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224 lines
9.1 KiB
Plaintext
224 lines
9.1 KiB
Plaintext
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-------------------
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Written by Ted T'so
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-------------------
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> https://www.gnu.org/software/libtool/manual/html_node/Updating-version-info.html
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>
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> I understood that, if there is no interface change but some implementation
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> changes, I need to bump revision. If new interface is added, for example, I
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> need to bump current while revision=0 and age++.
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So part of the problem here is that libtool is doing something really
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strange because they are trying to use some abstract concept that is
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OS-independent. I don't use libtool because I find it horribly
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complex and doesn't add enough value to be worth the complexity.
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So I'll tell you how things work with respect to Linux's ELF version
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numbering system. Translating this to libtool's wierd "current,
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revision, age" terminology is left as an exercise to the reader. I've
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looked at the libtool documentation, and it confuses me horribly.
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Reading it, I suspect it's wrong, but I don't have the time to
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experiment to confirm that the documentation is wrong and how it
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diverges from the libtool implementation.
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So let me explain things using the ELF shared library terminology,
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which is "major version, minor version, patchlevel". This shows up in
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the library name:
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libudev.so.1.6.11
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So in this example, the major version number is 1, the minor version
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is 6, and the patchlevel is 11. The patchlevel is entirely optional,
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and many packages don't use it at all. The minor number is also
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mostly useless on Linux, but it's still there for historical reasons.
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The patchlevel and minor version numbers were useful back for SunOS
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(and Linux a.out shared library), back when there weren't rpm and dpkg
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as package managers.
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So many modern Linux shared libraries will only use the major and
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minor version numbers, e.g:
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libext2fs.so.2.4
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The only thing you really need to worry about is the major version
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number, really. The minor version is *supposed* to change when new
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interfaces has changed (but I and most other people don't do that any
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more). But the big deal is that the major number *must* get bumped if
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an existing interface has *changed*.
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So let's talk about the major version number, and then we'll talk
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about why the minor version number isn't really a big deal for Linux.
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So if you change any of the library's function signatures --- and this
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includes changing a type from a 32-bit integer to a 64-bit integer,
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that's an ABI breakage, and so you must bump the major version number
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so that a program that was linked against libfoo.so.4 doesn't try to
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use libfoo.so.5. That's really the key --- will a program linked
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against the previous version library break if it links against the
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newer version. If it does, then you need to bump the version number.
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So for structures, if you change any of the existing fields, or if the
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application program allocates the structure --- either by declaring it
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on the stack, or via malloc() --- and you expand the structure,
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obviously that will cause problem, and so that's an ABI break.
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If however, you arrange to have structures allocated by the library,
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and struct members are always added at the end, then an older program
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won't have any problems. You can guarantee this by simply only using
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a pointer to the struct in your public header files, and defining the
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struct in a private header file that is not available to userspace
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programs.
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Similarly, adding new functions never breaks the ABI. That's because
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older program won't try to use the newer interfaces. So if I need to
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change an interface to a function, what I'll generally do is to define
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a new function, and then implement the older function in terms of the
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newer one. For example:
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extern errcode_t ext2fs_open(const char *name, int flags, int superblock,
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unsigned int block_size, io_manager manager,
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ext2_filsys *ret_fs);
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extern errcode_t ext2fs_open2(const char *name, const char *io_options,
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int flags, int superblock,
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unsigned int block_size, io_manager manager,
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ext2_filsys *hret_fs);
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As far as the minor version numbers are concerned, the dynamic linker
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doesn't use it. In SunOS 4, if you have a DT_NEEDED for libfoo.so.4,
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and the dynamic linker finds in its search path:
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libfoo.so.4.8
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libfoo.so.4.9
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It will preferentially use libfoo.so.4.9.
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That's not how it works in Linux, though. In Linux there will be a
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symlink that points libfoo.so.4 to libfoo.so.4.9, and the linker just
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looks for libfoo.so.4. One could imagine a package manager which
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adjusts the symlink to point at the library with the highest version,
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but given that libfoo.so.4.9 is supposed to contain a superset of
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libfoo.so.4.8, there's no point. So we just in practice handle all of
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this in the package manager, or via an ELF symbol map. Or, we just
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assume that since vast majority of software comes from the
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distribution, the distro package manager will just update libraries to
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the newer version as a matter of course, and nothing special needs to
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be done.
