From 1e25185de28bedb1bc30c53205b2c09632c4c019 Mon Sep 17 00:00:00 2001 From: Kenny Ballou Date: Thu, 1 Feb 2018 18:23:48 -0700 Subject: coreboot-x230 post conversion --- content/blog/coreboot-x230.markdown | 498 ------------------------------------ 1 file changed, 498 deletions(-) delete mode 100644 content/blog/coreboot-x230.markdown (limited to 'content') diff --git a/content/blog/coreboot-x230.markdown b/content/blog/coreboot-x230.markdown deleted file mode 100644 index 5193e53..0000000 --- a/content/blog/coreboot-x230.markdown +++ /dev/null @@ -1,498 +0,0 @@ ---- -title: "Coreboot for x230" -description: "Getting Coreboot onto Lenovo x230" -tags: - - "Coreboot" - - "GNU/Linux" - - "BIOS" - - "Hardware" - - "Lenovo" - - "x230" - - "Raspberry-Pi" -date: "2017-01-31" -categories: - - "Guides" - - "Notes" -slug: "coreboot-x230" ---- - -{{< - figure src="/media/coreboot-x230-1.png" - alt="Disassembled Laptop" - width="70%" ->}} - -In this post, we will go through the steps to get [coreboot][1] compiled and -installed on a [Lenovo x230][2] laptop. This is a somewhat lengthy and involved -process that is not for the faint of heart. *It is very possible to ruin or -otherwise brick your laptop performing these steps improperly or even -properly!* You have been warned. - -## Coreboot ## - -> coreboot is an extended firmware platform that delivers a lightning fast and -> secure boot experience on modern computers and embedded systems ---[coreboot project][1] - -Coreboot is an OpenSource firmware alternative that supports a number of modern -computers and embedded systems. It can replace your system's [BIOS][28] with a -faster and more secure platform. It can be preloaded with a number of -payloads, e.g., [SeaBIOS][29] or [tianocore][30], and/or it can come with some -additional payloads, e.g., [memtest86+][31]. - -## Motivation ## - -Why replace the default BIOS image in the first place? There are several -motivations for doing this. For one, it's [well documented][5] that Lenovo -installs a device whitelist onto its systems, disabling the computer if a -third-party peripheral is installed, which can include WiFi cards and SSD's. -If you're more adventurous and want to replace the x230 screen with that of an -x240, the whitelist will also get in the way. By replacing the BIOS entirely, -this whitelist problem will be avoided. - -Furthermore, in older laptops, x200/1 for example, it's possible to replace the -disastrous [Intel ME][6] platform. This is, unfortunately, (currently) -impossible on the x230 and later. That is, removing the ME code will make the -laptop effectively unusable. - -## Necessary Equipment ## - - -Before we go into the actual steps, let's take a moment to gather all the -necessary equipment. Disassembly is necessary because the BIOS chip is locked -and not accessible from software flashers like [flashrom][13]. However, -desoldering will not be necessary. - -* SPI Flash Programmer - - This guide will perform the ROM flashing via the GPIO headers of a - [Raspberry Pi 2][3] (RPI-1 should work, but different pinouts are - required). - -* [SOIC-8 Clip][4] - - This clip will be used for interfacing with the BIOS chip and the SPI - programmer. They are sometimes available for less (with longer shipping - times) from [eBay][20]. - -* Some [_short_ cables][21] - - These cables will connect the SOIC chip to the GPIO headers of the - Raspberry Pi. It is important that they are short, no more than 25cm or so. - -* [Plastic opening tools][27] - - After not having these for too long, I can't recommend these enough for - opening up laptops and other devices. - -* A precision Phillips screwdriver - - A percision set will be better, used for disassembling the laptop. - -* A magnifying lens - - The specific chip found in _your_ x230 may be different from mine. A - magnifying lens will be helpful in determining the exact version. - -## Disassembly and BIOS Access ## - -[Steps][11] and [manuals][12] for disassembling the laptop can be found with a -simple search. However, it's only necessary to remove the keyboard and the palm -rest to gain access to the BIOS chip. Of course, remove the battery and power -supply before opening the laptop. I personally, removed the hard drive and WiFi -card as well, I wanted nothing attached while working. - -{{< figure src="/media/coreboot-x230-2.png" alt="BIOS Chip" width="30%" >}} - -You will notice there are two chips in