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 File.........: 5 - Using the toolchain.txt
 Copyright....: (C) 2010 Yann E. MORIN <yann.morin.1998@free.fr>
 License......: Creative Commons Attribution Share Alike (CC-by-sa), v2.5


 Using the toolchain  /
 ____________________/


 Using the toolchain is as simple as adding the toolchain's bin directory in
 your PATH, such as:
   export PATH="${PATH}:/your/toolchain/path/bin"

 and then using the '--host' tuple to tell the build systems to use your
 toolchain (if the software package uses the autotools system you should
 also pass --build, for completeness):
   ./configure --host=your-host-tuple --build=your-build-tuple
 or
   make CC=your-host-tuple-gcc
 or
   make CROSS_COMPILE=your-host-tuple-
 and so on...

 (Note: in the above example, 'host' refers to the host of your program,
 not the host of the toolchain; and 'build' refers to the machine where
 you build your program, that is the host of the toolchain.)


 Assembling a root filesystem  /
 _____________________________/


 Assembling a root filesystem for a target device requires the successive
 building of a set of software packages for the target architecture. Building
 a package potentially requires artifacts which were generated as part of an
 earlier build. Note that not all artifacts which are installed as part of a
 package are desirable on a target's root filesystem (e.g. man/info files,
 include files, etc.). Therefore we must distinguish between a 'staging'
 directory and a 'rootfs' directory.

 A 'staging' directory is a location into which we install all the build
 artifacts. We can then point future builds to this location so they can find
 the appropriate header and library files. A 'rootfs' directory is a location
 into which we place only the files we want to have on our target.

 There are four schools of thought here:

 1) Install directly into the sysroot of the toolchain.

    By default (i.e. if you don't pass any arguments to the tools which
    would change this behaviour) the toolchain that is built by
    crosstool-NG will only look in its toolchain directories for system
    header and library files:

 #include "..." search starts here:
 #include <...> search starts here:
 <ct-ng install path>/lib/gcc/<host tuple>/4.5.2/include
 <ct-ng install path>/lib/gcc/<host tuple>/4.5.2/include-fixed
 <ct-ng install path>/lib/gcc/<host tuple>/4.5.2/../../../../<host tuple>/include
 <ct-ng install path>/<host tuple>/sysroot/usr/include

    In other words, the compiler will automagically find headers and
    libraries without extra flags if they are installed under the
    toolchain's sysroot directory.

    However, this is bad because the toolchain gets poluted, and can
    not be re-used.

    $ ./configure --build=<build tuple> --host=<host tuple> \
          --prefix=/usr --enable-foo-bar...
    $ make
    $ make DESTDIR=/<ct-ng install path>/<host tuple>/sysroot install

 2) Copy the toolchain's sysroot to the 'staging' area.

    If you start off by copying the toolchain's sysroot directory to your
    staging area, you can simply proceed to install all your packages'
    artifacts to the same staging area. You then only need to specify a
    '--sysroot=<staging area>' option to the compiler of any subsequent
    builds and all your required header and library files will be found/used.

    This is a viable option, but requires the user to always specify CFLAGS
    in order to include --sysroot=<staging area>, or requires the use of a
    wrapper to a few select tools (gcc, ld...) to pass this flag.

    Instead of polluting the toolchain's sysroot you are copying its contents
    to a new location and polluting the contents in that new location. By
    specifying the --sysroot option you're effectively abandoning the default
    sysroot in favour of your own.

    Incidentally this is what buildroot does using a wrapper, when using an
    external toolchain.

    $ cp -a $(<host tuple>-gcc --your-cflags-except-sysroot -print-sysroot) \
          /path/to/staging
    $ ./configure --build=<build tuple> --host=<host tuple>          \
                  --prefix=/usr --enable-foo-bar...                  \
                  CC="<host tuple>-gcc --syroot=/path/to/staging"    \
                  CXX="<host tuple>-g++ --sysroot=/path/to/staging"  \
                  LD="<host tuple>-ld --sysroot=/path/to/staging"    \
                  AND_SO_ON="tuple-andsoon --sysroot=/path/to/staging"
    $ make
    $ make DESTDIR=/path/to/staging install

 3) Use separate staging and sysroot directories.

    In this scenario you use a staging area to install programs, but you do
    not pre-fill that staging area with the toolchain's sysroot. In this case
    the compiler will find the system includes and libraries in its sysroot
    area but you have to pass appropriate CPPFLAGS and LDFLAGS to tell it
    where to find your headers and libraries from your staging area (or use
    a wrapper).

