Building OFW to Load from BIOS
This page tells how to build the x86 version of Open Firmware to boot under a conventional BIOS. These instructions specifically describe a configuration that is good for running on the QEMU and VirtualBox emulators, but very similar instructions can be used to make a version that runs on any PC. In this version, OFW is stored on a floppy disk image. The conventional BIOS boots it as if it were an operating system like DOS or Windows. OFW then "takes over" the machine, ignoring the conventional BIOS that booted it. That BIOS has already done the work of early-startup machine initialization - turning on the memory controller and configuring chipset-dependent registers.
In addition to this BIOS-loaded version, there are two other ways to run OFW under QEMU:
- You can build an OFW image that replaces the QEMU BIOS ROM image, entirely from code in the OFW tree - see Building OFW for QEMU.
- You can build an OFW image that replaces the QEMU BIOS ROM image, using OFW as a "payload" for Coreboot, so Coreboot does the early-startup stuff - see OFW as a Coreboot Payload.
- 1 Software Requirements
- 2 Getting Open Firmware Source
- 3 Building OFW
- 4 Making a bootable Floppy Image
- 5 Copying OFW onto the Floppy Image
- 6 Booting OFW from QEMU
- 7 Booting OFW from VirtualBox
- 8 Recompiling
- 9 What is on the Floppy Image
- 10 Making a Prototype Floppy Image with Linux Commands
- 11 Booting on a Real PC from a USB Key
- 12 Booting on a Real PC via GRUB or Etherboot
- qemu-0.9.1 or VirtualBox
- Open Firmware rev. >= 1053
- GCC and GNU make - most versions work for builing OFW
Getting Open Firmware Source
$ svn co svn://openfirmware.info/openfirmware
$ cd cpu/x86/pc/biosload/ $ cp config-virtualbox.fth config.fth $ cd build $ make floppyofw.img
The "config-virtualbox.fth" configuration is known to work with QEMU. Other configurations may work also - but the "qemu-loaded" config option isn't what you want for this technique, because it's a subcase of the CoreBoot-payload configuration.
You will use the "floppyofw.img" output file in a later step.
Making a bootable Floppy Image
$ ../../../Linux/forth fw.dic ../makefloppy.fth
This creates a file that is a bootable floppy image with an empty FAT12 filesystem. This step only has to be done once.
Copying OFW onto the Floppy Image
$ mkdir flp $ sudo mount -t msdos -o loop floppy.img flp $ sudo cp floppyofw.img flp/ofw.img $ sudo umount flp
Copy floppy.img to the QEMU or VirtualBox directory.
Booting OFW from QEMU
$ qemu -L <dir> -boot a -fda floppy.img
"<dir>" is the directory that contains QEMU's BIOS and VGA BIOS files.
Booting OFW from VirtualBox
The following VirtualBox configuration settings work for me:
OS Type = Other/Unknown Base Memory = 64 MB Video Memory = 8 MB Boot Order = Floppy, Hard Disk ACPI = Disabled IO APIC = Disabled VT-x/AMD-V = Disabled PAE/NX = Disabled Floppy Image = floppy.img Network Adapter 1 = PCnet-PCI II (host interface, <tap name>) (other settings are mostly irrelevant)
If you want to make changes and recompile OFW, you need not repeat the "makefloppy" step; you can just loopback mount the floppy image and copy the new OFW version to ofw.img .
What is on the Floppy Image
The floppy image is a bootable floppy with a FAT12 filesystem. Its first two sectors contain a simple bootloader program that uses BIOS INT 13 callbacks to read floppy sectors. The program scans the FAT root directory entries to find the file "ofw.img", then loads that into memory and jumps to it.
When you build floppyofw.img, as a side effect it also builds bootsec.img, which is that simple bootloader. The source code (Forth-style assembly language) is in biosload/bootsec.fth .
The "makefloppy.fth" program that creates the image is pretty simple; it copies bootsec.img to the output file "floppy.img", creates a couple of initially empty FAT tables, zeros the root directory area, and fills the data area with zeros.
Making a Prototype Floppy Image with Linux Commands
Here's a pair of Linux commands that accomplish the same thing as makefloppy.fth:
Step6a $ /sbin/mkdosfs -C -f 2 -F 12 -R 2 -r 224 -s 1 -S 512 floppy.img 1440 Step6b $ dd <bootsec.img of=floppy.img conv=nocreat,notrunc
The arguments to mkdosfs force the filesystem layout to match the layout that is specified in the BIOS parameter block in bootsec.img.
The advantage of makefloppy.fth is that it reads the filesystem layout parameters from the BPB in bootsec.img, so its guaranteed to be consistent. If bootsec.fth were edited to change the layout, the arguments to "mkdosfs" would have to change. (But there's little need to change that layout, since it's a standard floppy size.)
The advantage of the Linux command sequence is that it creates a file with "holes", thus saving disk space for awhile (until something fills in the holes).
Booting on a Real PC from a USB Key
To build for a real PC:
$ cd openfirmware/cpu/x86/biosload $ cp config-usbkey.fth config.fth $ cd build $ make
That will create a file named "ofw.c32" that can be booted from a USB key that has "syslinux" installed on it. http://www.911cd.net/forums//index.php?showtopic=21902 has some tips on how to install syslinux.
Your syslinux.cfg file needs a line that says:
Booting on a Real PC via GRUB or Etherboot
You can make a version in "Multiboot" format that you can boot with GRUB:
$ cd openfirmware/cpu/x86/biosload $ cp config-grub.fth config.fth $ cd build $ make
The output file is "ofwgrub.elf". Copy that in to /boot on your GRUB-enabled disk and add this to /boot/grub/menu.lst:
title Open Firmware kernel /boot/ofwgrub.elf
That version can also be booted via Etherboot. Here's an example of how to Etherboot it with QEMU (assuming that the ofwgrub.elf file is in /tmp on the host machine):
qemu -L . -boot n -tftp /tmp -bootp /ofwgrub.elf