# coreboot-x230 pre-built [coreboot](https://www.coreboot.org/) image and documentation on how to flash them for the [Thinkpad X230](https://pcsupport.lenovo.com/en/products/laptops-and-netbooks/thinkpad-x-series-laptops/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](front.jpg) 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-x230 0.0.5 - see our [release page](https://github.com/merge/coreboot-x230/releases) * The only proprietary binary, the VGA BIOS is executed in "secure" mode ([PCI_OPTION_ROM_RUN_YABEL](https://www.coreboot.org/Coreboot_Options)) ### 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 * revision `1f` from 2018-02-07 (Intel package [20180312](https://downloadcenter.intel.com/download/27591) not yet in coreboot upstream) under [Intel's license](LICENSE.microcode) ### SeaBIOS * version [1.11.1](https://seabios.org/Releases) from 2018-03-19 (part of coreboot upstream) ## table of contents * [TL;DR](#tl-dr) * [Flashing for the first time](#flashing-for-the-first-time) * [How to update](#how-to-update) * [When do we do a release?](#when-do-we-do-a-release) * [How we build](#how-we-build) * [Why does this work](#why-does-this-work) * [Alternatives](#alternatives) ## 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. ## 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](https://flashrom.org/) for flashing. Run `flashrom -p ` (for [example](#how-to-flash) `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 `). 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](https://github.com/mfc/flashing-docs/blob/master/walkthrough%20for%20flashing%20heads%20on%20an%20x230.md#neutering-me) * `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](https://support.lenovo.com/at/en/downloads/ds029188) 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](https://github.com/coreboot/coreboot/tree/master/util/ifdtool) and, while we are at it, [me_cleaner](https://github.com/corna/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 .tar.xz -C tarball_extracted cd tarball_extracted And finally unlock the 8M chip by using the included script (be patient): sudo ./flashrom_rpi_bottom_unlock.sh -m -c -k 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__top.rom -c -k 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](https://manpages.debian.org/stretch/flashrom/flashrom.8.en.html) 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) and with our release tarball unpacked, the command you need looks like so: flashrom_rpi_top_write.sh -i x230_coreboot_seabios__top.rom -c We run [Raspbian](https://www.raspberrypi.org/downloads/raspbian/) and have the following setup * [Serial connection](https://elinux.org/RPi_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](https://www.flashrom.org/RaspberryPi) we put `spi_bcm2835` and `spidev` in /etc/modules * [Connect to a wifi](https://www.raspberrypi.org/documentation/configuration/wireless/wireless-cli.md) or to network over ethernet to `sudo apt-get flashrom` * only flash the top 4M chip * connect the Clip to the Raspberry Pi 3 (there are [prettier images](https://github.com/splitbrain/rpibplusleaf) 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 .ascii > .ascii (transfer) rpi$ cat > .ascii host$ pv .ascii > /dev/ttyUSBX (wait) rpi$ (CTRL-D) (convert back) rpi$ uudecode -o .ascii (verify) host$ sha1sum rpi$ sha1sum ![Raspberry Pi at work](rpi_clip.jpg) Now unpack it: mkdir tarball_extracted tar -xf -C tarball_extracted cd tarball_extracted Check the SPI connection to the "top" chip to update, and run: sudo ./flashrom_rpi_top_write.sh -i x230_coreboot_seabios__top.rom -c 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. ## When do we do a release? Either when * There is a new SeaBIOS release, * There is a new Intel microcode release (for our CPU model), * There is a coreboot issue that affects us, or * We change the config ## How we build * Everything necessary to build coreboot (while only the top 4MB are usable of course) is included here * The task of [building coreboot](https://www.coreboot.org/Build_HOWTO) is not too difficult * When doing a release here, we always try to upload to coreboot's [board status project](https://www.coreboot.org/Supported_Motherboards) * If we add out-of-tree patches, we always [post them for review](http://review.coreboot.org/) upstream ## 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](#flashing-for-the-first-time), if you like, but strictly speaking, you [don't need to touch it at all](https://www.coreboot.org/Board:lenovo/x230#Building_Firmware). What's this "rest"? Mainly a tiny binary used by the Ethernet card and the Intel Management Engine. ## Alternatives We aim to be the easiest possible coreboot distribution for the X230 - both to install and to use. And since our images are unlocked to enable easy software updates, it's easy to try alternative systems too: * [Heads](https://github.com/osresearch/heads/releases) - coreboot distribution with pre-built (or reproducibly buildable) flash images for the X230. Heads includes Linux, with tools to create a trusted boot chain using your GPG key and the TPM. * [libreboot](https://libreboot.org/) - also a coreboot distribution with pre-built image releases. But the X230 is currently not supported (the X200 is) - libreboot images are built from free software only and include the GRUB bootloader.