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这个文档 ABS - The Arch Build System 提供了一份良好的用于制作和修改 Arch Linux 软件包所需工具和文件的总览。如果你只想要定制或重新编译一个已经存在的软件包，这里应该已经提供了足够的信息。但是，如果你想要制作一个新的软件包，你还需要一些额外的指南。这个文档假定你已经事先阅读并掌握了 ABS 的描述。
pacman -Up <package file> 命令将其安装。
PKGBUILD 文件包含 所有 用于制作一个软件包所需的指令，这些指令以能够被 bash 识别的的格式存在(don't worry if that little tidbit of clue doesn't help you)。 ABS 条目中描述了这里使用的变量，但是最重要的也是最让人迷惑的变量在这里recapped。为了开始制作一个新的包，你应该首先创建一个空的目录，最好取名为
/var/abs/local/<PKGNAME>。这样的话，它可以很好的统一到统一的 ABS 树，但如果你没有同步该树的话，cvsup 不会接触(touch)它。进入你新建的目录，创建
- pkgname: 将这个变量设置为你的包的名字。按照惯例，你应该使用小写字母。最好包的名字与你所在的工作目录的名字相同，当然也与你将要下载的包含源程序的 tar.gz 文件名相同，但这并不是必须的。
- pkgver: 设置包的版本。它可以包含字母、数字和点，但不能有连字符。它由你打包的程序使用的版本系统决定（主版本.次版本.漏洞修复版本、major.日期等）。另外，在大多数情况下，你可以遵循源代码包的文件名的一部分的版本，以便后续步骤变得更为简单和灵活。还要注意：如果包的作者在其版本编号方案中使用了短横，请用下划线替代它。('0.99-10' => '0.99_10')
- pkgrel: This should be incremented each time you release a package, starting with 1. Its purpose is to differentiate consecutive builds of the same version of a package. Occasionally the first release of a package contains a problem or misfeature. When you make the second release, you increment the
pkgrelvariable so that pacman knows it needs to be reinstalled. When a new version of the package is released, you reset the
pkgrelvariable to 1.
- pkgdesc: This should contain a short, usually less than 76 characters, description of the package. Usually it is not needed repeating the program name.
OpenGL accelerated X serveris better than
xgl is a OpenGL....
- arch: This should contain an array of architectures, usually 'i686', that describes where the PKGBUILD file can be used. You can access this value with the variable
$archduring the build.
- url: This should contain the address of the official site of the program where who is interested can find more informations.
- license: The type of license, if you do not know it please write down 'unknow.'
- depends: This should contain an array of package names that need to be installed before this program can be run, separated by spaces. The names can optionally be enclosed in single quotes (apostrophes) to prevent possible shell quoting problems, and the array should be enclosed in round brackets. Sometimes a program requires a minimum version of a dependency; In that case, you might want to use the mathematical "larger or equal than" operator, and enclose the whole construct in quotes. Here's an example to add a dependency on the glibc package, and the slang library of at least version 1.8.0:
- makedepends: This should contain an array of package names that are needed only during the build, but that are unneeded for *using* the package after install. Example:
unarjused in a build to unpack some patches.
- provides: This should contain an array of package names that become unneeded with described one since it gives at least the same features.
- conflicts: This should be an array of package names that if installed with the described one will give problems.
- replaces: This should be an array of obsolete package names that are replaced by the described one.
- source: This must be an array of files which are needed to build the package, containing at least the location of the program source, which is in most cases a full HTTP or FTP URL enclosed in double quotes. The prototype
PKGBUILDshows how you can use the previously set variables for package name and version effectively here. If you find you need to supply files which are not downloadable on the fly, for example self-made patches, you simply put those into the same directory where your
PKGBUILDis in, and add the filename to this source array. Any paths you add here are resolved relative to the directory where the
PKGBUILDlies. Before the actual build process is started, all of the files referenced here will be downloaded or checked for existence, and
makepkgwill not proceed if any are missing.
- md5sums: An array of md5 checksums for the source files, space seperated and enclosed in quotes. Once all files in the source array are available, an md5 hash of each file will be automatically generated and compared with the values of this array, in the same order they appear in the source array. Whilst the order of the source files itself does not matter, it's important that it's coherent with the order of the md5sums, as
makepkgwon't guess which md5sum belongs to what source file, and will happily start spewing errors if they don't match to prevent download errors or manipulations. You can generate the md5sums array quickly and easily using the command
makepkg -g(after the source array has been properly set up) in the directory that contains the
makepkg -g >>PKGBUILDwill generate the sums and append them to the end of the
PKGBUILD, from whence you can move the line(s) into the proper position of the file.
