With Python 3 being the future of Python while Python 2 is still in active use, it is good to have your project available for both major releases of Python. This guide is meant to help you figure out how best to support both Python 2 & 3 simultaneously.
If you are looking to port an extension module instead of pure Python code, please see Porting Extension Modules to Python 3.
For help with porting, you can email the python-porting mailing list with questions.
To make your project be single-source Python 2/3 compatible, the basic steps are:
pip install coverage)
pip install future)
pip install pylint)
pip install caniusepython3)
pip install tox)
A key point about supporting Python 2 & 3 simultaneously is that you can start today! Even if your dependencies are not supporting Python 3 yet that does not mean you can’t modernize your code now to support Python 3. Most changes required to support Python 3 lead to cleaner code using newer practices even in Python 2 code.
Another key point is that modernizing your Python 2 code to also support Python 3 is largely automated for you. While you might have to make some API decisions thanks to Python 3 clarifying text data versus binary data, the lower-level work is now mostly done for you and thus can at least benefit from the automated changes immediately.
Keep those key points in mind while you read on about the details of porting your code to support Python 2 & 3 simultaneously.
While you can make Python 2.5 work with Python 3, it is much easier if you
only have to work with Python 2.7. If dropping Python 2.5 is not an
option then the six project can help you support Python 2.5 & 3 simultaneously
pip install six). Do realize, though, that nearly all the projects listed
in this HOWTO will not be available to you.
If you are able to skip Python 2.5 and older, then the required changes to your code should continue to look and feel like idiomatic Python code. At worst you will have to use a function instead of a method in some instances or have to import a function instead of using a built-in one, but otherwise the overall transformation should not feel foreign to you.
But you should aim for only supporting Python 2.7. Python 2.6 is no longer freely supported and thus is not receiving bugfixes. This means you will have to work around any issues you come across with Python 2.6. There are also some tools mentioned in this HOWTO which do not support Python 2.6 (e.g., Pylint), and this will become more commonplace as time goes on. It will simply be easier for you if you only support the versions of Python that you have to support.
setup.py file you should have the proper trove classifier
specifying what versions of Python you support. As your project does not support
Python 3 yet you should at least have
Programming Language :: Python :: 2 :: Only specified. Ideally you should
also specify each major/minor version of Python that you do support, e.g.
Programming Language :: Python :: 2.7.
Once you have your code supporting the oldest version of Python 2 you want it to, you will want to make sure your test suite has good coverage. A good rule of thumb is that if you want to be confident enough in your test suite that any failures that appear after having tools rewrite your code are actual bugs in the tools and not in your code. If you want a number to aim for, try to get over 80% coverage (and don’t feel bad if you find it hard to get better than 90% coverage). If you don’t already have a tool to measure test coverage then coverage.py is recommended.
Once you have your code well-tested you are ready to begin porting your code to Python 3! But to fully understand how your code is going to change and what you want to look out for while you code, you will want to learn what changes Python 3 makes in terms of Python 2. Typically the two best ways of doing that is reading the “What’s New” doc for each release of Python 3 and the Porting to Python 3 book (which is free online). There is also a handy cheat sheet from the Python-Future project.
Once you feel like you know what is different in Python 3 compared to Python 2,
it’s time to update your code! You have a choice between two tools in porting
your code automatically: Futurize and Modernize. Which tool you choose will
depend on how much like Python 3 you want your code to be. Futurize does its
best to make Python 3 idioms and practices exist in Python 2, e.g. backporting
bytes type from Python 3 so that you have semantic parity between the
major versions of Python. Modernize,
on the other hand, is more conservative and targets a Python 2/3 subset of
Python, directly relying on six to help provide compatibility. As Python 3 is
the future, it might be best to consider Futurize to begin adjusting to any new
practices that Python 3 introduces which you are not accustomed to yet.
Regardless of which tool you choose, they will update your code to run under Python 3 while staying compatible with the version of Python 2 you started with. Depending on how conservative you want to be, you may want to run the tool over your test suite first and visually inspect the diff to make sure the transformation is accurate. After you have transformed your test suite and verified that all the tests still pass as expected, then you can transform your application code knowing that any tests which fail is a translation failure.
Unfortunately the tools can’t automate everything to make your code work under
Python 3 and so there are a handful of things you will need to update manually
to get full Python 3 support (which of these steps are necessary vary between
the tools). Read the documentation for the tool you choose to use to see what it
fixes by default and what it can do optionally to know what will (not) be fixed
for you and what you may have to fix on your own (e.g. using
open() function is off by default in Modernize). Luckily,
though, there are only a couple of things to watch out for which can be
considered large issues that may be hard to debug if not watched for.
