e0c4aa5ac5
Signed-off-by: Shawn Landden <shawn@churchofgit.com> Reviewed-by: Thomas De Schampheleire <thomas.de.schampheleire@gmail.com> Signed-off-by: Peter Korsgaard <peter@korsgaard.com>
381 lines
19 KiB
Plaintext
381 lines
19 KiB
Plaintext
// -*- mode:doc; -*-
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// vim: set syntax=asciidoc:
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[[configure]]
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Details on Buildroot configuration
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----------------------------------
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All the configuration options in +make *config+ have a help text
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providing details about the option. However, a number of topics
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require additional details that cannot easily be covered in the help
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text and are there covered in the following sections.
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Cross-compilation toolchain
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~~~~~~~~~~~~~~~~~~~~~~~~~~~
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A compilation toolchain is the set of tools that allows you to compile
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code for your system. It consists of a compiler (in our case, +gcc+),
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binary utils like assembler and linker (in our case, +binutils+) and a
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C standard library (for example
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http://www.gnu.org/software/libc/libc.html[GNU Libc],
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http://www.uclibc.org/[uClibc]).
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The system installed on your development station certainly already has
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a compilation toolchain that you can use to compile an application
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that runs on your system. If you're using a PC, your compilation
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toolchain runs on an x86 processor and generates code for an x86
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processor. Under most Linux systems, the compilation toolchain uses
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the GNU libc (glibc) as the C standard library. This compilation
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toolchain is called the "host compilation toolchain". The machine on
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which it is running, and on which you're working, is called the "host
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system" footnote:[This terminology differs from what is used by GNU
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configure, where the host is the machine on which the application will
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run (which is usually the same as target)].
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The compilation toolchain is provided by your distribution, and
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Buildroot has nothing to do with it (other than using it to build a
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cross-compilation toolchain and other tools that are run on the
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development host).
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As said above, the compilation toolchain that comes with your system
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runs on and generates code for the processor in your host system. As
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your embedded system has a different processor, you need a
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cross-compilation toolchain - a compilation toolchain that runs on
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your _host system_ but generates code for your _target system_ (and
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target processor). For example, if your host system uses x86 and your
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target system uses ARM, the regular compilation toolchain on your host
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runs on x86 and generates code for x86, while the cross-compilation
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toolchain runs on x86 and generates code for ARM.
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Buildroot provides two solutions for the cross-compilation toolchain:
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* The *internal toolchain backend*, called +Buildroot toolchain+ in
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the configuration interface.
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* The *external toolchain backend*, called +External toolchain+ in
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the configuration interface.
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The choice between these two solutions is done using the +Toolchain
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Type+ option in the +Toolchain+ menu. Once one solution has been
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chosen, a number of configuration options appear, they are detailed in
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the following sections.
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[[internal-toolchain-backend]]
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Internal toolchain backend
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^^^^^^^^^^^^^^^^^^^^^^^^^^
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The _internal toolchain backend_ is the backend where Buildroot builds
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by itself a cross-compilation toolchain, before building the userspace
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applications and libraries for your target embedded system.
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This backend is the historical backend of Buildroot, and has been
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limited for a long time to the usage of the
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http://www.uclibc.org[uClibc C library]. Support for the _eglibc_ C
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library has been added in 2013 and is at this point considered
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experimental. See the _External toolchain backend_ for another
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solution to use _glibc_ or _eglibc_.
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Once you have selected this backend, a number of options appear. The
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most important ones allow to:
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* Change the version of the Linux kernel headers used to build the
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toolchain. This item deserves a few explanations. In the process of
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building a cross-compilation toolchain, the C library is being
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built. This library provides the interface between userspace
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applications and the Linux kernel. In order to know how to "talk"
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to the Linux kernel, the C library needs to have access to the
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_Linux kernel headers_ (i.e, the +.h+ files from the kernel), which
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define the interface between userspace and the kernel (system
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calls, data structures, etc.). Since this interface is backward
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compatible, the version of the Linux kernel headers used to build
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your toolchain do not need to match _exactly_ the version of the
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Linux kernel you intend to run on your embedded system. They only
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need to have a version equal or older to the version of the Linux
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kernel you intend to run. If you use kernel headers that are more
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recent than the Linux kernel you run on your embedded system, then
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the C library might be using interfaces that are not provided by
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your Linux kernel.
