrange a null modem serial cable for connecting this serial port to a
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second computer running a terminal emulation program. I use 'microcom' which
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is simple and allows all output to be captured into a file for later analysis.
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The port is set up to use 115200 baud, 8bit, No parity, 1 stop bit.
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Under LinuxBIOSv2 you have a choice of 'payloads'. The payload is the program
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which LinuxBIOSv2 hands over to once it has finished initialising everything
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on the mainboard at boot time. The payload is included in the flash rom along
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with LinuxBIOSv2, and usually its function is to locate and load the operating
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system. The 2 most common payloads are FILO, for booting Linux off an IDE
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disk, and Etherboot for booting a diskless workstation accross a network.
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This howto assumes the use of FILO.
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A vga bios image. LinuxBIOS2v2 uses the vga bios of the original Via BIOS to
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initialise the vga. It is not directly downloadable, but you can capture it from
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a system running with the original bios, so you might as well capture it now:
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dd if=/dev/mem of=/video.bios.bin \
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bs=1 count=65536 skip=790528
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Getting Going
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-------------
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The steps for loading LinuxBIOSv2 are simple:
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1) Get Linux installed on your machine.
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2) Download and install LinuxBIOSv2 sources.
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3) Understand how to flash your rom.
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4) Download, Configure and build the FILO payload
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5) Configure and build LinuxBIOSv2.
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6) Burn the LinuxBIOSv2 image to the flash.
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7) Reset the machine -- did it work?
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Options Once it has booted
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i) Speeding up the boot
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ii) Enhancing ACPI support
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iii) On EPIA-MII, booting the computer from on-board compact flash
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Step 1)
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Get Linux installed on your LinuxBIOSv2 machine.
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Don't forget to note which partition is / (/dev/hda3 etc.)
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Step 2)
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Grab the LinuxBIOSv2 source.
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cd to the directory you want the source tree to be.
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Note: this will create a sub directory called LinuxBIOSv2 which contains
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the LinuxBIOSv2 source code
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Download the latest code for LinuxBIOSv2 from the downloads page at
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http://www.linuxbios.org
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having expanded the tarball, cd into the LinuxBIOSv2 directory and browse around.
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The top level directory includes:
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'src' - where all of the source files for LinuxBIOSv2 are located.
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'targets' - where all of the platform specific configuration files
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for each platform supported by LinuxBIOSv2 are kept, and
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where the build files and build process occur.
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'util' - where various utilities required for the build process
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and debugging are kept.
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Hereafter, this howto refers to directory locations relative to these directories,
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unless an absolute pathlist is given.
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Step 3)
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Whilst getting LinuxBIOSv2 going on your EPIA-M, you are almost
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certainly going to be re-programming the flash rom several times, and
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there is a very high probability that at one of these stages you will
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get a flash rom that fails to boot your mainboard into Linux.
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Before we proceed any further, it is absolutley vital that you have
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worked out how to program the flash chip, and how you are going to
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get back to your original bios when things go wrong. Otherwise you
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will end up with a very expensive paper weight as described earlier.
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You can use a professional Data I/O burner, or you can be foolhardy
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and simply re-program the flash part of a running machine. However
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whilst getting going a BIOS SAVIOUR RD1-PL is a very inexpensive
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but effective device for ensuring that you always have a working
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BIOS to hand.
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The bios saviour is a little device which plugs into the flash rom
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socket of the motherboard, and the original flash rom then plugs into
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the bios saviour. The bios saviour includes a second flash rom chip,
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and either of these chips can be selected as the active chip by a
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simple supplied electrical switch mounted on flying leads. Make
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sure that this switch is clearly visible, so that you know which
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chip you are booting from, and which chip you are about to re-program.
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Decide which chip you are going to use for LinuxBIOSv2, and which chip
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you are going to keep the original working bios in, and mark them
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clearly on this switch.
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In the 'util/flash_and_burn' directory is the source for the 'flash_rom'
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utility, which is great for re-programming the flash chips on the
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EPIA-M / MII. Once you have built this utility:
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Make sure that it can detect both flash chips on the bios saviour:
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with switch set to chip 1 run 'flash_rom'
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flash rom should search through a list of known flash rom
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device types until it finds the type of the original chip
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from your EPIA-M, and report what it has found.
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with the switch set to chip 2, run 'flash_rom' again and confirm
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that it can 'see' the second flash chip.
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If your are lucky, the actual part number of the 2 chips may
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be different, which you can use just prior to re-programming
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a chip to make sure you are programming the right chip.
