diff -r ec1948191461 Doc/howto/pyporting.rst --- a/Doc/howto/pyporting.rst Wed Nov 12 10:19:46 2014 -0500 +++ b/Doc/howto/pyporting.rst Fri Nov 21 15:01:22 2014 -0500 @@ -19,600 +19,318 @@ If you would like to read one core Python developer's take on why Python 3 came into existence, you can read Nick Coghlan's `Python 3 Q & A`_. - If you prefer to read a (free) book on porting a project to Python 3, - consider reading `Porting to Python 3`_ by Lennart Regebro which should cover - much of what is discussed in this HOWTO. - For help with porting, you can email the python-porting_ mailing list with questions. -The Short Version -================= +The Short Explanation +===================== -* Decide what's the oldest version of Python 2 you want to support (if at all) -* Make sure you have a thorough test suite and use continuous integration - testing to make sure you stay compatible with the versions of Python you care - about -* If you have dependencies, check their Python 3 status using caniusepython3 - (`command-line tool `__, - `web app `__) +To make your project be single-source Python 2/3 compatible, the basic steps +are: -With that done, your options are: +#. Update your code to drop support for Python 2.5 or older (supporting only + Python 2.7 is ideal) +#. Make sure you have good test coverage (coverage.py_ can help) +#. Learn the differences between Python 2 & 3 +#. Use Modernize_ or Futurize_ to update your code +#. Use Pylint_ to help make sure you don't regress on your Python 3 support +#. Use caniusepython3_ to find out which of your dependencies are blocking your + use of Python 3 +#. Once your dependencies are no longer blocking you, use constant integration + to make sure you stay compatible with Python 2 & 3 (tox_ can help test + against multiple versions of Python) -* If you are dropping Python 2 support, use :ref:`2to3 <2to3-reference>` to port - to Python 3 +If you are dropping support for Python 2 entirely, then after you learn the +differences between Python 2 & 3 you can run 2to3_ over your code and skip the +rest of the steps outlined above. -* If you are keeping Python 2 support, then start writing Python 2/3-compatible - code starting **TODAY** - + If you have dependencies that have not been ported, reach out to them to port - their project while working to make your code compatible with Python 3 so - you're ready when your dependencies are all ported - + If all your dependencies have been ported (or you have none), go ahead and - port to Python 3 +Details +======= -* If you are creating a new project that wants to have 2/3 compatibility, - code in Python 3 and then backport to Python 2 +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 supporting newer practices which will lead +to a better code base overall even in a Python 2 context. +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. -Before You Begin -================ +Keep those key points in mind while you read on about the details of porting +your code to support Python 2 & 3 simultaneously. -If your project is on the Cheeseshop_/PyPI_, make sure it has the proper -`trove classifiers`_ to signify what versions of Python it **currently** -supports. At minimum you should specify the major version(s), e.g. -``Programming Language :: Python :: 2`` if your project currently only supports -Python 2. It is preferrable that you be as specific as possible by listing every -major/minor version of Python that you support, e.g. if your project supports -Python 2.6 and 2.7, then you want the classifiers of:: - Programming Language :: Python :: 2 - Programming Language :: Python :: 2.6 - Programming Language :: Python :: 2.7 +Drop support for Python 2.5 and older (at least) +------------------------------------------------ -Once your project supports Python 3 you will want to go back and add the -appropriate classifiers for Python 3 as well. This is important as setting the -``Programming Language :: Python :: 3`` classifier will lead to your project -being listed under the `Python 3 Packages`_ section of PyPI. +While you can make Python 2.5 work with Python 3, it is **much** easier if you +only have to work with Python 2.6 or newer (and easier still 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. Do realize, though, +that nearly all the projects listed in this HOWTO will not be available to you. -Make sure you have a robust test suite. You need to -make sure everything continues to work, just like when you support a new -minor/feature release of Python. This means making sure your test suite is -thorough and is ported properly between Python 2 & 3 (consider using coverage_ -to measure that you have effective test coverage). You will also most likely -want to use something like tox_ to