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* Change the version and the configuration of the uClibc C library
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(if uClibc is selected). The default options are usually
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fine. However, if you really need to specifically customize the
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configuration of your uClibc C library, you can pass a specific
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configuration file here. Or alternatively, you can run the +make
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uclibc-menuconfig+ command to get access to uClibc's configuration
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interface. Note that all packages in Buildroot are tested against
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the default uClibc configuration bundled in Buildroot: if you
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deviate from this configuration by removing features from uClibc,
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some packages may no longer build.
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* Change the version of the GCC compiler and binutils.
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* Select a number of toolchain options (uClibc only): whether the
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toolchain should have largefile support (i.e support for files
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larger than 2 GB on 32 bits systems), IPv6 support, RPC support
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(used mainly for NFS), wide-char support, locale support (for
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internationalization), C++ support, thread support. Depending on
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which options you choose, the number of userspace applications and
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libraries visible in Buildroot menus will change: many applications
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and libraries require certain toolchain options to be enabled. Most
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packages show a comment when a certain toolchain option is required
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to be able to enable those packages.
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It is worth noting that whenever one of those options is modified,
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then the entire toolchain and system must be rebuilt. See
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xref:full-rebuild[].
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Advantages of this backend:
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* Well integrated with Buildroot
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* Fast, only builds what's necessary
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Drawbacks of this backend:
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* Rebuilding the toolchain is needed when doing +make clean+, which
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takes time. If you're trying to reduce your build time, consider
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using the _External toolchain backend_.
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[[external-toolchain-backend]]
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External toolchain backend
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^^^^^^^^^^^^^^^^^^^^^^^^^^
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The _external toolchain backend_ allows to use existing pre-built
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cross-compilation toolchains. Buildroot knows about a number of
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well-known cross-compilation toolchains (from
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http://www.linaro.org[Linaro] for ARM,
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http://www.mentor.com/embedded-software/sourcery-tools/sourcery-codebench/editions/lite-edition/[Sourcery
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CodeBench] for ARM, x86, x86-64, PowerPC, MIPS and SuperH,
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https://blackfin.uclinux.org/gf/project/toolchain[Blackfin toolchains
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from ADI], http://git.xilinx.com/[Xilinx toolchains for Microblaze],
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etc.) and is capable of downloading them automatically, or it can be
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pointed to a custom toolchain, either available for download or
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installed locally.
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Then, you have three solutions to use an external toolchain:
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* Use a predefined external toolchain profile, and let Buildroot
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download, extract and install the toolchain. Buildroot already knows
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about a few CodeSourcery, Linaro, Blackfin and Xilinx toolchains.
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Just select the toolchain profile in +Toolchain+ from the
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available ones. This is definitely the easiest solution.
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* Use a predefined external toolchain profile, but instead of having
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Buildroot download and extract the toolchain, you can tell Buildroot
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where your toolchain is already installed on your system. Just
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select the toolchain profile in +Toolchain+ through the available
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ones, unselect +Download toolchain automatically+, and fill the
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+Toolchain path+ text entry with the path to your cross-compiling
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toolchain.
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* Use a completely custom external toolchain. This is particularly
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useful for toolchains generated using crosstool-NG. To do this,
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select the +Custom toolchain+ solution in the +Toolchain+ list. You
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need to fill the +Toolchain path+, +Toolchain prefix+ and +External
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toolchain C library+ options. Then, you have to tell Buildroot what
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your external toolchain supports. If your external toolchain uses
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the 'glibc' library, you only have to tell whether your toolchain
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supports C\+\+ or not and whether it has built-in RPC support. If
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your external toolchain uses the 'uClibc'
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library, then you have to tell Buildroot if it supports largefile,
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IPv6, RPC, wide-char, locale, program invocation, threads and
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C++. At the beginning of the execution, Buildroot will tell you if
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the selected options do not match the toolchain configuration.
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Our external toolchain support has been tested with toolchains from
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CodeSourcery and Linaro, toolchains generated by
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http://crosstool-ng.org[crosstool-NG], and toolchains generated by
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Buildroot itself. In general, all toolchains that support the
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'sysroot' feature should work. If not, do not hesitate to contact the
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developers.
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We do not support toolchains from the
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http://www.denx.de/wiki/DULG/ELDK[ELDK] of Denx, for two reasons:
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* The ELDK does not contain a pure toolchain (i.e just the compiler,
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binutils, the C and C++ libraries), but a toolchain that comes with
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a very large set of pre-compiled libraries and programs. Therefore,
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Buildroot cannot import the 'sysroot' of the toolchain, as it would
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contain hundreds of megabytes of pre-compiled libraries that are
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normally built by Buildroot.