In Python 3,
5 / 2 == 2.5 and not
2; all division between
result in a
float. This change has actually been planned since Python 2.2
which was released in 2002. Since then users have been encouraged to add
from __future__ import division to any and all files which use the
// operators or to be running the interpreter with the
-Q flag. If you
have not been doing this then you will need to go through your code and do two
from __future__ import divisionto your files
//to use floor division or continue using
/and expect a float
The reason that
/ isn’t simply translated to
// automatically is that if
an object defines a
__truediv__ method but not
__floordiv__ then your
code would begin to fail (e.g. a user-defined class that uses
signify some operation but not
// for the same thing or at all).
In Python 2 you could use the
str type for both text and binary data.
Unfortunately this confluence of two different concepts could lead to brittle
code which sometimes worked for either kind of data, sometimes not. It also
could lead to confusing APIs if people didn’t explicitly state that something
str accepted either text or binary data instead of one
specific type. This complicated the situation especially for anyone supporting
multiple languages as APIs wouldn’t bother explicitly supporting
when they claimed text data support.
To make the distinction between text and binary data clearer and more pronounced, Python 3 did what most languages created in the age of the internet have done and made text and binary data distinct types that cannot blindly be mixed together (Python predates widespread access to the internet). For any code that deals only with text or only binary data, this separation doesn’t pose an issue. But for code that has to deal with both, it does mean you might have to now care about when you are using text compared to binary data, which is why this cannot be entirely automated.
To start, you will need to decide which APIs take text and which take binary
(it is highly recommended you don’t design APIs that can take both due to
the difficulty of keeping the code working; as stated earlier it is difficult to
do well). In Python 2 this means making sure the APIs that take text can work
unicode and those that work with binary data work with the
bytes type from Python 3 (which is a subset of
str in Python 2 and acts
as an alias for
bytes type in Python 2). Usually the biggest issue is
realizing which methods exist on which types in Python 2 & 3 simultaneously
(for text that’s
unicode in Python 2 and
str in Python 3, for binary
bytes in Python 2 and
bytes in Python 3). The following
table lists the unique methods of each data type across Python 2 & 3
decode() method is usable on the equivalent binary data type in
either Python 2 or 3, but it can’t be used by the textual data type consistently
between Python 2 and 3 because
str in Python 3 doesn’t have the method). Do
note that as of Python 3.5 the
__mod__ method was added to the bytes type.
|Text data||Binary data|
Making the distinction easier to handle can be accomplished by encoding and decoding between binary data and text at the edge of your code. This means that when you receive text in binary data, you should immediately decode it. And if your code needs to send text as binary data then encode it as late as possible. This allows your code to work with only text internally and thus eliminates having to keep track of what type of data you are working with.
The next issue is making sure you know whether the string literals in your code
represent text or binary data. You should add a
b prefix to any
literal that presents binary data. For text you should add a
u prefix to
the text literal. (there is a
__future__ import to force all unspecified
literals to be Unicode, but usage has shown it isn’t as effective as adding a
u prefix to all literals explicitly)
As part of this dichotomy you also need to be careful about opening files.
Unless you have been working on Windows, there is a chance you have not always
bothered to add the
b mode when opening a binary file (e.g.,
binary reading). Under Python 3, binary files and text files are clearly
distinct and mutually incompatible; see the
io module for details.
Therefore, you must make a decision of whether a file will be used for
binary access (allowing binary data to be read and/or written) or textual access
(allowing text data to be read and/or written). You should also use
for opening files instead of the built-in
open() function as the
module is consistent from Python 2 to 3 while the built-in
is not (in Python 3 it’s actually
io.open()). Do not bother with the
outdated practice of using
codecs.open() as that’s only necessary for
keeping compatibility with Python 2.5.
The constructors of both
bytes have different semantics for the
same arguments between Python 2 & 3. Passing an integer to
bytes in Python 2
will give you the string representation of the integer:
bytes(3) == '3'.
But in Python 3, an integer argument to
bytes will give you a bytes object
as long as the integer specified, filled with null bytes:
bytes(3) == b'\x00\x00\x00'. A similar worry is necessary when passing a
bytes object to
str. In Python 2 you just get the bytes object back:
str(b'3') == b'3'. But in Python 3 you get the string representation of the
str(b'3') == "b'3'".