the above figure. The combination of -these two chips is what makes up the BIOS (and the Intel ME) for the x230. *We -will be dealing exclusively with the _top_ chip* (one closest to the screen). - -Once we have physical access to the top chip, use the magnifying glass to read -the _tiny_ print of the chip. We need to know the precise version of the chip -to remove any future guesswork from the process, especially for disaster -recovery. - -If you are unable to read the version of the chip, there are steps we can take -to proceed, but it will be far more tedious and less comfortable. - -### Connecting the Raspberry Pi to the SOIC Clip ### - -Next, we will be connecting the Raspberry Pi with the cables and clips to the -BIOS chip. - -> I found this to be the most difficult of the entire process. Finding a solid -> source for the documentation on the chip and the GPIO headers was incredibly -> difficult the first time around. - -First, get [GPIO header diagram][14] for your Raspberry Pi model. - -Next, cross-reference the header diagram with your chip's spec sheet. It should -be in the list at [All Data Sheet][15]. Specifically, I found mine [here][16]. -It's very likely, yours will be similar. Cross reference the "Pin -Configuration" page with the GPIO header diagram to discern the proper -connections. - -The pin arrangement that I used was the following (using the notch on the chip -for starting): - -* 1: GPIO 26 - -* 2: GPIO 19 - -* 3: Not Connected - -* 4: GPIO 17 - -* 5: GPIO 21 - -* 6: GPIO 23 - -* 7: Not Connected - -* 8: GPIO 25 - -### Using the Raspberry Pi ### - -{{< figure - src="/media/coreboot-x230-3.png" - alt="Raspberry Pi connected to x230 via SOIC clip" - width="70%" ->}} - -> Before connecting the clip, it's imperative to remove all external power -> sources. The Raspberry Pi will be providing power to the ROM chip, any -> external current can and most likely _will_ brick your laptop. - -Attach the clip to the chip and power on the Raspberry Pi. Before you are able -to read the chip, you may need to install [flashrom][13] and ensure your kernel -has SPI enabled. Most distributions will have it on by default. An easy way to -check is to list the contents of `/dev` and look for `spi` devices, since the -chip is connected, there should be one. - -Before we begin the process of flashing, let's inspect the ROM itself. First, -simply run flashrom, specifying the SPI device as the programmer: - - # flashrom --programmer linux_spi:dev=/dev/spidev0.0 - flashrom v0.9.9-r1955 on Linux 4.4.10-1-ARCH (armv7l) - flashrom is free software, get the source code at https://flashrom.org - - Calibrating delay loop... OK. - Found Macronix flash chip "MX25L3205(A)" (4096 kB, SPI) on linux_spi. - Found Macronix flash chip "MX25L3205D/MX25L3208D" (4096 kB, SPI) on linux_spi. - Found Macronix flash chip "MX25L3206E/MX25L3208E" (4096 kB, SPI) on linux_spi. - Found Macronix flash chip "MX25L3273E" (4096 kB, SPI) on linux_spi. - Multiple flash chip definitions match the detected chip(s): "MX25L3205(A)", "MX25L3205D/MX25L3208D", "MX25L3206E/MX25L3208E", "MX25L3273E" - Please specify which chip definition to use with the -c option. - -> If you are seeing numbers like 8192 kB, you're reading the wrong chip! -> Disconnect and attach to the other. - -If you were able to read the chip number, pass it along, and try again: - - # flashrom --programmer linux_spi:dev=/dev/spidev0.0 \ - --chip "MX25L3206E/MX25L3208E" - flashrom v0.9.9-r1955 on Linux 4.4.10-1-ARCH (armv7l) - flashrom is free software, get the source code at https://flashrom.org - - Calibrating delay loop... OK. - Found Macronix flash chip "MX25L3206E/MX25L3208E" (4096 kB, SPI) on linux_spi. - -Now, we will want to create a back up image of the ROM, but we also want to -verify we are reading correctly: - - # flashrom --programmer linux_spi:dev=/dev/spidev0.0 \ - --chip "MX25L3206E/MX25L3208E" \ - --read original.1.rom - flashrom v0.9.9-r1955 on Linux 4.4.10-1-ARCH (armv7l) - flashrom is free software, get the source code at https://flashrom.org - - Calibrating delay loop... OK. - Found Macronix flash chip "MX25L3206E/MX25L3208E" (4096 kB, SPI) on linux_spi. - Reading flash... done. - - # flashrom --programmer linux_spi:dev=/dev/spidev0.0 \ - --chip "MX25L3206E/MX25L3208E" \ - --read original.2.rom - flashrom v0.9.9-r1955 on Linux 4.4.10-1-ARCH (armv7l) - flashrom is free software, get the source code at