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* The ELDK toolchains have a completely non-standard custom mechanism
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to handle multiple library variants. Instead of using the standard
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GCC 'multilib' mechanism, the ARM ELDK uses different symbolic links
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to the compiler to differentiate between library variants (for ARM
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soft-float and ARM VFP), and the PowerPC ELDK compiler uses a
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+CROSS_COMPILE+ environment variable. This non-standard behaviour
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makes it difficult to support ELDK in Buildroot.
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We also do not support using the distribution toolchain (i.e the
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gcc/binutils/C library installed by your distribution) as the
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toolchain to build software for the target. This is because your
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distribution toolchain is not a "pure" toolchain (i.e only with the
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C/C++ library), so we cannot import it properly into the Buildroot
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build environment. So even if you are building a system for a x86 or
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x86_64 target, you have to generate a cross-compilation toolchain with
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Buildroot or crosstool-NG.
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If you want to generate a custom toolchain for your project, that can
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be used as an external toolchain in Buildroot, our recommandation is
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definitely to build it with http://crosstool-ng.org[crosstool-NG]. We
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recommend to build the toolchain separately from Buildroot, and then
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_import_ it in Buildroot using the external toolchain backend.
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Advantages of this backend:
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* Allows to use well-known and well-tested cross-compilation
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toolchains.
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* Avoids the build time of the cross-compilation toolchain, which is
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often very significant in the overall build time of an embedded
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Linux system.
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* Not limited to uClibc: glibc and eglibc toolchains are supported.
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Drawbacks of this backend:
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* If your pre-built external toolchain has a bug, may be hard to get a
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fix from the toolchain vendor, unless you build your external
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toolchain by yourself using Crosstool-NG.
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/dev management
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~~~~~~~~~~~~~~~
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On a Linux system, the +/dev+ directory contains special files, called
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_device files_, that allow userspace applications to access the
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hardware devices managed by the Linux kernel. Without these _device
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files_, your userspace applications would not be able to use the
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hardware devices, even if they are properly recognized by the Linux
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kernel.
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Under +System configuration+, +/dev management+, Buildroot offers four
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different solutions to handle the +/dev+ directory :
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* The first solution is *Static using device table*. This is the old
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classical way of handling device files in Linux. With this method,
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the device files are persistently stored in the root filesystem
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(i.e they persist accross reboots), and there is nothing that will
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automatically create and remove those device files when hardware
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devices are added or removed from the system. Buildroot therefore
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creates a standard set of device files using a _device table_, the
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default one being stored in +system/device_table_dev.txt+ in the
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Buildroot source code. This file is processed when Buildroot
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generates the final root filesystem image, and the _device files_
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are therefore not visible in the +output/target+ directory. The
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+BR2_ROOTFS_STATIC_DEVICE_TABLE+ option allows to change the
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default device table used by Buildroot, or to add an additional
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device table, so that additional _device files_ are created by
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Buildroot during the build. So, if you use this method, and a
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_device file_ is missing in your system, you can for example create
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a +board/<yourcompany>/<yourproject>/device_table_dev.txt+ file
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that contains the description of your additional _device files_,
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and then you can set +BR2_ROOTFS_STATIC_DEVICE_TABLE+ to
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+system/device_table_dev.txt
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board/<yourcompany>/<yourproject>/device_table_dev.txt+. For more
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details about the format of the device table file, see
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xref:makedev-syntax[].
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* The second solution is *Dynamic using devtmpfs only*. _devtmpfs_ is
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a virtual filesystem inside the Linux kernel that has been
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introduced in kernel 2.6.32 (if you use an older kernel, it is not
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possible to use this option). When mounted in +/dev+, this virtual
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filesystem will automatically make _device files_ appear and
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disappear as hardware devices are added and removed from the
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system. This filesystem is not persistent accross reboots: it is
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filled dynamically by the kernel. Using _devtmpfs_ requires the
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following kernel configuration options to be enabled:
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+CONFIG_DEVTMPFS+ and +CONFIG_DEVTMPFS_MOUNT+. When Buildroot is in
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charge of building the Linux kernel for your embedded device, it
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makes sure that those two options are enabled. However, if you
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build your Linux kernel outside of Buildroot, then it is your
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responsability to enable those two options (if you fail to do so,
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your Buildroot system will not boot).
