PEP 3149 – ABI version tagged .so files
- Author:
- Barry Warsaw <barry at python.org>
- Status:
- Final
- Type:
- Standards Track
- Created:
- 09-Jul-2010
- Python-Version:
- 3.2
- Post-History:
- 14-Jul-2010, 22-Jul-2010
- Resolution:
- Python-Dev message
Abstract
PEP 3147 described an extension to Python’s import machinery that improved the sharing of Python source code, by allowing more than one byte compilation file (.pyc) to be co-located with each source file.
This PEP defines an adjunct feature which allows the co-location of extension module files (.so) in a similar manner. This optional, build-time feature will enable downstream distributions of Python to more easily provide more than one Python major version at a time.
Background
PEP 3147 defined the file system layout for a pure-Python package,
where multiple versions of Python are available on the system. For
example, where the alpha
package containing source modules one.py
and two.py
exist on a system with Python 3.2 and 3.3, the post-byte
compilation file system layout would be:
alpha/
__pycache__/
__init__.cpython-32.pyc
__init__.cpython-33.pyc
one.cpython-32.pyc
one.cpython-33.pyc
two.cpython-32.pyc
two.cpython-33.pyc
__init__.py
one.py
two.py
For packages with extension modules, a similar differentiation is needed for the module’s .so files. Extension modules compiled for different Python major versions are incompatible with each other due to changes in the ABI. Different configuration/compilation options for the same Python version can result in different ABIs (e.g. –with-wide-unicode).
While PEP 384 defines a stable ABI, it will minimize, but not eliminate extension module incompatibilities between Python builds or major versions. Thus a mechanism for discriminating extension module file names is proposed.
Rationale
Linux distributions such as Ubuntu [3] and Debian [4] provide more than one Python version at the same time to their users. For example, Ubuntu 9.10 Karmic Koala users can install Python 2.5, 2.6, and 3.1, with Python 2.6 being the default.
In order to share as much as possible between the available Python
versions, these distributions install third party package modules
(.pyc
and .so
files) into /usr/share/pyshared
and symlink to
them from /usr/lib/pythonX.Y/dist-packages
. The symlinks exist
because in a pre-PEP 3147 world (i.e < Python 3.2), the .pyc
files
resulting from byte compilation by the various installed Pythons will
name collide with each other. For Python versions >= 3.2, all
pure-Python packages can be shared, because the .pyc
files will no
longer cause file system naming conflicts. Eliminating these symlinks
makes for a simpler, more robust Python distribution.
A similar situation arises with shared library extensions. Because
extension modules are typically named foo.so
for a foo
extension
module, these would also name collide if foo
was provided for more
than one Python version.
In addition, because different configuration/compilation options for
the same Python version can cause different ABIs to be presented to
extension modules. On POSIX systems for example, the configure
options --with-pydebug
, --with-pymalloc
, and
--with-wide-unicode
all change the ABI. This PEP proposes to
encode build-time options in the file name of the .so
extension
module files.
PyPy [5] can also benefit from this PEP, allowing it to avoid name
collisions in extension modules built for its API, but with a
different .so
tag.
Proposal
The configure/compilation options chosen at Python interpreter build-time will be encoded in the shared library file name for extension modules. This “tag” will appear between the module base name and the operation file system extension for shared libraries.
The following information MUST be included in the shared library file name:
- The Python implementation (e.g. cpython, pypy, jython, etc.)
- The interpreter’s major and minor version numbers
These two fields are separated by a hyphen and no dots are to appear
between the major and minor version numbers. E.g. cpython-32
.
Python implementations MAY include additional flags in the file name tag as appropriate. For example, on POSIX systems these flags will also contribute to the file name:
--with-pydebug
(flag:d
)--with-pymalloc
(flag:m
)--with-wide-unicode
(flag:u
)
By default in Python 3.2, configure
enables --with-pymalloc
so
shared library file names would appear as foo.cpython-32m.so
.
When the other two flags are also enabled, the file names would be
foo.cpython-32dmu.so
.
The shared library file name tag is used unconditionally; it cannot be
changed. The tag and extension module suffix are available through
the sysconfig
modules via the following variables:
>>> sysconfig.get_config_var('EXT_SUFFIX')
'.cpython-32mu.so'
>>> sysconfig.get_config_var('SOABI')
'cpython-32mu'
Note that $SOABI
contains just the tag, while $EXT_SUFFIX
includes the
platform extension for shared library files, and is the exact suffix
added to the extension module name.