https://flashrom.org - - Calibrating delay loop... OK. - Found Macronix flash chip "MX25L3206E/MX25L3208E" (4096 kB, SPI) on linux_spi. - Reading flash... done. - - # diff original.1.rom original.2.rom - -> Again, if the size of `original.1.rom` and `original.2.rom` are 8MB, you're -> reading the wrong chip, move the clip to the other chip and repeat the above -> steps! - -If you get no output from the last command, we should be set, or it means we're -reading both incorrectly. However, it's more likely flashrom will complain -first. - -Keep at least one of the images around just in case this fails and you need to -attempt recovery. - -> If you were unable to read the serial number off the chip, perform the read 4 -> to 8 times, once or twice for each chip type. - -## Configuration and Compilation ## - -Half the battle to getting Coreboot onto your system is properly putting -together the build-tools and compiling the coreboot image. There already exists -a [guide for configuring and building][8] the Coreboot tool-chain, but for -completeness, the basic steps will be copied here. - -> I'll assume a certain comfortability with GNU/Linux and the GNU GCC and Make -> tools. - -First up, get a copy of the [Coreboot Source][7]: - - % git clone --recursive https://review.coreboot.org/coreboot.git - -This will get the latest source code of the Coreboot project and also -initialize the project's submodules. - -Next, we will need to download the blobs archive: - - % curl -SLO https://www.coreboot.org/releases/coreboot-blobs-4.5.tar.xz - -> The link can be found from the [Coreboot Downloads][9] page. - -Now, unpack the blobs into the `coreboot/3rdparty/blobs` folder: - - % tar -xf coreboot-blobs-4.5.tar.xz --strip-components=1 -C coreboot - -Now, we can move onto configuring the tool-chain, building the tool-chain, and -finally building the coreboot image itself. - -### Configuration ### - - % cd coreboot - -We'll start by configuring the compile options for coreboot: - - ± make menuconfig - -OR - - ± make nconfig - -Set the following options: - -``` -general --| - |-[*] Compress ramstage with LZMA - |-[*] Include the coreboot .config file into the ROM image -mainboard -| - |-Mainboard vendor (Lenovo) - |-Mainboard model (ThinkPad X230) - |-ROM chip size (12288 KB (12 MB)) - |-(0x100000) Size of CBFS filesystem in ROM -devices ---| - |-[*] Use native graphics initialization -generic ---| - |-[*] PS/2 keyboard init -console ---| - |-[*] Squelch AP CPUs from early console. - |-[*] Send console output to a CBMEM buffer - |-[*] Send POST codes to an external device - |-[*] Send POST codes to an IO port -sys table -| - |-[*] Generate SMBIOS tables -payload ---| - |-Add a payload (SeaBIOS) - |-SeaBIOS version (master) - |-(10) PS/2 keyboard controller initialization timeout (milliseconds) - |-[*] Hardware init during option ROM execution - |-[*] Include generated option rom that implements legacy VGA BIOS compatibility - |-[*] Use LZMA compression for payloads -``` - -These configuration options were borrowed from [Unix Blather][26]. - -### Compilation ### - -> If you were thinking of compiling the ROM on the Pi, I recommend you -> reconsider. If you have an exorbitant amount of time to kill, go for it, but -> you'll prefer a machine with more power. - -From here, we can build the tool-chain: - - ± make crossgcc-x64 CPUS=$(nproc) - -This will only build the tool-chain for the x64 architecture, update as -necessary. - -`CPUS=#` is used to specify the parallelization of the tool-build. This is -unfortunately different from the usual `--jobs|-j` argument of `make`, but has -the same effect. - -Now, we can build the coreboot image itself: - - ± make -j$(nproc) - -This will create `build/coreboot.rom` image. - -However, this will *not* be the image we flash onto our laptop! Because the -Lenovo x230 comes with the [nasty Intel ME][6] and we built the coreboot image -using a stub for the Intel ME section, we need to create a new image that -contains only the Coreboot contents. To do this, we will use `dd` to skip the -first 8MB of the image, and only grab the last 4: - - ± dd if=build/coreboot.rom bs=1M of=/tmp/x230.rom skip=8 - -This will create a 4MB file in `/tmp/` named `x230.rom`. Finally, copy the new -image to the Raspberry Pi. - -## Flashing the New Image ## - -After the image is copied to the Pi, we can use flashrom to write the new -image: - - # flashrom --programmer