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365 lines
14 KiB
Plaintext
File.........: overview.txt
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Content......: Overview of how crosstool-NG works.
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Copyrigth....: (C) 2007 Yann E. MORIN <yann.morin.1998@anciens.enib.fr>
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License......: Creative Commons Attribution Share Alike (CC-by-sa), v2.5
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________________
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/
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Introduction /
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_____________/
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crosstool-NG aims at building toolchains. Toolchains are an essential component
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in a software development project. It will compile, assemble and link the code
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that is being developped. Some pieces of the toolchain will eventually end up
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in the resulting binary/ies: static libraries are but an example.
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So, a toolchain is a very sensitive piece of software, as any bug in one of the
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components, or a poorly configured component, can lead to execution problems,
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ranging from poor performance, to applications ending unexpectedly, to
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mis-behaving software (which more than often is hard to detect), to hardware
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damage, or even to human risks (which is more than regretable).
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Toolchains are made of different piece of software, each being quite complex
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and requiring specially crafted options to build and work seamlessly. This
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is usually not that easy, even in the not-so-trivial case of native toolchains.
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The work reaches a higher degree of complexity when it comes to cross-
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compilation, where it can become quite a nightmare...
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Some cross-toolchains exist on the internet, and can be used for general
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development, but they have a number of limitations:
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- they can be general purpose, in that they are configured for the majority:
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no optimisation for your specific target,
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- they can be prepared for a specific target and thus are not easy to use,
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nor optimised for, or even supporting your target,
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- they often are using ageing components (compiler, C library, etc...) not
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supporting special features of your shiny new processor;
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On the other side, these toolchain offer some advantages:
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- they are ready to use and quite easy to install and setup,
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- they are proven if used by a wide community.
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But once you want to get all the juice out of your specific hardware, you will
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want to build your own toolchain. This is where crosstool-NG comes into play.
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There are also a number of tools that builds toolchains for specific needs,
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which is not really scalable. Examples are:
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- buildroot (buildroot.uclibc.org) whose main puprpose is to build root file
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systems, hence the name. But once you have your toolchain with buildroot,
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part of it is installed in the root-to-be, so if you want to build a whole
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new root, you either have to save the existing one as a template and
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restore it later, or restart again from scratch. This is not convenient,
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- ptxdist (www.pengutronix.de/software/ptxdist), whose purpose is very
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similar to buildroot,
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- other projects (openembeded.org for example), which is again used to
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build root file systems.
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crosstool-NG is really targetted at building toolchains, and only toolchains.
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It is then up to you to use it the way you want.
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___________
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/
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History /
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________/
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crosstool was first 'conceived' by Dan Kegel, which offered it to the community,
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as a set of scripts, a repository of patches, and some pre-configured, general
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purpose setup files to be used to configure crosstool. This is available at
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http://www.kegel.com/crosstool, and the subversion repository is hosted on
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google at http://code.google.com/p/crosstool/.
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At the time of writing, crosstool only supports building with one C library,
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namely glibc, and one C compiler, gcc; it is cripled with historical support
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for legacy components, and is some kind of a mess to upgrade. Also, submited
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patches take a loooong time before they are integrated mainline.
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I once managed to add support for uClibc-based toolchains, but it did not make
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into mainline, mostly because I don't have time to port the patch forward to
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the new versions, due in part to the big effort it was taking.
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So I decided to clean up crosstool in the state it was, re-order the things
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in place, and add appropriate support for what I needed, that is uClibc
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support. That was a disaster, as inclusion into mainline is slow as hell,
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and the changes were so numerous.
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The only option left to me was rewrite crosstool from scratch. I decided to go
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this way, and name the new implementation crosstool-NG, standing for crosstool
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Next Generation, as many other comunity projects do, and as a wink at the TV
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series "Star Trek: The Next Generation". ;-)
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____________________________
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/
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Configuring crosstool-NG /
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_________________________/
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crosstool-NG is configured the same way you configure your Linux kernel: by
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using a curses-based menu. It is assumed you now how to handle this.
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To enter the menu, type:
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ct-ng menuconfig
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Almost every config item has a help entry. Read them carefully.
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String and number options can refer to environment variables. In such a case,
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you must use the shell syntax: ${VAR}. You shall neither single- nor double-
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quote the string options.