Finally, the indexing of binary data requires careful handling (slicing does
not require any special handling). In Python 2,
b'123' == b'2' while in Python 3
b'123' == 50. Because binary data
is simply a collection of binary numbers, Python 3 returns the integer value for
the byte you index on. But in Python 2 because
bytes == str, indexing
returns a one-item slice of bytes. The six project has a function
six.indexbytes() which will return an integer like in Python 3:
unicodeand code for binary data works with
bytesin Python 2 (see the table above for what methods you cannot use for each type)
bprefix, textual literals with a
io.open()and make sure to specify the
bmode when appropriate
Inevitably you will have code that has to choose what to do based on what version of Python is running. The best way to do this is with feature detection of whether the version of Python you’re running under supports what you need. If for some reason that doesn’t work then you should make the version check be against Python 2 and not Python 3. To help explain this, let’s look at an example.
Let’s pretend that you need access to a feature of importlib that
is available in Python’s standard library since Python 3.3 and available for
Python 2 through importlib2 on PyPI. You might be tempted to write code to
access e.g. the
importlib.abc module by doing the following:
import sys if sys.version_info == 3: from importlib import abc else: from importlib2 import abc
The problem with this code is what happens when Python 4 comes out? It would be better to treat Python 2 as the exceptional case instead of Python 3 and assume that future Python versions will be more compatible with Python 3 than Python 2:
import sys if sys.version_info > 2: from importlib import abc else: from importlib2 import abc
The best solution, though, is to do no version detection at all and instead rely on feature detection. That avoids any potential issues of getting the version detection wrong and helps keep you future-compatible:
try: from importlib import abc except ImportError: from importlib2 import abc
Once you have fully translated your code to be compatible with Python 3, you will want to make sure your code doesn’t regress and stop working under Python 3. This is especially true if you have a dependency which is blocking you from actually running under Python 3 at the moment.
To help with staying compatible, any new modules you create should have at least the following block of code at the top of it:
from __future__ import absolute_import from __future__ import division from __future__ import print_function
You can also run Python 2 with the
-3 flag to be warned about various
compatibility issues your code triggers during execution. If you turn warnings
into errors with
-Werror then you can make sure that you don’t accidentally
miss a warning.
You can also use the Pylint project and its
--py3k flag to lint your code
to receive warnings when your code begins to deviate from Python 3
compatibility. This also prevents you from having to run Modernize or Futurize
over your code regularly to catch compatibility regressions. This does require
you only support Python 2.7 and Python 3.4 or newer as that is Pylint’s
minimum Python version support.
After you have made your code compatible with Python 3 you should begin to care about whether your dependencies have also been ported. The caniusepython3 project was created to help you determine which projects – directly or indirectly – are blocking you from supporting Python 3. There is both a command-line tool as well as a web interface at https://caniusepython3.com.
The project also provides code which you can integrate into your test suite so that you will have a failing test when you no longer have dependencies blocking you from using Python 3. This allows you to avoid having to manually check your dependencies and to be notified quickly when you can start running on Python 3.
setup.pyfile to denote Python 3 compatibility
Once your code works under Python 3, you should update the classifiers in
setup.py to contain
Programming Language :: Python :: 3 and to not
specify sole Python 2 support. This will tell anyone using your code that you
support Python 2 and 3. Ideally you will also want to add classifiers for
each major/minor version of Python you now support.
Once you are able to fully run under Python 3 you will want to make sure your code always works under both Python 2 & 3. Probably the best tool for running your tests under multiple Python interpreters is tox. You can then integrate tox with your continuous integration system so that you never accidentally break Python 2 or 3 support.
You may also want to use the
-bb flag with the Python 3 interpreter to
trigger an exception when you are comparing bytes to strings or bytes to an int
(the latter is available starting in Python 3.5). By default type-differing
comparisons simply return
False, but if you made a mistake in your
separation of text/binary data handling or indexing on bytes you wouldn’t easily
find the mistake. This flag will raise an exception when these kinds of
comparisons occur, making the mistake much easier to track down.
And that’s mostly it! At this point your code base is compatible with both Python 2 and 3 simultaneously. Your testing will also be set up so that you don’t accidentally break Python 2 or 3 compatibility regardless of which version you typically run your tests under while developing.
Another way to help port your code is to use a static type checker like mypy or pytype on your code. These tools can be used to analyze your code as if it’s being run under Python 2, then you can run the tool a second time as if your code is running under Python 3. By running a static type checker twice like this you can discover if you’re e.g. misusing binary data type in one version of Python compared to another. If you add optional type hints to your code you can also explicitly state whether your APIs use textual or binary data, helping to make sure everything functions as expected in both versions of Python.