Re: Question before buying hardware

-- Richard A. Smith rsmith@bitworks.com LinuxBIOS FAQ/HOWTO Ver 0.0.3 Last Modified: 5/21/2003 Richard A. Smith Credits. Various portions of this document were derived from posts on the linuxBIOS mailing list. I neglected to keep who said what in a lot of cases. My apologies to those people. Let me know if you want credit for what you wrote and I'll add it in. Context. Although LinuxBIOS has been ported to other architectures such as the PowerPC almost all the info in this FAQ/HOWTO is specific to the x86 architecture. 1. General Questions Where is the linuxBIOS webpage? http://www.linuxbios.org What kind of coding skills are necessary to work with LinuxBIOS? You better be comfortable with assembly language as LinuxBIOS has a lot of it. LinuxBIOS switches to protected mode and a C enviroment as soon as it can but there is a lot of hardware init that has to happen first. Most of this happens in assembly _WITHOUT_ a stack! Very tedious to debug. Grokking the SDRAM init process is a very humbleing experience. DDR is said to be worse. Strong C skills are also a plus as most of LinuxBIOS and friends is/are written in C. You should also not be afraid of digging hip deep in chipset datasheets and attempting to mind read what the chipset designers were really trying to say when they wrote the documentation. Sometimes its less than clear. LinuxBIOS is a _very_ hands-on-study-the-code type project. 'grep -r' is your friend. Especially when attempting to figure out what all the config options do. What kind of hardware do I need? A motherboard (or mainboard as LinuxBIOS calls it) that has a supported chipset on it. Ok.. Well not exactly. As long as you have the documentation for the chipset/mainboard and its free of any NDA issues you can use an unsupported chipset/Mainboard but you have a twisty road ahead of you. And of course you need a Linux developemnet machine. The LinuxBIOS build enviroment is not supported on Windows. Here's a list of the currently supported chipsets/Mainboards http://www.linuxbios.org/status/index.html It's also handy to have one/some/all of the following: - EPROM/Flash programmer that can program the flash on your motherboard. - ROM emulator - Bios Savior http://www.ioss.com.tw/web/English/RD1BIOSSavior.html http://www.cwlinux.com/eng/products/products_lbmb.php - Compact Flash IDE adaptor http://www.cwlinux.com/eng/products/products_ide2cf.php <Need some more links to CF adapters> - Oscilliscope - In Circuit Emulator hardware debugger - LinuxBIOS SDK http://www.cwlinux.com/eng/products/products_sdk.php How can I tell if my motherboard/chipset is supported by LinuxBIOS? There are 2 methods: 1) Check http://www.linuxbios.org/status/index.html If you don't see your chipset/Mainboard listed there then boot linux on your target and send the output of 'lspci -vvv' to the linuxBIOS list asking if this chipset is supported. 2) "Use the source Luke" Check out the latest copy of LinuxBios from CVS (instructions are on the webpage) and look in the freebios/src/mainboard directory. [The LinuxBios module is called 'freebios' in CVS for legacy reasons] There are directories for each manufacturer of mainboards that LinuxBIOS supports. Below the manufacturer directory is a directory for each mainboard or family of mainboard. If a directory for your mainboad dosen't exist then theres a good chance LinuxBIOS dosen't support your mainboard out-of-the-box. Posting to the list would probally be the next option. See 'the lspci -vvv' in the earlier part of the question. If the directory does exist then it still dosen't mean 100% the mainboard will work but at least it probally worked at one time. Posting to the list will probally get you the latest info for that mainboard. What documentation do I need? As much as you can possibly get a hold of. Minimum you need the docs for your chipset. Without chipset docs you are basically lost. There have been some reports of people making things work by popping in the BIOS that comes with the board. Dumping the PCI config registers and then making LinuxBIOS match those registers. But since sometimes you have to set different bits in a given register at different times it can be a vere long and involved process. The following items will also be of some use: IA-32 Intel Architecture Software Developer’s Manual Volume 3, System Programming Guide <What are some other good reference docs?