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There are three environment variables that are computed by crosstool-NG, and
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that you can use:
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CT_TARGET:
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It represents the target triplet you are building for. You can use it for
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example in the installation/prefix directory, such as:
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/opt/x-tools/${CT_TARGET}
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CT_TOP_DIR:
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The top directory where crosstool-NG is running. You shouldn't need it in
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most cases. There is one case where you may need it: if you have local
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patches and you store them in your running directory, you can refer to them
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by using CT_TOP_DIR, such as:
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${CT_TOP_DIR}/patches.myproject
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CT_VERSION:
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The version of crosstool-NG you are using. Not much use for you, but it's
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there if you need it.
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Interesting config options |
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---------------------------*
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CT_LOCAL_TARBALLS_DIR:
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If you already have sone tarballs in a direcotry, enter it here. That will
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speed up the retrieving phase, where crosstool-NG would otherwise download
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those tarballs.
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CT_PREFIX_DIR:
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This is where the toolchain will be installed in (and for now, where it
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will run from).
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CT_TARGET_VENDOR:
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An identifier for your toolchain, will take place in the vendor part of the
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target triplet. It shall *not* contain spaces or dashes. Usually, keep it
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to a one-word string, or use underscores to separate words if you need.
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Avoid dots, commas, and special characters.
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CT_TARGET_ALIAS:
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An alias for the toolchian. It will be used as a prefix to the toolchain
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tools. For example, you will have ${CT_TARGET_ALIAS}-gcc
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Also, if you think you don't see enough versions, you can try to enable one of
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those:
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CT_OBSOLETE:
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Show obsolete versions or tools. Most of the time, you don't want to base
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your toolchain on too old a version (of gcc, for example). But at times, it
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can come handy to use such an old version for regression tests. Those old
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versions are hidden behind CT_BSOLETE.
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CT_EXPERIMENTAL:
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Show experimental versions or tools. Again, you might not want to base your
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toolchain on too recent tools (eg. gcc) for production. But if you need a
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feature present only in a recent version, or a new tool, you can find them
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hidden behind CT_EXPERIMENTAL.
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CT_BROKEN:
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Show broken versions or tools. Some usefull tools are currently broken: they
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won't compile, run, or worse, cause defects when running. But if you are
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brave enough, you can try and debug them. They are hidden behind CT_BROKEN,
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which itself is hiddent behind EXPERIMENTAL.
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________________________
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/
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Running crosstool-NG /
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_____________________/
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crosstool-NG is configured by a configurator presenting a menu-stuctured set of
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options. These options let you specify the way you want your toolchain built,
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where you want it installed, what architecture and specific processor it
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will support, the version of the components you want to use, etc... The
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value for those options are then stored in a configuration file.
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To build the toolchain, simply type:
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ct-ng build
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This will use the above configuration to retrieve, extract and patch the
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components, build, install and eventually test your newly built toolchain.
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You are then free to add the toolchain /bin directory in your PATH to use
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it at will.
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In any case, you can get some terse help. Just type:
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ct-ng help
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or:
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man 1 ct-ng
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Stoping and restarting a build |
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-------------------------------*
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If you want to stop the build after a step you are debugging, you can pass the
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variable STOP to make:
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ct-ng STOP=some_step
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Conversely, if you want to restart a build at a specific step you are
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debugging, you can pass the RESTART variable to make:
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ct-ng RESTART=some_step
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Alternatively, you can call make with the name of a step to just do that step:
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ct-ng libc_headers
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is equivalent to:
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ct-ng RESTART=libs_headers STOP=libc_headers
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The shortcuts -step_name and step_name- allow to respectively stop or restart
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at that step. Thus:
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ct-ng -libc_headers and: ct-ng libc_headers-
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are equivalent to:
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ct-ng STOP=libc_headers and: ct-ng RESTART=libc_headers
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To obtain the list of acceptable steps, please call:
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ct-ng liststeps
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Note that in order to restart a build, you'll have to say 'Y' to the config
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option CT_DEBUG_CT_SAVE_STEPS, and that the previous build effectively went
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that far.
