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Since anciens.enib.fr has been dead for two months now, without any hope of recovery, update my e-mail to point to @free.fr instead. Reported-by: "Bryan Hundven" <bryanhundven@gmail.com> Signed-off-by: "Yann E. MORIN" <yann.morin.1998@free.fr>
232 lines
9.5 KiB
Plaintext
232 lines
9.5 KiB
Plaintext
File.........: 5 - Using the toolchain.txt
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Copyright....: (C) 2010 Yann E. MORIN <yann.morin.1998@free.fr>
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License......: Creative Commons Attribution Share Alike (CC-by-sa), v2.5
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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 '--host' tuple to tell the build systems to use your
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toolchain (if the software package uses the autotools system you should
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also pass --build, for completeness):
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./configure --host=your-host-tuple --build=your-build-tuple
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or
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make CC=your-host-tuple-gcc
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or
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make CROSS_COMPILE=your-host-tuple-
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and so on...
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(Note: in the above example, 'host' refers to the host of your program,
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not the host of the toolchain; and 'build' refers to the machine where
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you build your program, that is the host of the toolchain.)
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Assembling a root filesystem /
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_____________________________/
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Assembling a root filesystem for a target device requires the successive
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building of a set of software packages for the target architecture. Building
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a package potentially requires artifacts which were generated as part of an
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earlier build. Note that not all artifacts which are installed as part of a
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package are desirable on a target's root filesystem (e.g. man/info files,
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include files, etc.). Therefore we must distinguish between a 'staging'
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directory and a 'rootfs' directory.
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A 'staging' directory is a location into which we install all the build
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artifacts. We can then point future builds to this location so they can find
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the appropriate header and library files. A 'rootfs' directory is a location
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into which we place only the files we want to have on our target.
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There are four schools of thought here:
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1) Install directly into the sysroot of the toolchain.
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By default (i.e. if you don't pass any arguments to the tools which
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would change this behaviour) the toolchain that is built by
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crosstool-NG will only look in its toolchain directories for system
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header and library files:
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#include "..." search starts here:
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#include <...> search starts here:
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<ct-ng install path>/lib/gcc/<host tuple>/4.5.2/include
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<ct-ng install path>/lib/gcc/<host tuple>/4.5.2/include-fixed
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<ct-ng install path>/lib/gcc/<host tuple>/4.5.2/../../../../<host tuple>/include
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<ct-ng install path>/<host tuple>/sysroot/usr/include
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In other words, the compiler will automagically find headers and
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libraries without extra flags if they are installed under the
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toolchain's sysroot directory.
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However, this is bad because the toolchain gets poluted, and can
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not be re-used.
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$ ./configure --build=<build tuple> --host=<host tuple> \
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--prefix=/usr --enable-foo-bar...
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$ make
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$ make DESTDIR=/<ct-ng install path>/<host tuple>/sysroot install
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2) Copy the toolchain's sysroot to the 'staging' area.
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If you start off by copying the toolchain's sysroot directory to your
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staging area, you can simply proceed to install all your packages'
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artifacts to the same staging area. You then only need to specify a
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'--sysroot=<staging area>' option to the compiler of any subsequent
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builds and all your required header and library files will be found/used.
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This is a viable option, but requires the user to always specify CFLAGS
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in order to include --sysroot=<staging area>, or requires the use of a
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wrapper to a few select tools (gcc, ld...) to pass this flag.
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Instead of polluting the toolchain's sysroot you are copying its contents
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to a new location and polluting the contents in that new location. By
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specifying the --sysroot option you're effectively abandoning the default
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sysroot in favour of your own.
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Incidentally this is what buildroot does using a wrapper, when using an
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external toolchain.
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$ cp -a $(<host tuple>-gcc --your-cflags-except-sysroot -print-sysroot) \
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/path/to/staging
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$ ./configure --build=<build tuple> --host=<host tuple> \
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--prefix=/usr --enable-foo-bar... \
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CC="<host tuple>-gcc --syroot=/path/to/staging" \
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CXX="<host tuple>-g++ --sysroot=/path/to/staging" \
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LD="<host tuple>-ld --sysroot=/path/to/staging" \
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AND_SO_ON="tuple-andsoon --sysroot=/path/to/staging"
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$ make
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$ make DESTDIR=/path/to/staging install
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3) Use separate staging and sysroot directories.