So far you've only been setting up meta-information about the package; Where to get the sources, what the name of the package shall be, etc. The next step is supplying instructions on how to actually compile and install the program you're intending to pack up.
Using the source
Now you should download the source tarball, extract it, and note all commands needed to compile and install it. The contents of the
build() function in your
PKGBUILD will do nothing but run exactly these steps again, with a little glue to pack everything up once compilation is done.
Now you probably need to edit the contents of the build() function in the
PKGBUILD. This function uses common shell commands in the bash syntax. The basic purpose of this function is to automatically compile the programs and create a
pkg directory to install the program to, allowing
makepkg to pack it all up easily without having to pick all interesting files from your "live" filesystem.
The build() function
Usually the first step in the build function is to change into one of the directories created by uncompressing the source files. You can use the
$startdir variable to do this (it refers to the directory that contains the
PKGBUILD). You may also use the $pkgname and $pkgver variables that you set earlier. For example, depending on the name of the directory that was uncompressed by makepkg, the first command in your build function might be
cd $startdir/src/$pkgname-$pkgver, which happens to be a very common case unless the program's author is a very, very evil person.
Compiling the programs is the more difficult part. I will assume you managed to compile the program successfully "by hand" here, as all imaginable steps to do this cannot possibly be covered here. That's what the program's author is supposed to write README and INSTALL files for after all.
Now that you are in that directory, you need to issue whatever commands it takes to compile the files. In simple cases, you may simply use
./configure; make, although there are dozens of variations including
ant build or issuing the actual
gcc commands to compile the packages.
Good thing is, if you already managed to compile the package manually, you basically only need to list the commands you used here, and things should work out just fine. Since many packages like to install their files relative to the
/usr/local directory, but Arch Linux prefers using just
/usr, you probably want to supply a parameter to the configure script or the make command to take care of this. The prototype
PKGBUILD serves as an example for that. It might work differently, though; Again, your mileage may vary.
The next step in the
build() function is to put the compiled files in a place where
makepkg can scoop them up to create a package. This directory is the
pkg directory. It is supposed to imitate the root of your filesystem to the program's installation procedure. Any files that should be installed in a directory in the root of your filesystem should go in the
pkg directory under the same directory structure (ie. if you want to install the file
/usr/bin, it should be placed in
$startdir/pkg/usr/bin). Fortunately, only a few programs require the user to copy dozens of files manually, but they supply some kind of installation procedure instead which is supposed to do that automatically, often invoked by running "make install". It's critical, however, that you find out how to tell this installation procedure that it's supposed to stuff all it's nifty files not into your /, but into
$startdir/pkg/ instead! Otherwise you'll end up with an empty package file, and the binaries of the program you installed "correctly" added to your system already. Most of the time you'll have to supply the prefix parameter to the "make install" call as shown in the prototype, but it's very well possible that the program you're packaging expects an altogether different approach, but here are some hints:
- Sometimes the
configurescript accepts a prefix property that tells where the files should be installed. You might use
./configure --prefix=$startdir/pkg/usrin such configuration, for example.
- Sometimes there is a
PREFIXoption to append to a
make installcommand. This is sometimes set as a variable, and sometimes set in the command. In worse cases you have to edit the Makefile(s) (or ant build/properties files if the project uses ant) with sed or a patch you'd have to create yourself.
- There might be other sorts of install scripts that allow you to specify where the program should be installed.
- In some cases, the program expects to be run from a single directory. Often it is wise to simply copy these to
As you might have guessed already, that's the part where actual knowledge and experience becomes a necessity. It helps a lot if you browse over the
PKGBUILD files in the ABS tree, as those are tested and contain a few tricks that might prove valuable.
More often that not, the installation routine of the program will take care to create any subdirectories below the
pkg/ directory. If it does not, however, you'll get a lot of errors during the install stage as files are copied to nonexistent subdirectories. In that case you'll have to create the needed subdirectories by adding the appropriate
mkdir commands in the
build() function before running the installation procedure. The actual directory structure is package dependent, of course; some programs need to place files in
/usr while others might need to use
/opt. Most will need to create several directories. You can do all of this with the
mkdir -p $startdir/pkg/OTHER/DIRS/AS/NEEDED command, where OTHER/DIRS/AS/NEEDED represent directories at the root of the filesystem.