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Testing all toolchains at once |
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-------------------------------*
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You can test-build all samples; simply call:
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ct-ng regtest
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_______________________
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/
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Using the toolchain /
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____________________/
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Using the toolchain is as simple as adding the toolchain's bin directory in
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your PATH, such as:
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export PATH="${PATH}:/your/toolchain/path/bin"
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and then using the target triplet to tell the build systems to use your
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toolchain:
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./configure --target=your-target-triplet
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make CC=your-target-triplet-gcc
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make CROSS_COMPILE=your-target-triplet-
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and so on...
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When your root directory is ready, it is still missing some important bits: the
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toolchain's libraries. To populate your root directory with those libs, just
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run:
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your-target-triplet-populate -s /your/root -d /your/root-populated
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This will copy /your/root into /your/root-populated, and put the needed and only
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the needed libraries there. Thus you don't polute /your/root with any cruft that
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would no longer be needed should you have to remove stuff. /your/root always
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contains only those things you install in it.
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You can then use /your/root-populated to build up your file system image, a
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tarball, or to NFS-mount it from your target, or whatever you need.
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___________________
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/
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Toolchain types /
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________________/
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There are four kinds of toolchains you could encounter.
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First off, you must understand the following: when it comes to compilers there
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are up to four machines involved:
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1) the machine configuring the toolchain components: the config machine
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2) the machine building the toolchain components: the build machine
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3) the machine running the toolchain: the host machine
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4) the machine the toolchain is generating code for: the target machine
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We can most of the time assume that the config machine and the build machine
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are the same. Most of the time, this will be true. The only time it isn't
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is if you're using distributed compilation (such as distcc). Let's forget
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this for the sake of simplicity.
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So we're left with three machines:
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- build
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- host
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- target
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Any toolchain will involve those three machines. You can be as pretty sure of
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this as "2 and 2 are 4". Here is how they come into play:
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1) build == host == target
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This is a plain native toolchain, targetting the exact same machine as the
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one it is built on, and running again on this exact same machine. You have
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to build such a toolchain when you want to use an updated component, such
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as a newer gcc for example.
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crosstool-NG calls it "native".
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2) build == host != target
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This is a classic cross-toolchain, which is expected to be run on the same
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machine it is compiled on, and generate code to run on a second machine,
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the target.
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crosstool-NG calls it "cross".
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3) build != host == target
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Such a toolchain is also a native toolchain, as it targets the same machine
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as it runs on. But it is build on another machine. You want such a
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toolchain when porting to a new architecture, or if the build machine is
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much faster than the host machine.
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crosstool-NG calls it "cross-native".
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4) build != host != target
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This one is called a canadian-toolchain (*), and is tricky. The three
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machines in play are different. You might want such a toolchain if you
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have a fast build machine, but the users will use it on another machine,
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and will produce code to run on a third machine.
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crosstool-NG calls it "canadian".
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crosstool-NG can build all these kinds of toolchains (or is aiming at it,
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anyway!)
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(*) The term Canadian Cross came about because at the time that these issues
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were all being hashed out, Canada had three national political parties.
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http://en.wikipedia.org/wiki/Cross_compiler
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_____________
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Internals /
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__________/
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Internally, crosstool-NG is script-based. To ease usage, the frontend is
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Makefile-based.
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Makefile front-end |
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-------------------*
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The entry point to crosstool-NG is the Makefile script "ct-ng". Calling this
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script with an action will act exactly as if the Makefile was in the current
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working directory and make was called with the action as rule. Thus:
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ct-ng menuconfig
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is equivalent to having the Makefile in CWD, and calling:
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make menuconfig
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Having ct-ng as it is avoids copying the Makefile everywhere, and acts as a
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traditional command.
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ct-ng loads sub- Makefiles from the library directory $(CT_LIB_DIR), as set up
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at configuration time with ./configure.
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ct-ng also search for config files, sub-tools, samples, scripts and patches in
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that library directory.
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Kconfig parser |
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---------------*
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The kconfig language is a hacked version, vampirised from the toybox project
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by Rob LANDLEY (http://www.landley.net/code/toybox/), itself coming from the
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Linux kernel (http://www.linux.org/ http://www.kernel.org/), and (heavily)
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adapted to my needs.
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The kconfig parsers (conf and mconf) are not installed pre-built, but as
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source files. Thus you can have the directory where crosstool-NG is installed,
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exported (via NFS or whatever) and have clients with different architectures
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use the same crosstool-NG installation, and most notably, the same set of
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patches.
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Build scripts |
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--------------*
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To Be Written later...
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