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lc-coreboot/x230/README.md

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coreboot-x230

pre-built coreboot image and documentation on how to flash them for the Thinkpad X230. SeaBIOS is used, to be compatible with Windows and Linux, and to be easy to use: simply a boot menu and a few options to tick.

seabios_bootmenu

We want to make it easy to "bootstrap" an X230 to a working, unlocked, up-to-date coreboot-based BIOS.

Latest release (config overview and version info)

coreboot

  • We simply take coreboot's current state in it's master branch at the time we build a release image. That's the preferred way to use coreboot. The git revision we use is always included in the release.

Intel microcode

SeaBIOS

  • version 1.11.1 from 2018-03-19 (part of coreboot upstream)

table of contents

TL;DR

For first-time flashing, remove the keyboard and palmrest, and (using a Raspberry Pi with a SPI 8-pin chip clip connected), run flashrom_rpi_bottom_unlock.sh on the lower chip and flashrom_rpi_top_write.sh on the top chip of the two.

For updating later, run prepare_internal_flashing.sh to get files and instructions about updating. No need to disassemble.

And always use the latest released package. This will be tested. The git master branch is not meant to be stable. Use it for testing only.

Flashing for the first time

Especially for the first time, you must flash externally. See below for the details for using a Rapberry Pi, for example.

flashrom chip config

We (or our scripts) use flashrom for flashing. Run flashrom -p <your_hardware> (for example flashrom -p linux_spi:dev=/dev/spidev0.0,spispeed=128 for the Raspberry Pi) to let flashrom detect the chip. It will probably list a few you need to choose from when flashing (by adding -c <chipname>). Please review the chip model for your device. In case you are unsure what to specify, here's some examples we find out there:

4MB chip

  • MX25L3206E seems to mostly be in use

8MB chip

  • MX25L6406E/MX25L6408E is used in this guide
  • MX25L3206E/MX25L3208E is seen working with various X230 models.
  • EN25QH64 is used sometimes

EC firmware (optional)

Enter Lenovo's BIOS with F1 and check the embedded controller (EC) version to be 1.14 and upgrade using the latest bootable CD if it isn't. This updates BIOS and EC. The EC cannot be upgraded when coreboot is installed. (In case a newer version should ever be available (I doubt it), you could temporarily flash back the original Lenovo BIOS image from your backup)

ifd unlock and me_cleaner: the 8MB chip

The Intel Management Engine resides on the 8MB chip (at the bottom, closer to you). We don't need to touch it for coreboot-upgrades in the future, but to enable internal flashing, we need to unlock it once. We run ifdtool and, while we are at it, me_cleaner on it:

We support using a RPi, see below for the connection details. Move the release-tarball to the RPi (USB Stick or however) and unpack it (to the current directory and change into it):

mkdir tarball_extracted
tar -xf <tarball>.tar.xz -C tarball_extracted
cd tarball_extracted

And finally unlock the 8M chip by using the included script (be patient). Again, this doesn't replace much; it reads the original, unlocks and flashes back:

sudo ./flashrom_rpi_bottom_unlock.sh -m -c <chipname> -k <backup.bin>

That's it. Keep the backup safe.

background (just so you know)

  • The -m option above also runs me_cleaner -S before flashing back.

  • The -l option will (re-)lock your flash ROM, in case you want to force yourself (and others) to hardware-flashing externally.

  • If you don't use a RPi, change the flashrom programmer to your needs.This is roughly what's going on:

    flashrom -p linux_spi:dev=/dev/spidev0.0,spispeed=128 -c "MX25L6406E/MX25L6408E" -r ifdmegbe.rom
flashrom -p linux_spi:dev=/dev/spidev0.0,spispeed=128 -c "MX25L6406E/MX25L6408E" -r ifdmegbe2.rom
diff ifdmegbe.rom ifdmegbe2.rom
git clone https://github.com/corna/me_cleaner.git && cd me_cleaner
./me_cleaner.py -S -O ifdmegbe_meclean.rom ifdmegbe.rom
ifdtool -u ifdmegbe_meclean.rom
flashrom -p linux_spi:dev=/dev/spidev0.0,spispeed=128 -c "MX25L6406E/MX25L6408E" -w ifdmegbe_meclean.rom.new

BIOS: the 4MB chip

(internally, memory of the two chips is mapped together, the 8MB being the lower part, but we can essientially ignore that). Again, using a RPi is supported here. We assume you have the unpacked release tarball ready, see above. Use the following included script:

sudo ./flashrom_rpi_top_write.sh -i x230_coreboot_seabios_<hash>_top.rom -c <chipname> -k <backup>

That's it. Keep the backup safe.