automate testing between all of your -supported versions of Python. You will also want to **port your tests first** so -that you can make sure that you detect breakage during the transition. Tests also -tend to be simpler than the code they are testing so it gives you an idea of how -easy it can be to port code. +If you are able to only support Python 2.6 or newer, 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. -Drop support for older Python versions if possible. Python 2.5 -introduced a lot of useful syntax and libraries which have become idiomatic -in Python 3. Python 2.6 introduced future statements which makes -compatibility much easier if you are going from Python 2 to 3. -Python 2.7 continues the trend in the stdlib. Choose the newest version -of Python which you believe can be your minimum support version -and work from there. +Make sure you specify the proper version support in your ``setup.py`` file +-------------------------------------------------------------------------- -Target the newest version of Python 3 that you can. Beyond just the usual -bugfixes, compatibility has continued to improve between Python 2 and 3 as time -has passed. E.g. Python 3.3 added back the ``u`` prefix for -strings, making source-compatible Python code easier to write. +In your ``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``. +Have good test coverage using coverage.py_ +------------------------------------------ -Writing Source-Compatible Python 2/3 Code -========================================= +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 can't easily get past 90%). If you +don't already have a tool to measure test coverage then coverage.py_ is +recommended. -Over the years the Python community has discovered that the easiest way to -support both Python 2 and 3 in parallel is to write Python code that works in -either version. While this might sound counter-intuitive at first, it actually -is not difficult and typically only requires following some select -(non-idiomatic) practices and using some key projects to help make bridging -between Python 2 and 3 easier. +Learn the differences between Python 2 & 3 +------------------------------------------- -Projects to Consider --------------------- +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). -The lowest level library for supporting Python 2 & 3 simultaneously is six_. -Reading through its documentation will give you an idea of where exactly the -Python language changed between versions 2 & 3 and thus what you will want the -library to help you continue to support. -To help automate porting your code over to using six, you can use -modernize_. This project will attempt to rewrite your code to be as modern as -possible while using six to smooth out any differences between Python 2 & 3. +Update your code using Modernize_ or Futurize_ +---------------------------------------------- -If you want to write your compatible code to feel more like Python 3 there is -the future_ project. It tries to provide backports of objects from Python 3 so -that you can use them from Python 2-compatible code, e.g. replacing the -``bytes`` type from Python 2 with the one from Python 3. -It also provides a translation script like modernize (its translation code is -actually partially based on it) to help start working with a pre-existing code -base. It is also unique in that its translation script will also port Python 3 -code backwards as well as Python 2 code forwards. +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: Modernize_ and Futurize_. 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 +the ``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, relying on six_ to help provide compatibility. +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. +The resulting code should run under Python 2 with equivalent +semantics compared to before the transformation. 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. -Tips & Tricks -------------- +Unfortunately the tools can't automate everything for working 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). Luckily +there are only a couple of things to watch out for and to update manually. -To help with writing source-compatible code using one of the projects mentioned -in `Projects to Consider`_, consider following the below suggestions. Some of -them are handled by the suggested projects, so if you do use one of them then -read their documentation first to see which suggestions below will taken care of -for you. +Division +++++++++ -Support Python 2.7 -////////////////// +In Python 3, ``5 / 2 == 2.5`` and not ``2``. All division between ``int`` values +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 ``/`` and +``//`` 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 +things: -As a first step, make sure that your project is compatible with Python 2.7. -This is just good to do as Python 2.7 is the last release of Python 2 and thus -will be used for a rather long time. It also allows for use of the ``-3`` flag -to Python to help discover places in your code where compatibility might be an -issue (the ``-3`` flag is in Python 2.6 but Python 2.7 adds more warnings). +#. Add ``from __future__ import division`` to your files +#. Update any division operator as necessary to either use ``//`` to use floor + division or leave using ``/`` and expect a float -Try to Support Python 2.6 and Newer Only -//////////////////////////////////////// +The reason that ``/`` isn't simply translated to ``//`` automatically is that if +an object defines its own ``__div__`` method but not ``__floordiv__`` then your +code would begin to fail. -While not possible for all projects, if you can support Python 2.6 and newer -**only**, your life will be much easier. Various future statements, stdlib -additions, etc. exist only in Python 2.6 and later which greatly assist in -supporting Python 3. But if you project must keep support for Python 2.5 then -it is still possible to simultaneously support Python 3. +Text versus binary data ++++++++++++++++++++++++ -Below are the benefits you gain if you only have to support Python 2.6 and -newer. Some of these options are personal choice while others are -**strongly** recommended (the ones that are more for personal choice are -labeled as such). If you continue to support older versions of Python then you -at least need to watch out for situations that these solutions fix and handle -them appropriately (which is where library help from e.g. six_ comes in handy). +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 +that accepted ``str`` accepted either text or binary data instea of one specific +type. This complicated the situation especially for anyone supporting multiple +languages as APIs wouldn't bother explicitly supporting ``unicode`` which is +needed for many languages which are not Latin-1 compatible. +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. For any code that only deals 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. -``from __future__ import print_function`` -''''''''''''''''''''''''''''''''''''''''' +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 +with ``unicode`` and those that work with binary data work with the ``bytes`` +type from Python 3 and thus a subset of ``str`` in Python 2 (which the ``bytes`` +type in Python 2 is an alias for). Usually the biggest issue is realizing which +methods exist for which types in Python 2 & 3 (for text that's ``unicode`` in +Python 2 and ``str`` in Python 3, for binary that's ``str``/``bytes`` in +Python 2 and ``bytes`` in Python 3). The following table lists the *unique* +methods of each data type across Python 2 & 3. -It will not only get you used to typing ``print()`` as a function instead of a -statement, but it will also give you the various benefits the function has over -the Python 2 statement (six_ provides a function if you support Python 2.5 or -older). +=================== ===================== +**Text data** **Binary data** +------------------- --------------------- +\ decode +------------------- --------------------- +encode +------------------- --------------------- +format +------------------- --------------------- +isdecimal +------------------- --------------------- +isnumeric +=================== ===================== +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 when +you receive binary data you know to be text then 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. -``from __future__ import unicode_literals`` -''''''''''''''''''''''''''''''''''''''''''' +The next issue is making sure you know whether the string literals in your code +represent text or binary data. At minimum you should add a ``b`` prefix to any +literal that presents binary data. For text you should either use the +``from __future__ import unicode_literals`` statement or add a ``u`` prefix to +the text literal. -If you choose to use this future statement then all string literals in -Python 2 will be assumed to be Unicode (as is already the case in Python 3). -If you choose not to use this future statement then you should mark all of your -text strings with a ``u`` prefix and only support Python 3.3 or newer. But you -are **strongly** advised to do one or the other (six_ provides a function in -case you don't want to use the future statement **and** you want to support -Python 3.2 or older). +Finally, the indexing of binary data requires careful handling (slicing does +**not** require any special handling). In Python 