> What documentation for linuxBIOS exists? You got the source. What more do you need? *grin* Unfortunaly there is very little documentation for linuxBIOS right now and what docs there are tend to be stale. "Use the source Luke". One thing to note is that LinuxBIOS has reached a stage where a good bit of newer users are coming on-line and thus the signal-to-noise level of the mailing list is beginning to decrease. The mailing list archives have *TONS* of good information in them I would say its required reading. Start at the beginning of the year or at least 3 to 4 months ago and read the various questions/responses. Chances are you will find serveral references to a setup similar to yours. Once you have gone through the mailing list navigating the LinuxBIOS code and dealing with the many config options will be much eaiser. What hardware vendors support LinuxBIOS? - SIS actively supports LinuxBIOS developement. http://www.sis.com/ - CWLinux makes various helpful LinuxBIOS stuff and also sells SBC with linuxBIOS pre-installed. http://www.cwlinux.com/eng/products/ <Who else is linux bios friendly?> I don't have an EPROM/FLASH programmer. What are my options? For a mainboard with a flash thats socketed or has a flash recovery setup. Its possible to work with linuxBIOS without a EPROM/Flash programmer. Personally I don't recommend it. Especially if your Flash is soldered onto the mainboard. Screw that up and the Mainboard is toast. Some motherboards have a flash recovery method that you can set for when you munge the flash. This enables a known good BIOS boot image that will allow you to recover when you screw up. The BIOS savior also works similar to this. It allows you to have 2 different BIOS images and choose the one you want to boot from. Which different operating systems will LinuxBIOS boot? - Linux (of course) - Windows 2000 (via ADLO) <Someone please fill the rest of this in> What payloads can/has linuxBIOS boot/booted? Linux Kernel regular - use as your OS kernel Linux Kernel Kexec bootloader - boots another linux kernel from a device supported by linux (I don't know where this payload stands as a formal package) Memtest86 - great memory tester Plan9 - Plan9 OS 9load ADLO + Bochs BIOS - Interrupt support, boots BSDs and Win2k Etherboot standard - kernel over ethernet Etherboot devel branch - kernel over ethernet and raw disk i/o Etherboot 5.0.6 polled ide patch - kernel over ethernet and buggy file system support Etherboot SIS patch - kernel over ethernet, file system support, and booting WinCE I think (but I don't know if SIS has let this out formally) RedBoot - could read the file system but never had the elf support to make it really usefull Steven James ELF finder - I think this was written as payload? Anyway, it lets you choose from payloads in your rom. Bare Metal Toolkit???? My cvs checkout failed. Whats up? Error: cvs [checkout aborted]: could not chdir to freebios/src/arch/alpha/config: Not a directory Issue: Chances are that you are attempting to use a filesystem that is not case sensitive. i.e. under cygwin. This won't work as several of the directories have both a directory called 'config' and a file called 'Config'. You must use a filesystem that is case sensitive. What is ADLO? See the following url: http://www.missl.cs.umd.edu/Projects/sebos/phase2.shtml But basically its the glue which bonds LinuxBIOS to the PC BIOS of the Bochs project. It allows you to boot some OS's that depend on legacy BIOS services. What bios services does ADLO provide and when would I need them. The full gory details are at: http://www.missl.cs.umd.edu/Projects/sebos/winint/index2.html How do I get LinuxBIOS to boot ADLO? ADLO compiles as an ELF image so you have to set up LinuxBIOS to elf boot just as if you were using etherboot. Go read the etherboot IDE section of this faq and get to where you can boot etherboot. ADLO is distributed with LinuxBIOS in the freebios/util/ADLO directory. Int that directory are some README's. Make sure you have read them. Compiling ADLO is quite simple. Mostly you just type 'make' You need a copy of your video BIOS if you want VGA to work. Again see the README. Out-of-the box ADLO probally won't boot unless you are using the exact mainboard that the ADLO project uses. The reason is that various areas of shadowing must be enabled for ADLO to boot. If you see elfboot indicate that its 'Jumping to boot code at 0x7c00' and then the board resets or hangs then its very likely that your shadow settings are incorrect. Applying the serial debug patch to ADLO can help you further investigate this. <Where is the defacto location for the serial patch? > The shadow settings are set in loader.s in the freebios/util/ADLO. Find section B) These are writes to PCI space that enable various areas of shadowing. Technically all you need is the only 64kb at 0xF0000 and 64kb at 0xC0000. Your mileage may vary. I would start by enabling Read/Write for all shadow ranges supported by your chipset and then backing off to 0xF0000 and 0xC0000 after you get it working. The ADLO makefile will