How to update

When upgrading to a new release, only the "upper" 4MB chip has to be written. Download the latest release image we provide and flash it:

Example: internal

CAUTION: THIS IS NOT ENCOURAGED

  • Only for updating! You have to have your 8MB chip flashed externally using our flashrom_rpi_bottom_unlock.sh script (ifdtool -u) before this, once
  • very convenient: just install flashrom on the X230 and software-update, but according to the flashrom manpage this is very dangerous!
  • Boot Linux with the iomem=relaxed boot parameter (for example set in /etc/default/grub)
  • download the latest release tarball (4MB "top" BIOS image is included) and extract it
  • run prepare_internal_flashing.sh for generating all necessary files and printing all instructions
  • run the flashrom command you got from the script. That's it.

Example: Raspberry Pi 3

Here you'll flash externally, using a "Pomona 5250 8-pin SOIC test clip". You'll find one easily. This is how the X230's SPI connection looks on both chips:

    Screen (furthest from you)
             __
      MOSI  5 --|  |-- 4  GND
       CLK  6 --|  |-- 3  N/C
       N/C  7 --|  |-- 2  MISO
       VCC  8 --|__|-- 1  CS

       Edge (closest to you)

We run Raspbian and have the following setup

  • Serial connection using a "USB to Serial" UART Adapter and picocom or minicom (yes, in this case you need a second PC connected to the RPi over UART)

  • in the SD Cards's /boot/config.txt file enable_uart=1 and dtparam=spi=on

  • For flashrom we put spi_bcm2835 and spidev in /etc/modules

  • Connect to a wifi or to network over ethernet to sudo apt-get install flashrom

  • connect the Clip to the Raspberry Pi 3 (there are prettier images too:

         Edge of pi (furthest from you)
                 (UART)
   L           GND TX  RX                           CS
   E            |   |   |                           |
   F +---------------------------------------------------------------------------------+
   T |  x   x   x   x   x   x   x   x   x   x   x   x   x   x   x   x   x   x   x   x  |
     |  x   x   x   x   x   x   x   x   x   x   x   x   x   x   x   x   x   x   x   x  |
   E +----------------------------------^---^---^---^-------------------------------^--+
   D                                    |   |   |   |                               |
   G                                   3.3V MOSIMISO|                              GND
   E                                 (VCC)         CLK
     Body of Pi (closest to you)

Now copy our release tarball over to the Rasperry Pi. One way to copy, is convertig it to ascii using uuencode (part of Debian's sharutils package) described below. This is a direct, shady and slow way to transfer a file. Use a USB Stick or scp instead. :) (but you need even more hardware or a network).

    (convert)
host$ uuencode <tarball> <tarball>.ascii > <tarball>.ascii
    (transfer)
rpi$ cat > <tarball>.ascii
host$ pv <tarball>.ascii > /dev/ttyUSBX
    (wait)
rpi$ (CTRL-D)
    (convert back)
rpi$ uudecode -o <tarball> <tarball>.ascii
    (verify)
host$ sha1sum <tarball>
rpi$ sha1sum <tarball>

Raspberry Pi at work

Now unpack it:

mkdir tarball_extracted
tar -xf <tarball> -C tarball_extracted
cd tarball_extracted

Connect the SPI clip to the "top" chip, and run:

sudo ./flashrom_rpi_top_write.sh -i x230_coreboot_seabios_<hash>_top.rom -c <chipname>

That's it.

background (just so you know)

  • Connecting an ethernet cable as a power-source for SPI (instead of the VCC pin) is not necessary (some other flashing how-to guides mention this). Setting a fixed (and low) SPI speed for flashrom offeres the same stability. Our scripts do this for you.

Why does this work?

On the X230, there are 2 physical "BIOS" chips. The "upper" 4MB one holds the actual bios we can generate using coreboot, and the "lower" 8MB one holds the rest that you can modify yourself once, if you like, but strictly speaking, you don't need to touch it at all. What's this "rest"? Mainly a tiny binary used by the Ethernet card and the Intel Management Engine.