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Make sure that you can read / write and verify a flash chip:
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with switch set to 1 (original BIOS) run
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'flash_rom -r original.rom'
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this should read the contents of the original bios into the
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file original.rom
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confirm that the newly read file matches the original bios
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'flash_rom -v original.rom'
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set the switch to 2
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confirm if you can that flash_rom 'sees' the second chip
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'flash_rom' - and look for the detected device type
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write the known good bios to the second chip with
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'flash_rom -w original.bios'
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verify that it has written correctly
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'flash_rom -v original.rom'
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with switch left at position 2, reboot the machine and make
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sure that it comes up corectly. If it does then you now have
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a working flash programming environment. If it does not, then
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set the switch back to 1, reboot the machine, and investigate
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further.
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Step 4)
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Download FILO from http://felixx.tsn.or.jp/~ts1/filo, and expand
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In the FILO source directory, type 'make'
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The first invocation of make builds the default Config file, which
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should be edited to meet your needs. In particular look at the line:
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"AUTOBOOT_FILE ...."
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and make sure that it looks sensible for your setup. The line
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AUTOBOOT_FILE "hda1:/vmlinuz root=/dev/hda2 console=ttyS0,115200"
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reads as:
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- find a linux os image on device hda partion 1 called vmlinuz,
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- load this image
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- execute the image passing kernel command line parameters of:
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"root=/dev/hda2 console=ttyS0,115200"
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after editing Config, type 'make' again, and this will build the file
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'filo.elf' which is the payload we will be using.
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Copy this file to somewhere which the LinuxBIOSv2 makefile can easily
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find it. I just tend to keep it in the root directory though I'm sure
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others will condem me for that practise:
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'cp filo.elf /'
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Make sure that you have compiled a kernel bzImage, and copied it to
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the file location you identified in the FILO Config file.
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Step 5)
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The next step is to create the build environment for the epia-m. This
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step creates the appropriate makefiles and build directories for the
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epia-m.
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'cd targets'
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'./buildtarget via/epia-m'
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This step will create a subdirectory in the targets/via/epia-m
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directory called epia-m, which is the build directory for LinuxBIOSv2.
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The main configuration file for the epia-m is in
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'targets/via/epia-m/Config.lb'
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If you need to make any changes to the configuration, for example you wish to
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locate filo.elf in a place other than '/filo.elf', or during the more advanced
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steps of this HOWTO, then these changes are made to this file.
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You need to re-run the './buildtartegt via/epia-m' after any such change.
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The directory 'targets/via/epia-m' contains other sample Config.lb files, any
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of which can be copied through to Config.lb in order to become the current
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configuration.
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Once you have your Config.lb set up to your needs, and the build environment
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created with './buildtarget', it is time to build a rom image.
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Change directory into the build directory 'targets/via/epia-m/epia-m'
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The configuration as set up by the buildtarget process will create a LinuxBIOS
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which is exactly 196608 bytes long, which is exactly 64K bytes short of what
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needs to go into the 256K flash rom. The other 64K is for your vga bios
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which is simply merged with the linuxbios image. The easiest way to make this
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happen is to edit the Makefile and change the line
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cat fallback/linuxbios.rom > linuxbios.rom
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to
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cat /video.bios.bin fallback/linuxbios.rom >linuxbios.rom
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Note: the above order of merging the files together is critical
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You will need to remember to make this change every time after you have run
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the buildtarget program.
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Type 'make', and wait for the build process to complete.
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If all went well, then you should find a file 'linuxbios.rom' in your
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current directory. Check that it is 262144 bytes long - i.e. exactly the right
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size for the flash rom chip in your EPIA-M / MII.
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Step 6)
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NOTE: BE ADVISED THAT THIS STEP CAN KILL YOUR MOTHERBOARD !
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IF YOU DO NOT HAVE A MEANS OF RECOVERING FROM FLASHING YOUR BIOS,
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YOU MAY/WILL BE LEFT WITH A DEAD MACHINE.
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Assuming that you are using a Bios Saviour, make sure that the switch is set
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to the position for your LinuxBIOSv2 image.
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Type 'flash_rom' to make sure it can see the flash chip, and verify its type if
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possible.
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Only once you are happy that you are about to re-programme the desired chip, type
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'flash_rom -w linuxbios.rom', and wait the few seconds it takes to program it.
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Once it has finished, verify that the chip was re-rogrammed correctly - type
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'flash_rom -v linuxbios.rom'
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Step 7)
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Power cycle the machine. LinuxBIOSv2 should come up in a few seconds.
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With a connection to the serial port set at 115200, you should see LinuxBIOSv2
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come up, launch FILO, and if you have a timeout set in FILO, then it may be
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waiting for you to confirm its boot command line.