copy your video bios from an existing setup. See the README and makefile for details. If you have one of the BIOS kits provided by the video chipset mfg for your board then you may have a stock image an then a program that allows you to customize the stock image. If so then you need to set things up so that the video bios is set to be loaded at 0x0C0000 (sometimes called the C000 segment) Also I found that ADLO expected the video bios to be 64k in size whereas my image file was only 32k. I solved this by just copying it twice in the same file and then letting ADLO use that. Some creative work with 'dd' would probally achieve the same result. Lastly if you have applied the serial debug patch to BOCHS then _all_ the output is routed out to the serial port so your video screen will be blank. However VSYNC will still be generated if the video chip is initialized properly. You can watch for VSYNC with a Oscope or plug a newer type monitor up to the video output. Most modern monitors will tell you when they can/can't find the VSYNC signal. Note you may have to power cycle the monitor between attempts as sometimes they can get very confused. If I burn ADLO along with linuxbios on rom do we need to specify BOOT_IDE=1? Nope. BOOT_IDE is merely to use the ide support thats directly in LinuxBIOS, in which case it would skip right over ADLO. My kernel won't fit in ROM so how do I boot? If you aren't blessed with a 8Mbit or larger flash there are a few other options. - Load from the net via etherboot - Load from IDE via etherboot - Load from IDE via ADLO - Load from Msystems Disk on Chip (DoC) How do I load a kernel from IDE? Currently there are 3 different methods. 1. Etherboot 5.0.6 with polled ide patch: Download etherboot-5.0.6 and see http://www.missl.cs.umd.edu/~agnew/ for the patch. 2. Etherboot development series: Download >= etherboot-5.1.7 3. ADLO see freebios/utils/ADLO/ from the linuxbios cvs. (this one is the most work, but wont require you to modify your kernel when you're done) How do I make LB use etherboot IDE? First you need to go get etherboot and compile it. You either get the developement branch with IDE support or the stable branch which need a patch to work. Now modify the etherboot config file so that its compatible with LB. Specifically the ./src/Config file and the arch/<your arch>/Config file Instructions for Ver 5.1.8 ========================== The options you need to make sure are set are: -DELF_IMAGE -DLINUXBIOS -DCONFIG_TSC_CURRTICKS -DCONFIG_PCI_DIRECT there are other options that are helpful like -DCONSOLE_SERIAL - DCOMCONSOLE=xxx The option(s) you need to make sure it NOT set are: -DPCBIOS Then compile etherboot. You want to compile with a specific make command so that it generates the elfimage for LB to load. This is done by taggin the .zelf on to your normal makefile command. For example to make the polling IDE loader elf image you need: make bin/ide_disk.zelf Now modify your linuxbios config file to include: option USE_ELF_BOOT=1 option PAYLOAD_SIZE=<size of you etherboot payload> payload /path/to/your/etherboot/driver A quick note about PAYLOAD_SIZE. This parameter does not specifiy the exact size of the image but rather its fed to the bs=<size> option of 'dd'. This along with the 'sync' option causes dd to only output files that are a mutiple of the bs= size. So if you specify bs=32768 but your input filesize is 40000 you will end up with a output file thats 65536. So far I have just kept PAYLOAD_SIZE at 32768 and then go back and adjust ROM_SIZE such that the final image size is the size of my ROM part. You also need an input stream for the elfboot code to read from so you must set one (or more?) of the following options. USE_GENERIC_ROM=1 <What are all the other stream options?> Now you need to create an elf kernel for the ether boot code to find. Go fetch the mkelfimage command at ftp://ftp.lnxi.com/pub/src/mkelfImage/ Generally the latest one is better. Note that there are several older versions of binutils that are broken and mkelfimage will expose those bugs. Insure that you are running a recient copy of binutils. The following shows the version output from a known working bintuils. # as --version GNU assembler 2.13.90.0.10 20021010 Debian GNU/Linux Now compile mkelfimage. Which should be as easy as ./configure, make, make install You can now create a elf kernel. Change to the directory where the image file for you kernel is. Normally this is somewhere in the kernel tree. In my case this is is arch/i386/boot and the kernel image is bzImage. By defaut mkelfimage is installed in /usr/local/sbin so you would do /usr/local/sbin/mkelfimage bzImage elfimage Now you have your kernel elfized in the file 'elfimage' mkelfimage support several options