For an arbitrary package foo
, you might see these files when the
distribution package was installed:
/usr/lib/python/foo.cpython-32m.so
/usr/lib/python/foo.cpython-33m.so
(These paths are for example purposes only. Distributions are free to use whatever filesystem layout they choose, and nothing in this PEP changes the locations where from-source builds of Python are installed.)
Python’s dynamic module loader will recognize and import shared
library extension modules with a tag that matches its build-time
options. For backward compatibility, Python will also continue to
import untagged extension modules, e.g. foo.so
.
This shared library tag would be used globally for all distutils-based
extension modules, regardless of where on the file system they are
built. Extension modules built by means other than distutils would
either have to calculate the tag manually, or fallback to the
non-tagged .so
file name.
Proven approach
The approach described here is already proven, in a sense, on Debian
and Ubuntu system where different extensions are used for debug builds
of Python and extension modules. Debug builds on Windows also already
use a different file extension for dynamic libraries, and in fact
encoded (in a different way than proposed in this PEP) the Python
major and minor version in the .dll
file name.
Windows
This PEP only addresses build issues on POSIX systems that use the
configure
script. While Windows or other platform support is not
explicitly disallowed under this PEP, platform expertise is needed in
order to evaluate, describe, and implement support on such platforms.
It is not currently clear that the facilities in this PEP are even
useful for Windows.
PEP 384
PEP 384 defines a stable ABI for extension modules. In theory, universal adoption of PEP 384 would eliminate the need for this PEP because all extension modules could be compatible with any Python version. In practice of course, it will be impossible to achieve universal adoption, and as described above, different build-time flags still affect the ABI. Thus even with a stable ABI, this PEP may still be necessary. While a complete specification is reserved for PEP 384, here is a discussion of the relevant issues.
PEP 384 describes a change to PyModule_Create()
where 3
is
passed as the API version if the extension was compiled with
Py_LIMITED_API
. This should be formalized into an official macro
called PYTHON_ABI_VERSION
to mirror PYTHON_API_VERSION
. If
and when the ABI changes in an incompatible way, this version number
would be bumped. To facilitate sharing, Python would be extended to
search for extension modules with the PYTHON_ABI_VERSION
number in
its name. The prefix abi
is reserved for Python’s use.
Thus, an initial implementation of PEP 384, when Python is configured
with the default set of flags, would search for the following file
names when extension module foo
is imported (in this order):
foo.cpython-XYm.so
foo.abi3.so
foo.so
The distutils [6] build_ext
command would also have to be
extended to compile to shared library files with the abi3
tag,
when the module author indicates that their extension supports that
version of the ABI. This could be done in a backward compatible way
by adding a keyword argument to the Extension
class, such as:
Extension('foo', ['foo.c'], abi=3)
Martin v. Löwis describes his thoughts [7] about the applicability of this PEP to PEP 384. In summary:
--with-pydebug
would not be supported by the stable ABI because this changes the layout ofPyObject
, which is an exposed structure.--with-pymalloc
has no bearing on the issue.--with-wide-unicode
is trickier, though Martin’s inclination is to force the stable ABI to use aPy_UNICODE
that matches the platform’swchar_t
.
Alternatives
In the initial python-dev thread [8] where this idea was first introduced, several alternatives were suggested. For completeness they are listed here, along with the reasons for not adopting them.
Independent directories or symlinks
Debian and Ubuntu could simply add a version-specific directory to
sys.path
that would contain just the extension modules for that
version of Python. Or the symlink trick eliminated in PEP 3147 could
be retained for just shared libraries. This approach is rejected
because it propagates the essential complexity that PEP 3147 tries to
avoid, and adds potentially several additional directories to search
for all modules, even when the number of extension modules is much
fewer than the total number of Python packages. For example, builds
were made available both with and without wide unicode, with and
without pydebug, and with and without pymalloc, the total number of
directories search increases substantially.
Reference implementation
Work on this code is tracked in a Bazaar branch on Launchpad [9] until it’s ready for merge into Python 3.2. The work-in-progress diff can also be viewed [10] and is updated automatically as new changes are uploaded.
References
Copyright
This document has been placed in the public domain.
Source: https://github.com/python/peps/blob/main/peps/pep-3149.rst
Last modified: 2023-09-09 17:39:29 GMT