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As long as you have this command line set up correctly, and an os image in the
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right place, then FILO should proceed to boot into your Linux os.
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If you do, CONGRATULATIONS ! It WORKED ! Pat yourself on the back,
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why not try the optional steps now ?
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If you don't, time to start capturing the output of the serial port
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and talking to the linuxbios mailing list.
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Optional steps - for use only if step 7 was successfull.
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OK so now we have a BIOS which boots your computer fully into the operating system, and
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depending upon your needs that may be all that you want. However LinuxBIOSv2 has a few more
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tricks up its sleeve should you find yourself hungry for more.
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Speeding up the boot
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--------------------
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Linuxbios sends its debugging output to the first serial port and, depending upon the amount of debug
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output selected, can be the limiting factor in the speed with which it boots your computer - regardless
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of whether you have anything attached to the serial port.
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Linuxbios uses the notion of debug levels to control what is sent to the serial port. These levels
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range from 0 to 9 with 0 being the least verbose and 9 being the most verbose.
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These levels are defined in the Config.lb file described earlier. To reduce the output set:
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option MAXIMUM_CONSOLE_LOGLEVEL=8
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option DEFAULT_CONSOLE_LOGLEVEL=8
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to lower values.
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Next you will have to run 'buildtarget' again to propagate the effects of the config change.
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Then edit your Makefile again to include your video bios in the final merging.
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Then run 'make clean' followed by 'make'.
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Advanced ACPI
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-------------
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LinuxBIOSv2 now supports ACPI on the epia-m and epia-m II. In particular the interrupt
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processing in Linux can be done through ACPI, and crude power management support
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is provided. This includes software power off, and power management events from the
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power button.
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It is possible to enhance this behaviour to provide the full capabilities of the
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original BIOS, which includes different sleep levels and wake from these levels
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upon certain events. This is achieved by using a 'grabbed' copy of the ACPI
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Differentiated System Descriptor Table or DSDT from the original BIOS.
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For copyright reasons this table cannot be included with the source distribution
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of LinuxBIOSv2.
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You MUST have 'iasl' - Intel's ACPI Asl compiler for Unix/Linux -
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http://developer.intel.com/technology/iapc/acpi/downloads.htm.
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To replace the LinuxBIOSv2 DSDT with the grabbed one from the original BIOS:
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- Start the computer using the original BIOS, and make sure that you
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have ACPI set up in the kernel that you are running
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- Grab the DSDT table - 'cat /proc/acpi/dsdt >dsdt.aml'
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- Convert to asl code - 'iasl -d dsdt.aml' (creates dsdt.dsl)
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- Convert it to a C hex table - 'iasl -tc dsdt.dsl' (creates dsdt.hex)
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- Replace the file 'src/mainboard/via/epia-m/dsdt.c with dsdt.hex
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Now re-build LinuxBIOSv2, re-program the flash and power cycle.
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If you wish to return to the LinuxBIOSv2 DSDT, then the original file dsdt.asl can be converted
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into a C hex file using 'iasl -tc dsdt.asl'
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Boot from Onboard Compact Flash (MII only)
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------------------------------------------
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LinuxBIOSv2 now supports the onboard compact flash on the MII as an IDE drive,
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and it is possible to boot directly from this drive using the following steps.
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The first step is to get Filo or whatever payload you are using to recognise
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and use this device.
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In order that the pcmcia subsystem of the Linux kernel can correctly configure
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the device later on in the boot process the CF is set up with its I/O
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registers in a contiguous block of 16 bytes at 0x1e0 through 0x1ef. Unfortunately
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this is not a standard IDE address which is why we need to 'fix' filo to use it.
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(Actually it is half of the address range used by IDE4, and so we need to
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be careful to tell the kernel not to probe that address - more on that later).
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The first step is to change the filo Config file.
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1) Comment out SUPPORT_PCI=1. This line instructs filo to search for PCI based IDE
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adapters only, and the CF is not attached to a PCI based IDE controller.