2, +``b'123'[1] == b'2'`` while in Python 3 ``b'123'[1] == 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. This means you will need to choose how you +want to normalize this. If you want the Python 3 approach, wrap all bytes +indexing in ``ord()`` calls: ``ord(b'123'[1]) == 50``. For the Python 2 approach +use ``bytes()``: ``bytes(b'123'[1]) == b'1'``. The six_ project has a function +named ``six.indexbytes()`` if you prefer the Python 3 approach: +``six.indexbytes(b'123', 1)``. +To summarize: -Bytes/string literals -''''''''''''''''''''' +#. Decide which of your APIs take text and which take binary data +#. Make your code that works with text work with ``unicode`` and binary data + work with ``bytes`` in Python 2 (see the table above for what methods you + cannot use for each type) +#. Decode binary data to text as soon as possible, encode text as binary data as + late as possible +#. Be careful when indexing binary data -This is a **very** important one. Prefix Python 2 strings that -are meant to contain bytes with a ``b`` prefix to very clearly delineate -what is and is not a Python 3 text string (six_ provides a function to use for -Python 2.5 compatibility). +Prevent compatibility regressions using Pylint_ +----------------------------------------------- -This point cannot be stressed enough: make sure you know what all of your string -literals in Python 2 are meant to be in Python 3. Any string literal that -should be treated as bytes should have the ``b`` prefix. Any string literal -that should be Unicode/text in Python 2 should either have the ``u`` literal -(supported, but ignored, in Python 3.3 and later) or you should have -``from __future__ import unicode_literals`` at the top of the file. But the key -point is you should know how Python 3 will treat every one one of your string -literals and you should mark them as appropriate. +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. -There are some differences between byte literals in Python 2 and those in -Python 3 thanks to the bytes type just being an alias to ``str`` in Python 2. -See the `Handle Common "Gotchas"`_ section for what to watch out for. +You can 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. -``from __future__ import absolute_import`` -'''''''''''''''''''''''''''''''''''''''''' -Discussed in more detail below, but you should use this future statement to -prevent yourself from accidentally using implicit relative imports. +To also 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_statement + from __future__ import unicode_literals -Supporting Python 2.5 and Newer Only -//////////////////////////////////// -If you are supporting Python 2.5 and newer there are still some features of -Python that you can utilize. +Check which dependencies block your transition with caniusepython3_ +------------------------------------------------------------------- +**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 . -``from __future__ import absolute_import`` -'''''''''''''''''''''''''''''''''''''''''' +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. -Implicit relative imports (e.g., importing ``spam.bacon`` from within -``spam.eggs`` with the statement ``import bacon``) do not work in Python 3. -This future statement moves away from that and allows the use of explicit -relative imports (e.g., ``from . import bacon``). +Update your ``setup.py`` file to denote Python 3 compatibility +-------------------------------------------------------------- -In Python 2.5 you must use -the __future__ statement to get to use explicit relative imports and prevent -implicit ones. In Python 2.6 explicit relative imports are available without -the statement, but you still want the __future__ statement to prevent implicit -relative imports. In Python 2.7 the __future__ statement is not needed. In -other words, unless you are only supporting Python 2.7 or a version earlier -than Python 2.5, use this __future__ statement. +Once your code works under Python 3, you should update the classifiers in +your ``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. +Use continuous integration to stay compatible with tox_ +------------------------------------------------------- -Mark all Unicode strings with a ``u`` prefix -''''''''''''''''''''''''''''''''''''''''''''' +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. -While Python 2.6 has a ``__future__`` statement to automatically cause Python 2 -to treat all string literals as Unicode, Python 2.5 does not have that shortcut. -This means you should go through and mark all string literals with a ``u`` -prefix to turn them explicitly into text strings where appropriate and only -support Python 3.3 or newer. Otherwise use a project like six_ which provides a -function to