for adding commandlines and initrd's to the kernel image type 'mkelfimage' without any arguments for the details. Ok final setp. Locate the kernel on the IDE device. Etherboot currently searchs the first 8k of disk space for the elf header. So you have to locate the start of that kernel within that space. If you don't care about having a proper partition table on your disk then you can just splat the kernel at the front of the disk. For the rest of the examples lets assume your disk is mounted in your *developement* machine as /dev/hde The following will write the kernel at the beginning of the IDE device. # cat elfimage > /dev/hde This works well if you don't need the IDE device for anything other than booting. If you want a filesystem on the device as well then you are going to have to protect the partition table as well. Currently the hack for accomplishing this is dd if=elfimage of=/dev/hde bs=4096 seek=1 This will skip over the partition table and write the data in the area where the first partition would normally be. So you have to create a disk with at least 2 partitions. /dev/hde1 should be large enough to hold your kernel plus any initrd you may want. You can then put your filesystem on /dev/hde2 Note. It appears that in some setups dd may whine about /dev/hde being an "Invalid argument" but it appears to write the data to the disk anyway. Somebody mentioned that it was a "buffer size" mismatch with dd and ext3 but nothing definitive was ever posted. If you receive this and solve the issue please report it. Instructions For Ver 5.0.x: =========================== <Someone needs to fill in the info for the earlier version> What do those IDE options mean? See IDE section in Appendix A. How do I make the prephials work on a National SCx2xx under linuxBIOS? The SCx2xx series have this feature where binary-only code gets executed in SMM (System Management Mode) when you (or kernel drivers) access certain addresses. It's called VSA, Virtual System Architecture. There's also VSA2 which adds something. NSC supplies some binary VSMs (Virtual System Modules) with their royalty free BIOS kit BLDT (BootLoader Development Toolkit), aka XpressLOADER. Among others, there are VSMs for enabling audio and video. LinuxBIOS does not currently implement VSA or VSA2. I see no reason why it couldn't, though, I even think it could be made as a separate ELF object loaded in the same way the bare bones toolkit is, I seem to remember the idea of being able to plug multiple ELF objects into the bootup sequence but this still requires some twiddling, right? NSC offers documentation on VSA/VSA2 but I'm not sure about availability.. NSC also offer a Linux audio driver for the SCx2xx family but this driver requires the XpressAUDIO VSM to work. Help! I'm a newbie and I'm completely lost in the code. There seem to be two main parts to linuxbios. The first is arch/{arch}/config/ctr0.base which does the very low level initialization, like turning on memory, etc. The second is arch/{arch}/lib/c_start.S which does whatever else is necessary to call the C function hardwaremain(). hardwaremain() then does whatever else is necessary to load linux. c_start.S is linked with linuxbios.a, a library containing generic support routines (those found in the lib directory) and anything specified using the 'object' directive in a Config file (and other stuff). The resultant 'executable' is called linuxbios_c. The loader script used to link linuxbios_c is config/linuxbios_c.ld, and is configured to be loaded relative to _RAMBASE. crt0.base is not linked against anything. Any additional assembly routines you need must be specified using the 'mainboardinit' directive in a Config file. This causes the specified assembly file to be added to "crt0_includes.h" which is in turn included at the start of crt0.base (or at the end in the case of the ppc version). The loader script used to link crt0.base is in arch/{arch}/config/ldscript.base. The resultant 'executable' is called linuxbios and will be loaded at _ROMBASE. The tricky thing is that this loader script will also load the linuxbios_c 'executable' at a location called _payload in this file. The main task of crt0.base is then to initialize enough hardware so that this payload can be copied from rom into ram (which may also involve uncompressing code). Then control is transferred to _start, which is the first location in linuxbios_c. To get an idea of how crt0.base works, look at the following files. This is the order of execution specified by the configuration file for sis735. cpu/i386/entry16.inc cpu/i386/entry32.inc superio/sis/950/setup_serial.inc pc80/serial.inc arch/i386/lib/console.inc cpu/k7/earlymtrr.inc northsouthbridge/sis/735/raminit.inc