This section relates to building libreboot from source, and working with the git repository.
Before doing anything, you need the dependencies first. This is true if you want to build libreboot from source, with either libreboot_src.tar.xz or git. If you are using libreboot_util.tar.xz (binary archive) then you can ignore this, because ROM images and statically compiled executables for the utilities are included.
For Trisquel 7, you can run the following command:
$ sudo ./build dependencies trisquel7
For Parabola, you can run the following command:
$ sudo ./build dependencies parabola
or:
# ./build dependencies parabola
For other GNU/Linux distributions, you can adapt the existing scripts.
If you downloaded libreboot from git, then there are some steps to download and patch the source code for all relevant dependencies. The archive in the git repository used to be available as a tarball called 'libreboot_meta.tar.gz'. It contains 'metadata' (scripts) which define how the source was created (where it came from).
You can use the scripts included to download everything.
First, install the build dependencies.
Since libreboot makes extensive use of git, you need to configure git properly. If you have not yet configured
git, then the minimum requirement is:
$ git config --global user.name "Your Name"
$ git config --global user.email your@emailaddress.com
This is what will also appear in git logs if you ever commit your own changes to a given repository. For
more information, see http://git-scm.com/doc.
Another nice config for you (optional, but recommended):
$ git config --global core.editor nano
$ git config --global color.status auto
$ git config --global color.branch auto
$ git config --global color.interactive auto
$ git config --global color.diff auto
After that, run the script:
$ ./download all
What this did was download everything (grub, coreboot, memtest86+, bucts, flashrom) at the versions last tested for this release, and patch them. Read the script in a text editor to learn more.
To build the ROM images, see #build.
This is for Lenovo BIOS users on the ThinkPad X60/X60S, X60 Tablet and T60. If you have coreboot or libreboot running already, ignore this.
BUC.TS isn't really specific to these laptops, but is a bit inside the a register in the chipset on some Intel systems.
Bucts is needed when flashing in software the X60/X60S/X60T/T60 ROM while Lenovo BIOS is running; external flashing will be safe regardless. Each ROM contains identical data inside the two final 64K region in the file*. This corresponds to the final two 64K regions in the flash chip. Lenovo BIOS will prevent you from writing the final one, so running "bucts 1" will set the system to boot from the other block instead (which is writeable along with everything beneath it when using a patched flashrom. see #build_flashrom). After shutting down and booting up after the first flash of libreboot, the final 64K block is writeable so you flash the ROM again with an unpatched flashrom and run "bucts 0" to make the system boot from the normal (highest) block again.
*Libreboot ROM images have identical data in those two 64KiB regions because dd is used to do that, by the build system. If you're building from upstream (coreboot), you have to do it manually.
BUC.TS is backed up (powered) by the NVRAM battery (or CMOS battery, as some people call it). On thinkpads, this is typically in a yellow plastic package with the battery inside, connected via power lines to the mainboard. Removing that battery removes power to BUC.TS, resetting the bit back to 0 (if you previously set it to 1).
BUC.TS utility is included in libreboot_src.tar.xz and libreboot_util.tar.xz.
If you downloaded from git, follow #build_meta before you proceed.
"BUC" means "Backup Control" (it's a register) and "TS" means "Top Swap" (it's a status bit). Hence "bucts" (BUC.TS). TS 1 and TS 0 corresponds to bucts 1 and bucts 0.
If you have the binary release archive, you'll find executables under ./bucts/. Otherwise if you need to build from source, continue reading.
First, install the build dependencies.
To build bucts, do this in the main directory:
$ ./build module bucts
To statically compile it, do this:
$ ./build module bucts static
The "builddeps" script in libreboot_src also makes use of builddeps-bucts.
Flashrom is the utility for flashing/dumping ROM images. This is what you will use to install libreboot.
Flashrom source code is included in libreboot_src.tar.xz and libreboot_util.tar.xz.
If you downloaded from git, follow #build_meta before you proceed.
If you are using the binary release archive, then there are already binaries included under ./flashrom/. The flashing scripts will try to choose the correct one for you. Otherwise if you wish to re-build flashrom from source, continue reading.