linux_spi:dev=/dev/spidev0.0 - --chip "MX25L3206E/MX25L3208E" - --write /tmp/x230.rom - flashrom v0.9.9-r1955 on Linux 4.4.10-1-ARCH (armv7l) - flashrom is free software, get the source code at https://flashrom.org - - Calibrating delay loop... OK. - Found Macronix flash chip "MX25L3206E/MX25L3208E" (4096 kB, SPI) on linux_spi. - Reading old flash chip contents... done. - Erasing and writing flash chip... Erase/write done. - Verifying flash... VERIFIED. - -Flashrom will read back the new contents and verify it was successful, however, -I like the comfort of having done this myself. This can be accomplished two -ways: using flashrom's `--verify` option, or reading the image and running -`diff`: - - - # flashrom --programmer linux_spi:dev=/dev/spidev0.0 - --chip "MX25L3206E/MX25L3208E" - --verify /tmp/x230.rom - flashrom v0.9.9-r1955 on Linux 4.4.10-1-ARCH (armv7l) - flashrom is free software, get the source code at https://flashrom.org - - Calibrating delay loop... OK. - Found Macronix flash chip "MX25L3206E/MX25L3208E" (4096 kB, SPI) on linux_spi. - Reading old flash chip contents... done. - Verifying flash... VERIFIED. - -OR - - # flashrom --programmer linux_spi:dev=/dev/spidev0.0 \ - --chip "MX25L3206E/MX25L3208E" \ - --read /tmp/x230.2.rom - flashrom v0.9.9-r1955 on Linux 4.4.10-1-ARCH (armv7l) - flashrom is free software, get the source code at https://flashrom.org - - Calibrating delay loop... OK. - Found Macronix flash chip "MX25L3206E/MX25L3208E" (4096 kB, SPI) on linux_spi. - Reading flash... done. - - # diff /tmp/x230.rom /tmp/x230.2.rom - -If you get "VERIFIED" or no output, respectively, the contents of the BIOS chip -should be replaced with the Coreboot image. - -All that's next is to disconnect the chip, reassemble the laptop and hope it -works! - -## Common Problems ## - -If you're having issues flashing or reading your BIOS, check the following: - -* The chip is getting sufficient power - -* The wires used to connect the Raspberry Pi and the chip are not _too long_ - -* Make sure your pinout is correct - -For some more information, check Flashrom's [in system programming][25]. - -## Summary and Auxiliary Advice ## - -Hopefully, you're now booting into your x230 with Coreboot. Enjoy your new -BIOS, whitelist free and awesome! - -However, if you have issues, e.g., the flashing doesn't go as planned: *DO NOT -POWER OFF THE CHIP!* Get help from the [#coreboot][22] IRC channel on -[freenode][23] or [email the mailing list][24]. - -## References ## - -[1]: https://www.coreboot.org - -* [coreboot homepage][1] - -[2]: http://shop.lenovo.com/us/en/laptops/thinkpad/x-series/x230/ - -* [x230 product page][2] - -[3]: https://www.raspberrypi.org/products/raspberry-pi-2-model-b/ - -* [Raspberry Pi 2 Model B][3] - -[4]: https://www.sparkfun.com/products/13153 - -* [IC Test Clip - SOIC 8-Pin][4] - -[5]: https://duckduckgo.com/?q=lenovo+whitelist+bios - -[6]: https://en.wikipedia.org/wiki/Intel_Active_Management_Technology - -* [Intel Active Management Technology Wikipedia Post][6] - -[7]: https://www.coreboot.org/downloads.html - -[8]: https://www.coreboot.org/Build_HOWTO - -* [Coreboot Build HOWTO][8] - -[9]: https://www.coreboot.org/downloads.html - -* [Coreboot Downloads][9] - -[11]: http://www.myfixguide.com/manual/lenovo-thinkpad-x230-disassembly-clean-cooling-fan-remove-keyboard/ - -[12]: https://www.ifixit.com/Device/Lenovo_Thinkpad_x230 - -[13]: https://www.flashrom.org/Flashrom - -* [Flashrom Project Homepage][13] - -[14]: http://www.raspberrypi-spy.co.uk/wp-content/uploads/2014/07/Raspberry-Pi-GPIO-Layout-Worksheet.pdf - -* [Raspberry Pi GPIO Header Sheet B/B+][14] - -[15]: http://www.alldatasheet.com - -[16]: http://html.alldatasheet.com/html-pdf/575458/MCNIX/MX25L3208EM2I12G/1149/7/MX25L3208EM2I12G.html - -[20]: https://eBay.com - -[21]: https://www.amazon.com/Elegoo-120pcs-Multicolored-Breadboard-arduino/dp/B01EV70C78 - -[22]: irc://irc.freenode.net/coreboot - -[23]: https://freenode.net/ - -[24]: https://www.coreboot.org/Mailinglist - -[25]: https://www.flashrom.org/ISP - -[26]: https://www.ericholzbach.net/blog/x230_coreboot/ - -* [Unix Blather: Coreboot on the Lenovo x230][26] - -[27]: https://www.amazon.com/Professional-Non-Abrasive-Spudgers-Anti-Static-Tweezers/dp/B00PHNMEMC - -[28]: https://en.wikipedia.org/wiki/BIOS - -[29]: https://www.seabios.org/SeaBIOS - -[30]: http://www.tianocore.org/ - -[31]: http://www.memtest.org/ -- cgit v1.2.1