arch/i386/config/crt0.base Next look at c_start.S which will show you what happens once control is transferred to _start. Finally, look at arch/{arch}/lib/hardwaremain.c to see what other stuff is done to get linux loaded. Most other files are specific to particular hardware, so it can be pretty confusing to just browse the tree. I don't understand the x86 boot mechanism. Steve James writes: The confusion is that there are multiple stages to LinuxBIOS. All x86 machines start at 0xf000:fff0 in real mode. The flash itself lives at the top of the 4GB address space and the chipset arranges for an alias at the top of the 1MB real mode address space. The instruction at that start address will be a jmp to the assembly language initialization code. Once the memory is set up, the next stage is copied from rom (possibly with decompression) to 0x80000 which includes _start. That code consists of a little assembly language (equivilant to crt0 in a normal C application) followed by the bulk of LinuxBIOS which is compiled from C. That code is entered at hardwaremain. Further clarified by Steve Gehlbach: To be strictly correct, x86 machines start at 0xfffffff0 in real mode. ( IA- 32 Intel Architecture Software Developer’s Manual Volume 3, System Programming Guide, sect. 9.1.4.). Quoting the manual, for those that don't have it handy: ------ "The first instruction that is fetched and executed following a hardware reset is located at physical address FFFFFFF0H. This address is 16 bytes below the processor’s uppermost physical address. The EPROM containing the software- initialization code must be located at this address The address FFFFFFF0H is beyond the 1-MByte addressable range of the processor while in real-address mode. The processor is initialized to this starting address as follows. The CS register has two parts: the visible segment selector part and the hidden base address part. In real-address mode, the base address is normally formed by shifting the 16-bit segment selector value 4 bits to the left to produce a 20-bit base address. However, during a hardware reset, the segment selector in the CS register is loaded with F000H and the base address is loaded with FFFF0000H. The starting address is thus formed by adding the base address to the value in the EIP register (that is, FFFF0000 + FFF0H = FFFFFFF0H). The first time the CS register is loaded with a new value after a hardware reset, the processor will follow the normal rule for address translation in real-address mode (that is, [CS base address = CS segment selector * 16]). To insure that the base address in the CS register remains unchanged until the EPROM based software-initialization code is completed, the code must not contain a far jump or far call or allow an interrupt to occur (which would cause the CS selector value to be changed)." ------ If the biosbase option is not set, almost immediately, linuxbios does a far jump to 0xf0000:0004, and so reloads the segment register such that the aliasing of this address to the top 4G becomes important, as Steven James points out. But setting biosbase=0xffff0000 will use a relative jump and actually execute physically in the top 4G. Whats a GDT? Steve Gehlbach writes: The gdt is one of a number of registers in the IA-32 model used for protected mode memory management (ie, for 32-bit mode). Typically, it is loaded to point to a data structure that defines a flat (ie, 4 GB) data segment, and an identical code segment, although you can in reality have many segments defined. These segments are referenced by their offset into the gdt data structure, for example in linux startup, 0x18 defines the data segment, and you would put this into the %ds register. This means the segment is defined 24 bytes into the gdt table. This is very different, of course, from how you use the %ds in real or 16-bit mode. Originally in linuxbios, the gdt was defined in flash, and not changed until jumping to linux. However, linux will hang if the gdt is located above 1M (not sure why, but I have tested this many times). So if you setup biosbase=0xffff0000, this would put the gdt high, and it has to be loaded low so linux will work. However, recently, Eric setup a gdt reload in c_start.S, which is relocated into ram below 1M, and so this will work fine for linux. This makes some gdt reload code I put into the sis630 area unnecessary. But the bottom line is you have to setup the gdt to point to a compatible (read that identical) gdt table to linux, before jumping to linux. Linux expects to be in 32-bit mode with the gdt data structure a certain way. You can see it at the bottom of linux/arch/i386/boot/setup.S in the kernel source tree. Anytime you go into protected mode, you have to setup the gdt, and usually also the