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2) Add the following two lines somewhere in the Config file:
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IDE2_CMD = 0x1e0
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IDE2_CNTRL =0x1ec
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The second step is to modify the file drivers/ide.c in the filo source directory.
|
||
|
Find the function 'find_ide_controller_compat' and change it to look like
|
||
|
|
||
|
static int find_ide_controller_compat(struct controller *ctrl, int index)
|
||
|
{
|
||
|
if (index >= IDE_MAX_CONTROLLERS)
|
||
|
return -1;
|
||
|
#ifdef IDE2_CMD
|
||
|
if(index == 2){
|
||
|
ctrl->cmd_base = IDE2_CMD;
|
||
|
ctrl->ctrl_base = IDE2_CNTRL;
|
||
|
return 0;
|
||
|
}
|
||
|
#endif
|
||
|
ctrl->cmd_base = ide_base[index];
|
||
|
ctrl->ctrl_base = ide_base[index] + IDE_REG_EXTENDED_OFFSET;
|
||
|
return 0;
|
||
|
}
|
||
|
Filo will now recognise the CF as the first device on the third IDE controller
|
||
|
(i.e. ide2), and can be referred to as 'hde'
|
||
|
|
||
|
|
||
|
The next step is to create an initrd file for your Linux kernel. What? Why?
|
||
|
The CF socket on your MII is hardwired to the PCMCIA controller and for all intents
|
||
|
and purposes it is a PCMCIA device. This means that once Linux boots it will be under
|
||
|
the control of the pcmcia manager. Now according to the pcmcia-utils documentation,
|
||
|
the pcmcia manager is intended to control and configure devices on an already
|
||
|
running system. Yet if we need the CF to be the root device, it needs to be mounted
|
||
|
very early on in the boot sequence, before the stage where pcmcia devices would normally
|
||
|
be configured. The answer is to use an initrd file to get the pcmcia manager running early
|
||
|
for the CF. If you are unfamiliar with initrd then 'man initrd' will give you more background.
|
||
|
|
||
|
|
||
|
The easiest way to create an initrd is to use the script 'mkcfinitrd' which is at the bottom
|
||
|
of this howto. This is a tailored version of the 'pcinitrd' script from the pcmcia-utils package.
|
||
|
Make sure that 'ash' is available on your system as this is the tiny shell programme used during
|
||
|
the initrd phase of booting.
|
||
|
|
||
|
It is worth mounting the initrd generated, and looking over it to make sure that
|
||
|
it contains all of the modules necessary to load and initialise the CF. It does not
|
||
|
need drivers for whatever you use in the pcmcia socket, as that can be initialised
|
||
|
later on in the boot process as before.
|
||
|
|
||
|
Finally gzip the file created, and move it alongside your kernel.
|
||
|
|
||
|
Next adjust your FILO command line to pick things up from the CF. My linux command
|
||
|
line in filo looks like:
|
||
|
|
||
|
AUTOBOOT_FILE = "hde:/vmlinuz initrd=hde:/initrd.gz root=/dev/hde console=tty0 ide4=noprobe"
|
||
|
|
||
|
The ide4=noprobe option is required to stop the kernel from probing the address used
|
||
|
by the CF. As this address is half that used as the standard address for a fifth (i.e. ide4)
|
||
|
controller, the kernel hangs whilst trying to initialise this device if this option
|
||
|
is not given.
|
||
|
|
||
|
Finally make sure that you have copied the necessary files onto your CF, and re-boot
|
||
|
your computer.
|
||
|
|
||
|
|
||
|
|
||
|
******************* mkcfinitrd script **************************************
|
||
|
#!/bin/sh
|
||
|
#
|
||
|
# Utility for constructing CF initrd for Epia-MII CF Boot
|
||
|
#
|
||
|
