The wiki is being retired!
Documentation is now handled by the same processes we use for code: Add something to the Documentation/ directory in the coreboot repo, and it will be rendered to https://doc.coreboot.org/. Contributions welcome!
Before starting to work on coreboot support for a new mainboard and/or chipset you'll want a few development tools (both hardware and software). Not all of them are strictly required, a lot depends on your specific task and needs.
- 1 Basic requirements
- 2 PLAICE: Programmer, Logic Analyzer and In-Circuit Emulator
- 3 Artecgroup programmable LPC dongle
- 4 PC Engines lpc1A
- 5 External EPROM/Flash programmer that can program the flash chip on your motherboard
- 6 BIOS Savior
- 7 Top Hat Flash
- 8 Chip removal tools
- 9 POST card
- 10 Null-modem cable
- 11 Compact Flash IDE adaptor
- 12 Oscilloscope
- 13 In Circuit Emulator hardware debugger
- 14 coreboot SDK
- 15 In Circuit chip programmer
- 16 EPROM emulators
- 17 USB debug devices
- 18 Serial console software
- A mainboard you want to port coreboot to.
- A Linux/UNIX machine for development purposes
- The coreboot build environment is not well-supported on Windows. It may be possible to do it under cygwin but nobody has tried.
It's also handy to have one/some/all of the following:
PLAICE: Programmer, Logic Analyzer and In-Circuit Emulator
The PLAICE is a powerful in circuit development tool that combines the features of programming and emulating FLASH devices as well as high speed multi-channel logic analysis into one device.
The FLASH BIOS emulator feature will help speed development of coreboot porting since the developer will no longer have to wait for either swapping FLASH devices or for lengthy FLASH programming cycles.
The design will also perform as a multi-channel logic analyzer with a JAVA client.
The PLAICE will make use of an adapter cable that will interface to the mainboard via the FLASH BIOS socket or onto the pins of a soldered in place FLASH device. It may also be used to program a FLASH device or emulate a FLASH device in circuit. Since the PLAICE attaches directly to the in-circuit FLASH device, the FLASH may be programmed without the need to reverse engineer any FLASH WRITE/ENABLE "security through obscurity" protection schemes incorporated into a mainboard.
Artecgroup programmable LPC dongle
PC Engines lpc1A
This board is most useful if you are working on machines from the ALIX family, but could also be useful if you can expose an LPC header on another board.
External EPROM/Flash programmer that can program the flash chip on your motherboard
External programmers are not always necessary. Use your mainboard as a programmer instead. Boot up with a known-good image, then unplug the (DIP32, PLCC32, or DIP8) ROM chip while powered on. Reflash that secondary piece and try a reboot. Many boards allow for more than one type of flash to be programmed, but clearly are less versatile than real programmers.
- GALEP-4: Has beta Linux drivers ~$300. See Galep IV for a description on how to get the more modern Windows software working in Linux with wine.
The BIOS Savior is a tool that plugs into and replaces the original mainboard Flash device. The BIOS Savior has its own Flash device and a socket for the original mainboard Flash device (PLCC or DIP versions are available). It features a switch to allow the developer to choose between which Flash device is accessed by the mainboard during read and write cycles.
This device helps to minimize the amount of hot swapping required and reduces mechanical and electrical stress on the BIOS chips.
The BIOS Savior is available from:
Top Hat Flash
A similar function is achieved by the "top hat flash" which comes at no extra cost with many Elitegroup, and some Gigabyte and Albatron mainboards like ECS KN3 SLI2 Extreme with MCP55 southbridge (which is getting severely out of stock around central europe as of 8/2007 unfortunately). After bootup, it can manually be lifted off the original BIOS chip, so the original BIOS can be reflashed after a failure. /rst is wired to /oe on the spare chip otherwise 1:1. Top hat flash is equipped with a Winbond W39V040AP FWH. It may rely on particular circuitry on the mainboard to operate.
Chip removal tools
If you're hot-swapping your BIOS chips (i.e., removing the chip while your computer is running, then inserting another one) you'll usually need some tools.
There are different tools for DIP and PLCC chips (see photos). You can find them in most electronics stores, usually. Both types cost roughly 5-10 Euros.
Another very nifty idea is clipping off the needle point of normal office push pins, and then attaching them to (PLCC) ROM chips with super glue. That makes it pretty easy to insert and remove the ROM chips without extra tools.
Since after bootup, flash mem is not accessed anymore, you can even hot plug (plug in and out while PC powered on) push pin flashes. This way you save an external EEPROM programmer and mimic the procedure of top hat flash. Make sure you do not short circuit anything, though.
A POST card will save your life: it's the only output device (beside beeper) you have during the boot process. The term POST means Power On Self Test and comes from the original IBM specifications for the BIOS. Port 80 is a pre-defined I/O port to which programs can output a byte. The POST card displays the byte in hex on its 2 digit display. We use a lot of POST codes in coreboot, so if you can tell us the POST code you see, we will have some idea of what happened.
If your coreboot machine is working properly, you will see it count up from 0xd0 to 0xd9 (while it is gunzipping the kernel) and then display 0x98 (Linux idle loop). There are POST cards with ISA bus, PCI bus, USB und parallel port connectors (the latter for laptops).
Often they carry status LEDs for ISA/PCI signals such as: IRDY, BIOS-access, FRAME, OSC, PCI-CLK, RESET, 12V, -12V, 5V, -5V, 3.3V. Some cards were known to not function because the mainboard switches off the CLK on their slot after non-standard registration on PCI.
PCI POST cards can be found in various places.
A so-called null-modem cable is used for transmitting the output from a serial coreboot (or GRUB- or Linux-) console to another computer where a terminal program (such as minicom) can be used to display/save the messages.
Compact Flash IDE adaptor
Solid state disks (e.g. CompactFlash cards) save time during the repeated boot process compared with regular hard disks.
- http://www.hsc-us.com/industrial/adapter/ATP.html (2xCF, one with hotswap!)
- http://www.mesanet.com/ (Choose DISK EMULATORS then CFADPTHD in the menu. 2xCF)
For hardware debugging purposes when it goes down the most atomic details. Consider logic analyzers as alternative.
In Circuit Emulator hardware debugger
Allows very time-saving burn/debug cycles with added tracing capabilities but somewhat costly.
In Circuit chip programmer
Should allow you to program your BIOS even if it is soldered to the motherboard.
These hardware devices pretend to be an EEPROM chip.
- http://www.linuxselfhelp.com/HOWTO/Diskless-HOWTO-10.html (a larger list -- outdated)
USB debug devices
An alternative to a serial console may be a USB debug device. They are not so common, yet. Their advantage is higher speed than a serial console. One might hook an FPGA to it for profiling purposes or some automated checks. Accessing a USB debug device from within BIOS is not different than other USB devices, and is part of the USB standard.
See also EHCI Debug Port.
Serial console software
Minicom is not just a serial terminal. It was written long before the internet existed and electronic communication was only possible with a modem to a mailbox-computer. Minicom is written with the ncurses library and provides its magic via a text interface. Other than logging, it provides z-modem up- and download-capability.
This is an easy to use serial-terminal-program which is even able to write all communication into a log-file. It needs a computer with installed Qt-libs.