idt, which handles interrupts. You can find more that you would ever want to know about it in the Intel reference manuals, but most folks just copy the table data from someone else. It is very painful code to debug, many bytes of the entries in the table requiring bit by bit settings. What do I need to get started with linuxbios on a new motherboard ? First do a 'lspci' on that motherboard and determine what chipset is being used. Then search through the LinuxBIOS src/mainboard tree and see if any motherboards that are already supported are close to the chipset you have. If there isn't a good match then you will have to go aquire all the datasheets for the chipset used on that motherboard. Depending on the NDA stance of the manufacurer this may or may not be an easy task. Once you have all the technical data for the motherboard in question you create a directory(s) below the src/mainboard directory with the mfg and boardname of your motherboard. ie. if you have the 'superfoo5' motherboard made by Fooboards, Inc. you would create the following directory. src/mainboard/fooboards/superfoo5 Then if you found a motherboard that was close you can copy in all the files from that motherboard. Otherwise you start from scratch in which case you should use some of the other motherboards setups as templates and rework them to your needs. [Perhaps we need to setup a blank template directory just for this purpose?] Is there a reference for all the options in the config file? While no defacto reference exists beyond the source code I've collected as much as I can from gleaning the mailing list and my own experience with the code. See appendix A for that reference. How do I use the "new superio"/nsuperio interface. In light of the fact that some mainboards can have mutiple superIO's with different functions enabled on different chips a slightly more flexable superio interface had to be established. This is the nsuperio or "new superio" setup. Basiclly it allows you to define multiple superio's, the address they are at, and what functions to enable on that superio. The basic structure of the nsuperio command is: nsuperio <mfg>/<chipname> <cmd>=<value> You would have one of these lines for each superio on your mainboard that you wanted linuxbios to initialize. an example would be the Bitworks ims board which has a Nationl Semiconducior pc87351 superio on it. nsuperio NSC/pc87351 keyboard=1 com1={1} com2={1} floppy=0 lpt=0 looking at this in detail: 'nsuperio NSC/pc87351' tells the config generator to use the new superio interface and to use the config file in the freebios/src/superio/NSC/pc87351 directory. This will auto define the USE_NEW_SUPERIO_INTERFACE config option. The <cmd>=<value> options that follow set the enables and config info for all the differnet types of devices found in a superio. If the <value> section is surrounded by {} its because that particular command is a sub structure. In the serial device example you can also set the base address, IRQ value, default baud rate, etc See the pci.h file for the gory details of what you can and can't set. In this example the keyboard, com1, com2 are all enabled and the floppy and lpt port are disabled. The com port base address, and irq values are left to the defaults that are defined in freebios/src/superio/NSC/pc87351/superio.c Troubleshooting The board resets when it trys to jump to the loaded ELF image. So your serial log looks something like this? calling elf load... New segment addr 0x94000 size 0x8128 offset 0x60 filesize 0x38d4 (cleaned up) New segment addr 0x94000 size 0x8128 offset 0x60 filesize 0x38d4 Loading Segment: addr: 0x0000000000094000 memsz: 0x0000000000008128 filesz: 0x00000000000038d4 Clearing Segment: addr: 0x00000000000978d4 memsz: 0x0000000000004854 Jumping to boot code at 0x94000 LinuxBIOS-1.0.0 Thu May 1 04:29:36 IST 2003 starting... Ram1 This normally indicates a RAM setup problem. What's happening is that the code is jumping to instructions that aren't really there. The CPU evently triple faults and resets. Thus taking you back to the startup of linuxBIOS. My keyboard dosen't appear to work. Any suggestions? Did you set option NO_KEYBOARD=0? Next double, triple check that its really enabled. Some chipsets have mulitple places where you have to enable port 60 and 64. Don't forget to check your SuperIO chip as well since if thats where the keyboard IRQ comes from you will need to have it enabled as well. Appendix A. These are various options that I either ran across while I was working with LinuxBIOS or that I saw posted to the list. Code location options. Key: <bool> 1 or 0 1=active 0=inactive <address> hex address. ie 0x0ffff or 0xffff0000 include the '0x' prefix <n> decimal number ie 2 or 5, etc <hexval> hex