First, install the build dependencies.
To build it, do the following in the main directory:
$ ./build module flashrom
To statically compile it, do the following in the main directory:
$ ./build module flashrom static
After you've done that, under ./flashrom/ you will find the following executables:
The "builddeps" script in libreboot_src also makes use of builddeps-flashrom.
Before building a ROM in libreboot (or coreboot, for that matter), you need to configure it. Configuration files should already be included, so you don't need to do anything. This information is only for reference. If you are updating or modifying coreboot-libre, and need to update the configs in any way, refer to ../maintain/index.html#newboard_libreboot.
If you've already built a kernel before, you know how to use this interface.
There is certain information that can be useful to enter in particular:
This information can be obtained using:
$ sudo dmidecode
# dmidecode
Specifically, it's good practise to enter the same information for libreboot that you found when running this with the original BIOS or firmware. libreboot has already done this for you. This information is for reference, in the hope that it will be useful.
In practise, this information is useless and you can just leave it on the defaults that coreboot uses (this is what libreboot does, on most boards).
GRUB is one of the payloads that libreboot targets.
Configurations are then saved as files called ".config". Copies of each configuration used for each system type by the libreboot build scripts are stored in resources/libreboot/config/grub/
Now go back into Devices:
The resulting .config file was saved as resources/libreboot/config/grub/kfsn4-dre/config and is used by the build scripts for this system.
Now go back into Devices:
The resulting .config file was saved as resources/libreboot/config/grub/x60/config and is used by the build scripts for this system.
This configuration is used on all variants: X60, X60S and X60 Tablet.
Go back into Devices:
The resulting .config file was saved as resources/libreboot/config/grub/t60/config and is used by the build scripts for this system.
It is believed that the motherboards on 14.1" and 15.1" T60s are the same, so the same configuration is used on both the 14.1" and 15.1" T60s.
These are saved as two configs, because there are 2 size flash chips: 4MB or 8MB.
Go back and disable option ROMs:
The resulting .config file was saved as resources/libreboot/config/grub/x200_8mb/config and resources/libreboot/config/grub/x200_4mb/config and is used by the build scripts for this system.
These are saved as two configs, because there are 2 size flash chips: 4MB or 8MB.
Go back and disable option ROMs:
The resulting .config file was saved as resources/libreboot/config/grub/r400_8mb/config and resources/libreboot/config/grub/r400_4mb/config and is used by the build scripts for this system.
These are saved as two configs, because there are 2 size flash chips: 4MB or 8MB.
Go back and disable option ROMs:
The resulting .config file was saved as resources/libreboot/config/grub/t400_8mb/config and resources/libreboot/config/grub/t400_4mb/config and is used by the build scripts for this system.
These are saved as two configs, because there are 2 size flash chips: 4MB or 8MB.
Go back and disable option ROMs:
The resulting .config file was saved as resources/libreboot/config/grub/t500_8mb/config and resources/libreboot/config/grub/t500_4mb/config and is used by the build scripts for this system.
Go back and disable option ROMs:
The resulting .config file was saved as resources/libreboot/config/grub/macbook21/config and is used by the build scripts for this system. This config is also used for the MacBook1,1.
Go back and disable option ROMs:
The resulting .config file was saved as resources/libreboot/config/grub/qemu_i440fx_piix4/config and is used by the build scripts for this system.
Go back and disable option ROMs:
The resulting .config file was saved as resources/libreboot/config/grub/qemu_q35_ich9/config and is used by the build scripts for this system.
You don't need to do much, as there are scripts already written for you that can build everything automatically.
You can build libreboot from source on a 32-bit (i686) or 64-bit (x86_64) system. Recommended (if possible): x86_64. ASUS KFSN4-DRE has 64-bit CPUs. On a ThinkPad T60, you can replace the CPU (Core 2 Duo T5600, T7200 or T7600. T5600 recommended) for 64-bit support. On an X60s, you can replace the board with one that has a Core 2 Duo L7400 (you could also use an X60 Tablet board with the same CPU). On an X60, you can replace the board with one that has a Core 2 Duo T5600 or T7200 (T5600 is recommended). All MacBook2,1 laptops are 64-bit, as are all ThinkPad X200, X200S, X200 Tablet, R400, T400 and T500 laptops. Warning: MacBook1,1 laptops are all 32-bit only.