# Copyright (C) 2005 Nick Barker -- nick.barker9@btinternet.com
|
||
|
#
|
||
|
# Based on pcinitrd
|
||
|
# Copyright (C) 1999 David A. Hinds -- dahinds@users.sourceforge.net
|
||
|
|
||
|
SIZE=2400
|
||
|
MODULES="pcmcia/pcmcia_core.o pcmcia/ds.o pcmcia/yenta_socket.o"
|
||
|
BLK="kernel/drivers/ide/legacy/ide-cs.o"
|
||
|
KERNEL=`uname -r`
|
||
|
MODDIR=/lib/modules/$KERNEL
|
||
|
BIN="bin/mount bin/umount sbin/insmod sbin/cardmgr"
|
||
|
LIB=`ls /lib/libc.so.? | sort | tail -1`
|
||
|
ETC="/etc/ld.so.cache /etc/pcmcia/config /etc/pcmcia/config.opts"
|
||
|
DEV="/dev/console /dev/null /dev/ram /dev/tty1 /dev/tty2 /dev/tty3 /dev/tty4"
|
||
|
MNT=/tmp/initrd.mnt
|
||
|
|
||
|
# name of the initrd file to make
|
||
|
TARGET=/tmp/initrd
|
||
|
|
||
|
fail()
|
||
|
{
|
||
|
umount $MNT
|
||
|
rmdir $MNT
|
||
|
exit 1
|
||
|
}
|
||
|
trap fail SIGTERM SIGINT
|
||
|
|
||
|
strip_cp()
|
||
|
{
|
||
|
if [ -d $3 ] ; then
|
||
|
DEST=$3/`basename $2`
|
||
|
else
|
||
|
DEST=$3
|
||
|
fi
|
||
|
strip $1 --verbose -o $DEST $2 | sed -e 's/([^ ]*)//g' || fail
|
||
|
}
|
||
|
|
||
|
mkdir --verbose $MNT || exit 1
|
||
|
|
||
|
echo "Creating filesystem on $TARGET"
|
||
|
if [ -b $TARGET ] ; then
|
||
|
rm $TARGET || fail
|
||
|
fi
|
||
|
|
||
|
dd if=$ROOT/dev/zero of=$TARGET bs=1k count=$SIZE
|
||
|
echo "y" | mke2fs $TARGET $SIZE >/dev/null || fail
|
||
|
mount --verbose -t ext2 -o loop $TARGET $MNT || fail
|
||
|
|
||
|
|
||
|
rm -rf $MNT/lost+found
|
||
|
echo "Creating Directories on $TARGET"
|
||
|
for DIR in bin dev etc lib proc tmp mnt ; do
|
||
|
mkdir --verbose $MNT/$DIR || fail
|
||
|
done
|
||
|
for DIR in block misc fs net pcmcia ; do
|
||
|
mkdir --verbose $MNT/lib/$DIR || fail
|
||
|
done
|
||
|
|
||
|
echo "Copying Files to $TARGET"
|
||
|
for F in $DEV ; do
|
||
|
cp -a --verbose /$F $MNT/dev || fail
|
||
|
done
|
||
|
if [ -e /dev/systty ] ; then
|
||
|
cp -a --verbose /dev/systty $MNT/dev || fail
|
||
|
fi
|
||
|
|
||
|
for F in $BIN ; do
|
||
|
strip_cp --strip-all /$F $MNT/bin
|
||
|
done
|
||
|
strip_cp --strip-all /bin/ash $MNT/bin/sh
|
||
|
|
||
|
for F in $LIB ; do
|
||
|
strip_cp --strip-debug /$F $MNT/lib
|
||
|
done
|
||
|
cp --verbose /lib/ld-linux.so.? $MNT/lib || fail
|
||
|
|
||
|
for F in $ETC ; do
|
||
|
cp --verbose /$F $MNT/etc || fail
|
||
|
done
|
||
|
for F in scsi network ftl ide memory serial ; do
|
||
|
touch $MNT/etc/$F ; chmod +x $MNT/etc/$F
|
||
|
done
|
||
|
|
||
|
for MOD in $MODULES ; do
|
||
|
strip_cp --strip-debug $MODDIR/$MOD $MNT/lib/$MOD
|
||
|
done
|
||
|
|
||
|
strip_cp --strip-debug $MODDIR/$BLK $MNT/lib/block/ide-cs.o
|
||
|
|
||
|
echo "Creating linuxrc startup script"
|
||
|
cat > $MNT/linuxrc <<- 'EOF'
|
||
|
#!/bin/sh
|
||
|
|
||
|
mount -t proc /proc /proc
|
||
|
|
||
|
echo ""
|
||
|
echo "==== initrd: starting PCMCIA services ===="
|
||
|
echo ""
|
||
|
PC=/lib/pcmcia
|
||
|
insmod $PC/pcmcia_core.o
|
||
|
insmod $PC/yenta_socket.o
|
||
|
insmod $PC/ds.o
|
||
|
insmod /lib/block/ide-cs.o
|
||
|
if [ "$DEBUG" != "" ] ; then V=-v ; fi
|
||
|
cardmgr $V -q -o -c /etc -m /lib -s /tmp/stab -p /tmp/pid
|
||
|
umount /proc
|
||
|
echo ""
|
||
|
|
||
|
if [ "$DEBUG" != "" ] ; then
|
||
|
/bin/sh < /dev/console
|
||
|
fi
|
||
|
EOF
|
||
|
chmod +x $MNT/linuxrc
|
||
|
|
||
|
df -P $MNT | awk '/tmp/ { printf "%dK/%dK used\n",$3,$2 }'
|
||
|
umount $VERBOSE $MNT
|
||
|
rmdir $MNT
|
||
|
echo "Finished $TARGET"
|
||
|
echo "Now gzip $TARGET to create final initrd.gz"
|
||
|
exit 0
|
||
|
|
||
|
*************************** end mkcfinitrd ***********************************
|