    $ ./configure --build=<build tuple> --host=<host tuple>          \
                  --prefix=/usr --enable-foo-bar...                  \
                  CPPFLAGS="-I/path/to/staging/usr/include"          \
                  LDFLAGS="-L/path/to/staging/lib -L/path/to/staging/usr/lib"
    $ make
    $ make DESTDIR=/path/to/staging install

 4) A mix of 2) and 3), using carefully crafted union mounts.

    The staging area is a union mount of:
       - the sysroot as a read-only branch
       - the real staging area as a read-write branch
    This also requires passing --sysroot to point to the union mount, but has
    other advantages, such as allowing per-package staging, and a few more
    obscure pros. It also has its disadvantages, as it potentially requires
    non-root users to create union mounts. Additionally, union mounts are not
    yet mainstream in the Linux kernel, so it requires patching. There is a
    FUSE-based unionfs implementation, but development is almost stalled,
    and there are a few gotchas...

    $ (good luck!)


 It is strongly advised not to use the toolchain sysroot directory as an
 install directory (i.e. option 1) for your programs/packages. If you do so,
 you will not be able to use your toolchain for another project. It is even
 strongly advised that your toolchain is chmod-ed to read-only once
 successfully install, so that you don't go polluting your toolchain with
 your programs'/packages' files. This can be achieved by selecting the
 "Render the toolchain read-only" from crosstool-NG's "Paths and misc options"
 configuration page.

 Thus, when you build a program/package, install it in a separate, staging,
 directory and let the cross-toolchain continue to use its own, pristine,
 sysroot directory.

 When you are done building and want to assemble your rootfs you could simply
 take the full contents of your staging directory and use the 'populate'
 script to add in the necessary files from the sysroot. However, the staging
 area you have created will include lots of build artifacts that you won't
 necessarily want/need on your target. For example: static libraries, header
 files, linking helper files, man/info pages. You'll also need to add various
 configuration files, scripts, and directories to the rootfs so it will boot.

 Therefore you'll probably end up creating a separate rootfs directory which
 you will populate from the staging area, necessary extras, and then use
 crosstool-NG's populate script to add the necessary sysroot libraries.


 The 'populate' script |
 ----------------------+

 When your root directory is ready, it is still missing some important bits: the
 toolchain's libraries. To populate your root directory with those libs, just
 run:
   your-target-tuple-populate -s /your/root -d /your/root-populated

 This will copy /your/root into /your/root-populated, and put the needed and only
 the needed libraries there. Thus you don't pollute /your/root with any cruft that
 would no longer be needed should you have to remove stuff. /your/root always
 contains only those things you install in it.

 You can then use /your/root-populated to build up your file system image, a
 tarball, or to NFS-mount it from your target, or whatever you need.

 The populate script accepts the following options:

  -s src_dir
     Use 'src_dir' as the un-populated root directory.

  -d dst_dir
     Put the populated root directory in 'dst_dir'.

  -l lib1 [...]
     Always add specified libraries.

  -L file
     Always add libraries listed in 'file'.

  -f
     Remove 'dst_dir' if it previously existed; continue even if any library
     specified with -l or -L is missing.

  -v
     Be verbose, and tell what's going on (you can see exactly where libs are
     coming from).

  -h
     Print the help.

 See 'your-target-tuple-populate -h' for more information on the options.

 Here is how populate works:

   1) performs some sanity checks:
      - src_dir and dst_dir are specified
      - src_dir exists
      - unless forced, dst_dir does not exist
      - src_dir != dst_dir

   2) copy src_dir to dst_dir

   3) add forced libraries to dst_dir
      - build the list from -l and -L options
      - get forced libraries from the sysroot (see below for heuristics)
        - abort on the first missing library, unless -f is specified

   4) add all missing libraries to dst_dir
      - scan dst_dir for every ELF files that are 'executable' or
        'shared object'
      - list the "NEEDED Shared library" fields
        - check if the library is already in dst_dir/lib or dst_dir/usr/lib
        - if not, get the library from the sysroot
          - if it's in sysroot/lib, copy it to dst_dir/lib
          - if it's in sysroot/usr/lib, copy it to dst_dir/usr/lib
          - in both cases, use the SONAME of the library to create the file
            in dst_dir
          - if it was not found in the sysroot, this is an error.
	File.........: 5 - Using the toolchain.txt
	Copyright....: (C) 2010 Yann E. MORIN <yann.morin.1998@free.fr>
	License......: Creative Commons Attribution Share Alike (CC-by-sa), v2.5