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In this scenario you use a staging area to install programs, but you do
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not pre-fill that staging area with the toolchain's sysroot. In this case
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the compiler will find the system includes and libraries in its sysroot
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area but you have to pass appropriate CPPFLAGS and LDFLAGS to tell it
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where to find your headers and libraries from your staging area (or use
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a wrapper).
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$ ./configure --build=<build tuple> --host=<host tuple> \
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--prefix=/usr --enable-foo-bar... \
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CPPFLAGS="-I/path/to/staging/usr/include" \
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LDFLAGS="-L/path/to/staging/lib -L/path/to/staging/usr/lib"
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$ make
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$ make DESTDIR=/path/to/staging install
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4) A mix of 2) and 3), using carefully crafted union mounts.
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The staging area is a union mount of:
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- the sysroot as a read-only branch
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- the real staging area as a read-write branch
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This also requires passing --sysroot to point to the union mount, but has
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other advantages, such as allowing per-package staging, and a few more
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obscure pros. It also has its disadvantages, as it potentially requires
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non-root users to create union mounts. Additionally, union mounts are not
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yet mainstream in the Linux kernel, so it requires patching. There is a
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FUSE-based unionfs implementation, but development is almost stalled,
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and there are a few gotchas...
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$ (good luck!)
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It is strongly advised not to use the toolchain sysroot directory as an
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install directory (i.e. option 1) for your programs/packages. If you do so,
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you will not be able to use your toolchain for another project. It is even
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strongly advised that your toolchain is chmod-ed to read-only once
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successfully install, so that you don't go polluting your toolchain with
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your programs'/packages' files. This can be achieved by selecting the
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"Render the toolchain read-only" from crosstool-NG's "Paths and misc options"
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configuration page.
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Thus, when you build a program/package, install it in a separate, staging,
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directory and let the cross-toolchain continue to use its own, pristine,
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sysroot directory.
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When you are done building and want to assemble your rootfs you could simply
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take the full contents of your staging directory and use the 'populate'
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script to add in the necessary files from the sysroot. However, the staging
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area you have created will include lots of build artifacts that you won't
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necessarily want/need on your target. For example: static libraries, header
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files, linking helper files, man/info pages. You'll also need to add various
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configuration files, scripts, and directories to the rootfs so it will boot.
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Therefore you'll probably end up creating a separate rootfs directory which
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you will populate from the staging area, necessary extras, and then use
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crosstool-NG's populate script to add the necessary sysroot libraries.
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The 'populate' script |
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----------------------+
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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-tuple-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 pollute /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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The populate script accepts the following options:
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-s src_dir
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Use 'src_dir' as the un-populated root directory.
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-d dst_dir
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Put the populated root directory in 'dst_dir'.
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-l lib1 [...]
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Always add specified libraries.
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-L file
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Always add libraries listed in 'file'.
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-f
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Remove 'dst_dir' if it previously existed; continue even if any library
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specified with -l or -L is missing.
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-v
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Be verbose, and tell what's going on (you can see exactly where libs are
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coming from).
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-h
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Print the help.
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See 'your-target-tuple-populate -h' for more information on the options.
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Here is how populate works:
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1) performs some sanity checks:
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- src_dir and dst_dir are specified
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- src_dir exists
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- unless forced, dst_dir does not exist
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- src_dir != dst_dir
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2) copy src_dir to dst_dir
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3) add forced libraries to dst_dir
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- build the list from -l and -L options
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- get forced libraries from the sysroot (see below for heuristics)
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- abort on the first missing library, unless -f is specified
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4) add all missing libraries to dst_dir
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- scan dst_dir for every ELF files that are 'executable' or
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'shared object'
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- list the "NEEDED Shared library" fields
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- check if the library is already in dst_dir/lib or dst_dir/usr/lib
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- if not, get the library from the sysroot
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- if it's in sysroot/lib, copy it to dst_dir/lib
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- if it's in sysroot/usr/lib, copy it to dst_dir/usr/lib
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- in both cases, use the SONAME of the library to create the file
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in dst_dir
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- if it was not found in the sysroot, this is an error.
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