number ie. 0x0000ffff option BIOSBASE=<address> default = 0xf0000 I believe this region is automatically cached by linuxbios (maybe not?). If biosbase is set to 0xffff0000, then in your config you need to set: option XIP_ROM_SIZE= 0x01000000 default = ? option XIP_ROM_BASE= <address> default = ? This will cache the upper 16M of the 4G address space. Basically, the chipsets generally map both to the same physical memory, the flash, ie, they aliasing 0xf0000 to 0xffff0000. You can cover 0xf0000 with ram, by setting proper bits in the bridge, but not 0xffff0000. But on startup by default most if not all chipsets alias the top 64k under 1M to the top 64k under 4G. It all has to do with legacy, real-mode stuff. linuxbios is in 32-bit mode, though, after a few initial instructions. Peripheral Options option NO_KEYBOARD default = 1 Controls the linking and calling of the legacy keyboard enable code and ports 60 & 64. The keyboard_on() either calls the chipset specific and generic keyboard code or it does nothing. If your target has a keyboard port and you want it to work then you must set this to NO_KEYBOARD=0 IDE Options option BOOT_IDE=<bool> default = 0 This enables booting from IDE, the file to use is linux.bin.gz: More specifically it controls the compile and linking in of freebios/src/rom/ide_fill_inbuff.o option IDE_BOOT_DRIVE=<n> default = 0 If you do not use drive 0 (default), then you can set which drive to boot; (0,1,2,3) are the four standard PC drives: option ONE_TRACK=<n> default = 63 The linux.bin.gz file is put in raw form at partition 1, ie, the first partition on the disk. This is located just past the partition table. The partition table size varies, it is "one track" from the beginning of the disk. "one track" in c/h/s notation is "s" or the number of sectors per track. ONE_TRACK is in sectors, the software multiplies by 512. Most disks are 63 sectors per track (the default), but my CF is 32 sectors per track. eg, the partion table is 63x512 or 32x512 bytes. You can partition your disk as you want, but linux goes raw in partition 1; just make sure partition 1 is big enough, not a problem on today's disks. You could put the linux root file system on partition 2, for example. In pcchips787.config, I put the linux root file system on IDE 0, partition 2 (I was experimenting with linux in partition 1), but I eventually put linux on drive 2 using CF. You are right, copying of linux.bin.gz raw to the partition is dangerous, and something like "cat linux.bin.gz > /dev/hda1" will definitely screw the disk if you put the wrong disk or partition. I recommend a shell script, fingers cannot be trusted. You can also use "dd" but "cat" works. option STD_FLASH=<bool> default = ? In the sis northsouthbridge ipl.S code this controls some settings. <sis person please fill in more detail> option ZKERNEL_START=<address> default = 0xfff00000 The address where the kernel is located in the ROM. Data at this address is copied to the RAM destination address. option ZKERNEL_MASK=<hexval> default = 0x0000ffff <someone please explain this in more detail> Boot options. option ROM_SIZE=<n> default = ? Controls the size of the LinuxBIOS rom file. The actual LinuxBIOS code is seldom larger than 64k but it ususally goes into a ROM part thats much larger. This sets the size of the final LinuxBIOS rom file size with the actuall LinuxBIOS code justified to the top of the image. option USE_GENERIC_ROM=<bool> default = ? Controls the linking in of freebios/src/rom/rom_fill_inbuf.c <someone please explain this in more detail> option USE_ELF_BOOT=<bool> default = 0 Controls the building and linking of the elf image boot code. option PAYLOAD_SIZE = <n> default = ? Sets the size of the elf payload that is added to the LB rom image. A quick note about PAYLOAD_SIZE. This parameter does not specifiy the exact size of the image but rather its fed to the bs=<size> option of 'dd'. This along with the 'sync' option causes dd to only output files that are a mutiple of the bs= size. So if you specify bs=32768 but your input filesize is 40000 you will end up with a output file thats 65536. So far I have just kept PAYLOAD_SIZE at 32768 and then go back and adjust ROM_SIZE such that the final image size is the size of my ROM part. Logging options option DEFAULT_CONSOLE_LOGLEVEL default = 8 Sets the default for the ammount of verbosity LB uses to tell you whats happining. Default is for printk_debug. Increasing this to >=9 enables printk_spew which is currently the most verbosity avaliable. Note you have to increase MAXIMUM_CONSOLE_LOGLEVEL as well to get to level 9 option MAXIMUM_CONSOLE_LOGLEVEL default = 8 Max value of loglevel. If DEFAULT_CONSOLE_LOGLEVEL is higher than this it gets set to this value.