	Using the toolchain /
	____________________/


	Using the toolchain is as simple as adding the toolchain's bin directory in
	your PATH, such as:
	export PATH="${PATH}:/your/toolchain/path/bin"

	and then using the '--host' tuple to tell the build systems to use your
	toolchain (if the software package uses the autotools system you should
	also pass --build, for completeness):
	./configure --host=your-host-tuple --build=your-build-tuple
	or
	make CC=your-host-tuple-gcc
	or
	make CROSS_COMPILE=your-host-tuple-
	and so on...

	(Note: in the above example, 'host' refers to the host of your program,
	not the host of the toolchain; and 'build' refers to the machine where
	you build your program, that is the host of the toolchain.)


	Assembling a root filesystem /
	_____________________________/


	Assembling a root filesystem for a target device requires the successive
	building of a set of software packages for the target architecture. Building
	a package potentially requires artifacts which were generated as part of an
	earlier build. Note that not all artifacts which are installed as part of a
	package are desirable on a target's root filesystem (e.g. man/info files,
	include files, etc.). Therefore we must distinguish between a 'staging'
	directory and a 'rootfs' directory.

	A 'staging' directory is a location into which we install all the build
	artifacts. We can then point future builds to this location so they can find
	the appropriate header and library files. A 'rootfs' directory is a location
	into which we place only the files we want to have on our target.

	There are four schools of thought here:

	1) Install directly into the sysroot of the toolchain.

	By default (i.e. if you don't pass any arguments to the tools which
	would change this behaviour) the toolchain that is built by
	crosstool-NG will only look in its toolchain directories for system
	header and library files:

	#include "..." search starts here:
	#include <...> search starts here:
	<ct-ng install path>/lib/gcc/<host tuple>/4.5.2/include
	<ct-ng install path>/lib/gcc/<host tuple>/4.5.2/include-fixed
	<ct-ng install path>/lib/gcc/<host tuple>/4.5.2/../../../../<host tuple>/include
	<ct-ng install path>/<host tuple>/sysroot/usr/include

	In other words, the compiler will automagically find headers and
	libraries without extra flags if they are installed under the
	toolchain's sysroot directory.

	However, this is bad because the toolchain gets poluted, and can
	not be re-used.

	$ ./configure --build=<build tuple> --host=<host tuple> \
	--prefix=/usr --enable-foo-bar...
	$ make
	$ make DESTDIR=/<ct-ng install path>/<host tuple>/sysroot install

	2) Copy the toolchain's sysroot to the 'staging' area.

	If you start off by copying the toolchain's sysroot directory to your
	staging area, you can simply proceed to install all your packages'
	artifacts to the same staging area. You then only need to specify a
	'--sysroot=<staging area>' option to the compiler of any subsequent
	builds and all your required header and library files will be found/used.

	This is a viable option, but requires the user to always specify CFLAGS
	in order to include --sysroot=<staging area>, or requires the use of a
	wrapper to a few select tools (gcc, ld...) to pass this flag.

	Instead of polluting the toolchain's sysroot you are copying its contents
	to a new location and polluting the contents in that new location. By
	specifying the --sysroot option you're effectively abandoning the default
	sysroot in favour of your own.

	Incidentally this is what buildroot does using a wrapper, when using an
	external toolchain.

	$ cp -a $(<host tuple>-gcc --your-cflags-except-sysroot -print-sysroot) \
	/path/to/staging
	$ ./configure --build=<build tuple> --host=<host tuple> \
	--prefix=/usr --enable-foo-bar... \
	CC="<host tuple>-gcc --syroot=/path/to/staging" \
	CXX="<host tuple>-g++ --sysroot=/path/to/staging" \
	LD="<host tuple>-ld --sysroot=/path/to/staging" \
	AND_SO_ON="tuple-andsoon --sysroot=/path/to/staging"
	$ make
	$ make DESTDIR=/path/to/staging install

	3) Use separate staging and sysroot directories.

	In this scenario you use a staging area to install programs, but you do
	not pre-fill that staging area with the toolchain's sysroot. In this case
	the compiler will find the system includes and libraries in its sysroot
	area but you have to pass appropriate CPPFLAGS and LDFLAGS to tell it
	where to find your headers and libraries from your staging area (or use
	a wrapper).