Testing the PKGBUILD
As you are writing the
build() function, you will want to test your changes frequently to ensure there are no bugs. You can do this using the
makepkg command in the directory containing the
PKGBUILD. With a properly formatted
PKGBUILD, this will create a package, but with a broken or unfinished one it will throw an error. Hopefully it will be a descriptive error!
makepkg finished successfully, it will place a shiny new file called $pkgname-$pkgver.pkg.tar.gz in your working directory. This is a pacman package and can be installed with the
pacman -U and
pacman -A options, or added to a local or web based repository. Note that just because a package file was built it doesn't mean it works! It might conceivably contain only the directory structure and no files whatsoever if, for example, you specified a prefix improperly. You can use pacman's query functions to display a list of files contained in the package and the dependencies it requires, and compare those with what you consider as correct. "pacman -Qlp <package file>" and "pacman -Qip <package file>" do the trick.
If the package looks sane, that's all you need to do. However, if you plan on releasing the package or PKGBUILD, it is imperative that you check and double check and re-double-check the contents of the depends array. This should contain a list of all packages that need to be installed in order for your package to work. You only need to list first level depends in the depends array. That is, you do not need to list packages that your program depends on if other packages that your program depends on are already listed.
gtk2 depends on
glib2. Like most open source C programs, it also requires
glibc to be installed. However,
glibc does not need to be listed as a dependency for
gtk2 because it is a dependency for
glib2 is already listed in
There are some tools you can use to check dependencies, including Jason Chu's famous
namcap program (
pacman -Sy namcap), and the more arcane
ldd program. Check the man pages for these programs and the links at the end of this document for more information. You should also scour the program's documentation and website (some nice developers have a page called "dependencies" that helps a lot).
Testing the package
Also make sure that the package binaries actually run flawlessly! It's really annoying to release a package that contains all necessary files, but dumps core because of some obscure configuration option that doesn't quite work well with the rest of the system. If you're only going to compile packages for your own system, though, you don't need to worry too much about this quality assurance step, as you're the only person suffering from mistakes after all.
To sum it all up
- Download the source tarball of the program you want to package up
- Try compiling the package and installing it into an arbitrary directory
- Copy over the prototype
/var/abs/PKGBUILD.protoand rename it to
PKGBUILDin a temporary working directory
- Edit the PKGBUILD according to the needs of your package
makepkgand see whether the resulting package is built correctly
- If not, repeat the last two steps
- ABS - The Arch Build System
- makepkg man page
- about dependencies
- makepkg tutorial
- PKGBUILD Help
- Arch CVS & SVN PKGBUILD guidelines
- Before you can automate the package building process, you should have done it manually at least once unless you know exactly what you're doing in advance, in which case you would not be reading this in the first place. Unfortunately, although a good bunch of program authors stick to the 3-step build cycle of "./configure; make; make install", this is not always the case, and things can get real ugly if you have to apply patches to make everything work at all. Rule of thumb: If you can't get the program to compile from the source tarball, and make it install itself to a defined, temporary subdirectory, you don't even need to try packaging it. There isn't any magic pixie dust in
makepkgthat makes source problems go away.
- In a few cases, the packages are not even available as source and you have to use something like
sh installer.runto get it to work. You will have to do quite a bit of research (read READMEs, INSTALL instructions, man pages, perhaps ebuilds from gentoo or other package installers, possibly even the MAKEFILEs or source code) to get it working. In some really bad cases, you have to edit the source files to get it to work at all. However,
makepkgneeds to be completely autonomous, with no user input. Therefore if you need to edit the Makefiles, you may have to bundle a custom patch with the
PKGBUILDand install it from inside the
build()function, or you might have to issue some
sedcommands from inside the
- Note that just because a package file was built it doesn't mean it works! It might conceivably contain only the directory structure and no files whatsoever if, for example, you specified a prefix improperly. You can use pacman's query functions to display a list of files contained in the package and the dependencies it requires, and compare those with what you consider as correct. "pacman -Qlp <package file>" and "pacman -Qip <package file>" do the trick.