pass all text string literals through. +And that's 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. -Capturing the Currently Raised Exception -'''''''''''''''''''''''''''''''''''''''' +Dropping Python 2 support completely +==================================== -In Python 2.5 and earlier the syntax to access the current exception is:: +If you are able to fully drop support for Python 2, then the steps required +to transition to Python 3 simplify greatly. - try: - raise Exception() - except Exception, exc: - # Current exception is 'exc'. - pass +#. Update your code to only support Python 2.7 +#. Make sure you have good test coverage (coverage.py_ can help) +#. Learn the differences between Python 2 & 3 +#. Use 2to3_ to rewrite your code to run only under Python 3 -This syntax changed in Python 3 (and backported to Python 2.6 and later) -to:: +After this your code will be fully Python 3 compliant but in a way that is not +supported by Python 2. You should also update the classifiers in your +``setup.py`` to contain ``Programming Language :: Python :: 3 :: Only``. - try: - raise Exception() - except Exception as exc: - # Current exception is 'exc'. - # In Python 3, 'exc' is restricted to the block; in Python 2.6/2.7 it will "leak". - pass -Because of this syntax change you must change how you capture the current -exception in Python 2.5 and earlier to:: +.. _2to3: https://docs.python.org/3/library/2to3.html +.. _caniusepython3: +.. _coverage.py: https://pypi.python.org/pypi/coverage +.. _Futurize: http://python-future.org/automatic_conversion.html +.. _Modernize: +.. _Porting to Python 3: http://python3porting.com/ +.. _Pylint: https://pypi.python.org/pypi/pylint +.. _Python 3 Q & A: http://ncoghlan-devs-python-notes.readthedocs.org/en/latest/python3/questions_and_answers.html - try: - raise Exception() - except Exception: - import sys - exc = sys.exc_info()[1] - # Current exception is 'exc'. - pass - -You can get more information about the raised exception from -:func:`sys.exc_info` than simply the current exception instance, but you most -likely don't need it. - -.. note:: - In Python 3, the traceback is attached to the exception instance - through the ``__traceback__`` attribute. If the instance is saved in - a local variable that persists outside of the ``except`` block, the - traceback will create a reference cycle with the current frame and its - dictionary of local variables. This will delay reclaiming dead - resources until the next cyclic :term:`garbage collection` pass. - - In Python 2, this problem only occurs if you save the traceback itself - (e.g. the third element of the tuple returned by :func:`sys.exc_info`) - in a variable. - - -Handle Common "Gotchas" -/////////////////////// - -These are things to watch out for no matter what version of Python 2 you are -supporting which are not syntactic considerations. - - -``from __future__ import division`` -''''''''''''''''''''''''''''''''''' - -While the exact same outcome can be had by using the ``-Qnew`` argument to -Python, using this future statement lifts the requirement that your users use -the flag to get the expected behavior of division in Python 3 -(e.g., ``1/2 == 0.5; 1//2 == 0``). - - - -Specify when opening a file as binary -''''''''''''''''''''''''''''''''''''' - -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., ``rb`` for -binary reading). Under Python 3, binary files and text files are clearly -distinct and mutually incompatible; see the :mod:`io` module for details. -Therefore, you **must** make a decision of whether a file will be used for -binary access (allowing to read and/or write bytes data) or text access -(allowing to read and/or write unicode data). - -Text files -'''''''''' - -Text files created using ``open()`` under Python 2 return byte strings, -while under Python 3 they return unicode strings. Depending on your porting -strategy, this can be an issue. - -If you want text files to return unicode strings in Python 2, you have two -possibilities: - -* Under Python 2.6 and higher, use :func:`io.open`. Since :func:`io.open` - is essentially the same function in both Python 2 and Python 3, it will - help iron out any issues that might arise. - -* If pre-2.6 compatibility is needed, then you should use :func:`codecs.open` - instead. This will make sure that you get back unicode strings in Python 2. - -Subclass ``object`` -''''''''''''''''''' - -New-style classes have been around since Python 2.2. You need to make sure -you are subclassing from ``object`` to avoid odd edge cases involving method -resolution order, etc. This continues to be totally valid in Python 3 (although -unneeded as all classes implicitly inherit from ``object``). - - -Deal With the Bytes/String Dichotomy -'''''''''''''''''''''''''''''''''''' - -One of the biggest issues people have when porting code to Python 3 is handling -the bytes/string dichotomy. Because Python 2 allowed the ``str`` type to hold -textual data, people have over the years been rather loose in their delineation -of what ``str`` instances held text compared to bytes. In Python 3 you cannot -be so care-free anymore and need to properly handle the difference. The key to -handling this issue is to make sure that **every** string literal in your -Python 2 code is either syntactically or functionally marked as either bytes or -text data. After this is done you then need to make sure your APIs are designed -to either handle a specific type or made to be properly polymorphic. - - -Mark Up Python 2 String Literals -******************************** - -First thing you must do is designate every single string literal in Python 2 -as either textual or bytes data. If you are only supporting Python 2.6 or -newer, this can be accomplished by marking bytes literals with a ``b`` prefix -and then designating textual data with a ``u`` prefix or using the -``unicode_literals`` future statement. - -If your project supports versions of Python predating 2.6, then you should use -the six_ project and its ``b()`` function to denote bytes literals. For text -literals you can either use six's ``u()`` function or use a ``u`` prefix. - - -Decide what APIs Will Accept -**************************** - -In Python 2 it was very easy to accidentally create an API that accepted both -bytes and textual data. But in Python 3, thanks to the more strict handling of -disparate types, this loose usage of bytes and text together tends to fail. - -Take the dict ``{b'a': 'bytes', u'a': 'text'}`` in Python 2.6. It creates the -dict ``{u'a': 'text'}`` since ``b'a' == u'a'``. But in Python 3 the equivalent -dict creates ``{b'a': 'bytes', 'a': 'text'}``, i.e., no lost data. Similar -issues can crop up when transitioning Python 2 code to Python 3. - -This means you need to choose what an API is going to accept and create and -consistently stick to that API in both Python 2 and 3. - - -Bytes / Unicode Comparison -************************** - -In Python 3, mixing bytes and unicode is forbidden in most situations; it -will raise a :class:`TypeError` where Python 2 would have attempted an implicit -coercion between types. However, there is one case where it doesn't and -it can be very misleading:: - - >>> b"" == "" - False - -This is because an equality comparison is required by the language to always -succeed (and return ``False`` for incompatible types). However, this also -means that code incorrectly ported to Python 3 can display buggy behaviour -if such comparisons are silently executed. To detect such situations, -Python 3 has a ``-b`` flag that will display a warning:: - - $ python3 -b - >>> b"" == "" - __main__:1: BytesWarning: Comparison between bytes and string - False - -To turn the warning into an exception, use the ``-bb`` flag instead:: - - $ python3 -bb - >>> b"" == "" - Traceback (most recent call last): - File "", line 1, in - BytesWarning: Comparison between bytes and string - - -Indexing bytes objects -'''''''''''''''''''''' - -Another potentially surprising change is the indexing behaviour of bytes -objects in Python 3:: - - >>> b"xyz"[0] - 120 - -Indeed, Python 3 bytes objects (as well as :class:`bytearray` objects) -are sequences of integers. But code converted from Python 2 will often -assume that indexing a bytestring produces another bytestring, not an -integer. To reconcile both behaviours, use slicing:: - - >>> b"xyz"[0:1] - b'x' - >>> n = 1 - >>> b"xyz"[n:n+1] - b'y' - -The only remaining gotcha is that an out-of-bounds slice returns an empty -bytes object instead of raising ``IndexError``: - - >>> b"xyz"[3] - Traceback (most recent call last): - File "", line 1, in - IndexError: index out of range - >>> b"xyz"[3:4] - b'' - - -``__str__()``/``__unicode__()`` -''''''''''''''''''''''''''''''' - -In Python 2, objects can specify both a string and unicode representation of -themselves. In Python 3, though, there is only a string representation. This -becomes an issue as people can inadvertently do things in their ``__str__()`` -methods which have unpredictable results (e.g., infinite recursion if you -happen to use the ``unicode(self).encode('utf8')`` idiom as the body of your -``__str__()`` method). - -You can use a mixin class to work around this. This allows you to only define a -``__unicode__()`` method for your class and let the mixin derive -``__str__()`` for you (code from -http://lucumr.pocoo.org/2011/1/22/forwards-compatible-python/):: - - import sys - - class UnicodeMixin(object): - - """Mixin class to handle defining the proper __str__/__unicode__ - methods in Python 2 or 3.""" - - if sys.version_info[0] >= 3: # Python 3 - def __str__(self): - return self.