	$ ./configure --build=<build tuple> --host=<host tuple> \
	--prefix=/usr --enable-foo-bar... \
	CPPFLAGS="-I/path/to/staging/usr/include" \
	LDFLAGS="-L/path/to/staging/lib -L/path/to/staging/usr/lib"
	$ make
	$ make DESTDIR=/path/to/staging install

	4) A mix of 2) and 3), using carefully crafted union mounts.

	The staging area is a union mount of:
	- the sysroot as a read-only branch
	- the real staging area as a read-write branch
	This also requires passing --sysroot to point to the union mount, but has
	other advantages, such as allowing per-package staging, and a few more
	obscure pros. It also has its disadvantages, as it potentially requires
	non-root users to create union mounts. Additionally, union mounts are not
	yet mainstream in the Linux kernel, so it requires patching. There is a
	FUSE-based unionfs implementation, but development is almost stalled,
	and there are a few gotchas...

	$ (good luck!)


	It is strongly advised not to use the toolchain sysroot directory as an
	install directory (i.e. option 1) for your programs/packages. If you do so,
	you will not be able to use your toolchain for another project. It is even
	strongly advised that your toolchain is chmod-ed to read-only once
	successfully install, so that you don't go polluting your toolchain with
	your programs'/packages' files. This can be achieved by selecting the
	"Render the toolchain read-only" from crosstool-NG's "Paths and misc options"
	configuration page.

	Thus, when you build a program/package, install it in a separate, staging,
	directory and let the cross-toolchain continue to use its own, pristine,
	sysroot directory.

	When you are done building and want to assemble your rootfs you could simply
	take the full contents of your staging directory and use the 'populate'
	script to add in the necessary files from the sysroot. However, the staging
	area you have created will include lots of build artifacts that you won't
	necessarily want/need on your target. For example: static libraries, header
	files, linking helper files, man/info pages. You'll also need to add various
	configuration files, scripts, and directories to the rootfs so it will boot.

	Therefore you'll probably end up creating a separate rootfs directory which
	you will populate from the staging area, necessary extras, and then use
	crosstool-NG's populate script to add the necessary sysroot libraries.


	The 'populate' script \|
	----------------------+

	When your root directory is ready, it is still missing some important bits: the
	toolchain's libraries. To populate your root directory with those libs, just
	run:
	your-target-tuple-populate -s /your/root -d /your/root-populated

	This will copy /your/root into /your/root-populated, and put the needed and only
	the needed libraries there. Thus you don't pollute /your/root with any cruft that
	would no longer be needed should you have to remove stuff. /your/root always
	contains only those things you install in it.

	You can then use /your/root-populated to build up your file system image, a
	tarball, or to NFS-mount it from your target, or whatever you need.

	The populate script accepts the following options:

	-s src_dir
	Use 'src_dir' as the un-populated root directory.

	-d dst_dir
	Put the populated root directory in 'dst_dir'.

	-l lib1 [...]
	Always add specified libraries.

	-L file
	Always add libraries listed in 'file'.

	-f
	Remove 'dst_dir' if it previously existed; continue even if any library
	specified with -l or -L is missing.

	-v
	Be verbose, and tell what's going on (you can see exactly where libs are
	coming from).

	-h
	Print the help.

	See 'your-target-tuple-populate -h' for more information on the options.

	Here is how populate works:

	1) performs some sanity checks:
	- src_dir and dst_dir are specified
	- src_dir exists
	- unless forced, dst_dir does not exist
	- src_dir != dst_dir

	2) copy src_dir to dst_dir

	3) add forced libraries to dst_dir
	- build the list from -l and -L options
	- get forced libraries from the sysroot (see below for heuristics)
	- abort on the first missing library, unless -f is specified

	4) add all missing libraries to dst_dir
	- scan dst_dir for every ELF files that are 'executable' or
	'shared object'
	- list the "NEEDED Shared library" fields
	- check if the library is already in dst_dir/lib or dst_dir/usr/lib
	- if not, get the library from the sysroot
	- if it's in sysroot/lib, copy it to dst_dir/lib
	- if it's in sysroot/usr/lib, copy it to dst_dir/usr/lib
	- in both cases, use the SONAME of the library to create the file
	in dst_dir
	- if it was not found in the sysroot, this is an error.