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* The third solution is *Dynamic using mdev*. This method also relies
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on the _devtmpfs_ virtual filesystem detailed above (so the
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requirement to have +CONFIG_DEVTMPFS+ and +CONFIG_DEVTMPFS_MOUNT+
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enabled in the kernel configuration still apply), but adds the
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+mdev+ userspace utility on top of it. +mdev+ is a program part of
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Busybox that the kernel will call every time a device is added or
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removed. Thanks to the +/etc/mdev.conf+ configuration file, +mdev+
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can be configured to for example, set specific permissions or
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ownership on a device file, call a script or application whenever a
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device appears or disappear, etc. Basically, it allows _userspace_
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to react on device addition and removal events. +mdev+ can for
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example be used to automatically load kernel modules when devices
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appear on the system. +mdev+ is also important if you have devices
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that require a firmware, as it will be responsible for pushing the
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firmware contents to the kernel. +mdev+ is a lightweight
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implementation (with fewer features) of +udev+. For more details
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about +mdev+ and the syntax of its configuration file, see
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http://git.busybox.net/busybox/tree/docs/mdev.txt.
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* The fourth solution is *Dynamic using udev*. This method also
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relies on the _devtmpfs_ virtual filesystem detailed above, but
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adds the +udev+ userspace daemon on top of it. +udev+ is a daemon
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that runs in the background, and gets called by the kernel when a
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device gets added or removed from the system. It is a more
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heavyweight solution than +mdev+, but provides higher flexibility
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and is sometimes mandatory for some system components (systemd for
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example). +udev+ is the mechanism used in most desktop Linux
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distributions. For more details about +udev+, see
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http://en.wikipedia.org/wiki/Udev.
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The Buildroot developers recommandation is to start with the *Dynamic
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using devtmpfs only* solution, until you have the need for userspace
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to be notified when devices are added/removed, or if firmwares are
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needed, in which case *Dynamic using mdev* is usually a good solution.
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init system
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~~~~~~~~~~~
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The _init_ program is the first userspace program started by the
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kernel (it carries the PID number 1), and is responsible for starting
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the userspace services and programs (for example: web server,
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graphical applications, other network servers, etc.).
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Buildroot allows to use three different types of init systems, which
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can be chosen from +System configuration+, +Init system+:
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* The first solution is *Busybox*. Amongst many programs, Busybox has
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an implementation of a basic +init+ program, which is sufficient
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for most embedded systems. Enabling the +BR2_INIT_BUSYBOX+ will
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ensure Busybox will build and install its +init+ program. This is
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the default solution in Buildroot. The Busybox +init+ program will
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read the +/etc/inittab+ file at boot to know what to do. The syntax
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of this file can be found in
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http://git.busybox.net/busybox/tree/examples/inittab (note that
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Busybox +inittab+ syntax is special: do not use a random +inittab+
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documentation from the Internet to learn about Busybox
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+inittab+). The default +inittab+ in Buildroot is stored in
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+system/skeleton/etc/inittab+. Apart from mounting a few important
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filesystems, the main job the default inittab does is to start the
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+/etc/init.d/rcS+ shell script, and start a +getty+ program (which
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provides a login prompt).
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* The second solution is *systemV*. This solution uses the old
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traditional _sysvinit_ program, packed in Buildroot in
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+package/sysvinit+. This was the solution used in most desktop
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Linux distributions, until they switched to more recent
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alternatives such as Upstart or Systemd. +sysvinit+ also works with
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an +inittab+ file (which has a slightly different syntax than the
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one from Busybox). The default +inittab+ installed with this init
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solution is located in +package/sysvinit/inittab+.
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* The third solution is *systemd*. +systemd+ is the new generation
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init system for Linux. It does far more than traditional _init_
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programs: aggressive parallelization capabilities, uses socket and
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D-Bus activation for starting services, offers on-demand starting
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of daemons, keeps track of processes using Linux control groups,
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supports snapshotting and restoring of the system state,
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etc. +systemd+ will be useful on relatively complex embedded
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systems, for example the ones requiring D-Bus and services
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communicating between each other. It is worth noting that +systemd+
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brings a fairly big number of large dependencies: +dbus+, +udev+
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and more. For more details about +systemd+, see
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http://www.freedesktop.org/wiki/Software/systemd.
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The solution recommended by Buildroot developers is to use the
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*Busybox init* as it is sufficient for most embedded
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systems. *systemd* can be used for more complex situations.
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