First, install the build dependencies.
If you downloaded libreboot from git, refer to #build_meta.
Build all of the components used in libreboot:
$ ./build module all
You can also build each modules separately, using ./build module modulename.
To see the possible values for modulename, use:
$ ./build module list
NOTE: crossgcc is included in coreboot/util/crossgcc/tarballs/ in the release archives,
but the build system for libreboot does not automatically download/build it.
If you are using libreboot from the git repository, make sure to do the following:
$ cd coreboot/
$ make crossgcc-i386
$ cd ../
This will download coreboot's reference cross-compile toolchain,
which is highly recommended by the coreboot project.
After that, build the ROM images (for all boards):
$ ./build roms withgrub
Alternatively, you can build for a specific board or set of boards.
For example:
$ ./build roms withgrub x60
$ ./build roms withgrub x200_8mb
$ ./build roms withgrub x60 x200_8mb
The list of board options can be found by looking at the directory
names in resources/libreboot/config/grub/.
To clean (reverse) everything, do the following:
$ ./build clean all
The ROM images will be stored under bin/payload/, where payload could be grub, seabios, or whatever other payload those images were built for.
This is only confirmed to work (tested) in Trisquel 7. Parabola *fails* at this stage (for now). For all other distros, YMMV.
This is mainly intended for use with the git repository. These commands will work in the release archive (_src), unless otherwise noted below.
The archives will appear under release/${version}/; ${version} will either be set using git describe or, if a version file already exists (_src release archive), then it will simply re-use that.
Tag the current commit, and that version will appear in both the ${version} string on the directory under release/, and in the file names of the archives. Otherwise, whatever git uses for git describe --tags HEAD will be used.
Utilities (static executables):
$ ./build release util
Archive containing flashrom and bucts source code:
$ ./build release tobuild
Documentation archive (does not work on _src release archive, only git):
$ ./build release docs
ROM image archives:
$ ./build release roms
Source code archive:
$ ./build release src
SHA512 sums of all other release archives that have been generated:
$ ./build release sha512sums
If you are building on an i686 host, this will build statically linked 32-bit binaries in the binary release archive that you created, for: nvramtool, cbfstool, ich9deblob, cbmem.
If you are building on an x86_64 host, this will build statically linked 32- *and* 64-bit binaries for cbmem, ich9deblob, cbfstool and nvramtool.
To include statically linked i686 and x86_64 binaries for bucts and flashrom, you will need to build them on a chroot, a virtual system or a real system where the host uses each given architecture. These packages are difficult to cross-compile, and the libreboot project is still figuring out how to deal with them.
The same applies if you want to include statically linked flashrom binaries for ARM.
armv7l binaries (tested on a BeagleBone Black) are also included in libreboot_util, for:
If you are building binaries on a live system or chroot (for flashrom/bucts), you can use the following to statically link them:
$ ./build module flashrom static
$ ./build module bucts static
The same conditions as above apply for ARM (except, building bucts on ARM is pointless, and for flashrom you only need the normal executable since the lenovobios_sst and _macronix executables are meant to run on an X60/T60 while lenovo bios is present, working around the security restrictions).
The command that you used for generating the release archives will also run the following command:
$ ./build release tobuild
The archive tobuild.tar.xz will have been created under release/, containing bucts, flashrom and all other required
resources for building them.
You'll find that the files libreboot_util.tar.xz and libreboot_src.tar.xz have been created, under release/.
The ROM images will be stored in separate archives for each system, under release/rom/.
Copyright © 2014, 2015 Francis Rowe <info@gluglug.org.uk>
Permission is granted to copy, distribute and/or modify this document
under the terms of the GNU Free Documentation License, Version 1.3
or any later version published by the Free Software Foundation;
with no Invariant Sections, no Front-Cover Texts, and no Back-Cover Texts.
A copy of the license can be found at ../gfdl-1.3.txt
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