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So in practice I don't bump the minor version number for e2fsprogs
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each time I add new interfaces, because in practice it really doesn't
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matter for Linux. We have a much better system that gets used for
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Debian.
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For example in Debian there is a file that contains when each symbol
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was first introduced into a library, by its package version number.
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See:
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https://git.kernel.org/pub/scm/fs/ext2/e2fsprogs.git/tree/debian/libext2fs2.symbols
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This file contains a version number for each symbol in libext2fs2, and
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it tells us what version of libext2fs you need to guarantee that a
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particular symbol is present in the library. Then when *other*
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packages are built that depend on libext2fs2, the minimum version of
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libext2fs can be calculated based on which symbols they use.
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So for example the libf2fs-format4 package has a Debian dependency of:
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Depends: libblkid1 (>= 2.17.2), libc6 (>= 2.14), libf2fs5, libuuid1 (>= 2.16)
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The minimum version numbers needed for libblkid1 and libuuid1 are
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determined by figuring out all of the symbols used by the
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libf2fs-format4 package, and determining the minimum version number of
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libblkid1 that supports all of those blkid functions.
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This gets done automatically, so I didn't have to figure this out.
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All I have in the debian/control file is:
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Depends: ${misc:Depends}, ${shlibs:Depends}
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Sorry this got so long, but hopefully you'll find this useful. How
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you bend libtool to your will is something you'll have to figure out,
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because I don't use libtool in my packages.[1]
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Cheers,
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- Ted
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[1] If you are interested in how I do things in e2fsprogs, take a look
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at the Makefile.elf-lib, Makefile.solaris-lib, Makefile.darwin-lib,
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etc. here:
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https://git.kernel.org/pub/scm/fs/ext2/e2fsprogs.git/tree/lib
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This these Makefile fragments are then pulled into the generated
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makefile using autoconf's substitution rules, here:
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https://git.kernel.org/pub/scm/fs/ext2/e2fsprogs.git/tree/lib/ext2fs/Makefile.in
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(Search for "@MAKEFILE_ELF@" in the above Makefile.in).
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So when someone runs "configure --enable-elf-shlibs", they get the ELF
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shared libraries built. On BSD and MacOS systems they just have to
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run "configure --enable-bsd-shlibs", and so on.
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Personally, since most people don't bother to write truly portable
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programs, as their C code is full of Linux'isms, using libtool is just
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overkill, because they probably can't build on any other OS *anyway*
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so libtool's slow and complex abstraction layer is totally wasted.
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Might as well not use autoconf, automake, and libtool at all.
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On the other hand, if you really *do* worry about portability on other
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OS's (e2fsprogs builds on MacOS, NetBSD, Hurd, Solaris, etc.) then
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using autoconf makes sense --- but I *still* don't think the
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complexity of libtool is worth it.
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= Add-on =
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If you are going to be making one less major update, this is the
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perfect time to make sure that data structures are allocated by the
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library, and are (ideally) opaque to the calling application (so they
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only manipulate structure poitners). That is, the structure
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definition is not exposed in the public header file, and you use
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accessor functions to set and get fields in the structure.
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If you can't do that for all data structures, if you can do that with
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your primary data structure that's going to make your life much easier
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in the long term. For ext2fs, that's the file systme handle. It's
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created by ext2fs_open(), and it's passed to all other library
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functions as the first argument.
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The other thing you might want to consider doing is adding a magic
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number to the beginning of each structure. That way you can tell if
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the wrong structure gets passed to a library. It's also helpful for
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doing the equivalent of subclassing in C.
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This is how we do it in libext2fs --- we use com_err to define the
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magic numbers:
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error_table ext2
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ec EXT2_ET_BASE,
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"EXT2FS Library version @E2FSPROGS_VERSION@"
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ec EXT2_ET_MAGIC_EXT2FS_FILSYS,
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"Wrong magic number for ext2_filsys structure"
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ec EXT2_ET_MAGIC_BADBLOCKS_LIST,
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"Wrong magic number for badblocks_list structure"
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...
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And then every single structure starts like so:
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struct struct_ext2_filsys {
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errcode_t magic;
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...
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struct ext2_struct_inode_scan {
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errcode_t magic;
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...
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And then before we use any pointer we do this:
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if (file->magic != EXT2_ET_MAGIC_EXT2_FILE)
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return EXT2_ET_MAGIC_EXT2_FILE;
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