__unicode__() - else: # Python 2 - def __str__(self): - return self.__unicode__().encode('utf8') - - - class Spam(UnicodeMixin): - - def __unicode__(self): - return u'spam-spam-bacon-spam' # 2to3 will remove the 'u' prefix - - -Don't Index on Exceptions -''''''''''''''''''''''''' - -In Python 2, the following worked:: - - >>> exc = Exception(1, 2, 3) - >>> exc.args[1] - 2 - >>> exc[1] # Python 2 only! - 2 - -But in Python 3, indexing directly on an exception is an error. You need to -make sure to only index on the :attr:`BaseException.args` attribute which is a -sequence containing all arguments passed to the :meth:`__init__` method. - -Even better is to use the documented attributes the exception provides. - - -Don't use ``__getslice__`` & Friends -'''''''''''''''''''''''''''''''''''' - -Been deprecated for a while, but Python 3 finally drops support for -``__getslice__()``, etc. Move completely over to :meth:`__getitem__` and -friends. - - -Updating doctests -''''''''''''''''' - -Don't forget to make them Python 2/3 compatible as well. If you wrote a -monolithic set of doctests (e.g., a single docstring containing all of your -doctests), you should at least consider breaking the doctests up into smaller -pieces to make it more manageable to fix. Otherwise it might very well be worth -your time and effort to port your tests to :mod:`unittest`. - - -Update ``map`` for imbalanced input sequences -''''''''''''''''''''''''''''''''''''''''''''' - -With Python 2, when ``map`` was given more than one input sequence it would pad -the shorter sequences with ``None`` values, returning a sequence as long as the -longest input sequence. - -With Python 3, if the input sequences to ``map`` are of unequal length, ``map`` -will stop at the termination of the shortest of the sequences. For full -compatibility with ``map`` from Python 2.x, wrap the sequence arguments in -:func:`itertools.zip_longest`, e.g. ``map(func, *sequences)`` becomes -``list(map(func, itertools.zip_longest(*sequences)))``. - -Eliminate ``-3`` Warnings -------------------------- - -When you run your application's test suite, run it using the ``-3`` flag passed -to Python. This will cause various warnings to be raised during execution about -things that are semantic changes between Python 2 and 3. Try to eliminate those -warnings to make your code even more portable to Python 3. - - -Alternative Approaches -====================== - -While supporting Python 2 & 3 simultaneously is typically the preferred choice -by people so that they can continue to improve code and have it work for the -most number of users, your life may be easier if you only have to support one -major version of Python going forward. - -Supporting Only Python 3 Going Forward From Python 2 Code ---------------------------------------------------------- - -If you have Python 2 code but going forward only want to improve it as Python 3 -code, then you can use :ref:`2to3 <2to3-reference>` to translate your Python 2 -code to Python 3 code. This is only recommended, though, if your current -version of your project is going into maintenance mode and you want all new -features to be exclusive to Python 3. - - -Backporting Python 3 code to Python 2 -------------------------------------- - -If you have Python 3 code and have little interest in supporting Python 2 you -can use 3to2_ to translate from Python 3 code to Python 2 code. This is only -recommended if you don't plan to heavily support Python 2 users. Otherwise -write your code for Python 3 and then backport as far back as you want. This -is typically easier than going from Python 2 to 3 as you will have worked out -any difficulties with e.g. bytes/strings, etc. - - -Other Resources -=============== - -The authors of the following blog posts, wiki pages, and books deserve special -thanks for making public their tips for porting Python 2 code to Python 3 (and -thus helping provide information for this document and its various revisions -over the years): - -* https://wiki.python.org/moin/PortingPythonToPy3k -* http://python3porting.com/ -* http://docs.pythonsprints.com/python3_porting/py-porting.html -* http://techspot.zzzeek.org/2011/01/24/zzzeek-s-guide-to-python-3-porting/ -* http://dabeaz.blogspot.com/2011/01/porting-py65-and-my-superboard-to.html -* http://lucumr.pocoo.org/2011/1/22/forwards-compatible-python/ -* http://lucumr.pocoo.org/2010/2/11/porting-to-python-3-a-guide/ -* https://wiki.ubuntu.com/Python/3 - -If you feel there is something missing from this document that should be added, -please email the python-porting_ mailing list. - - -.. _3to2: https://pypi.python.org/pypi/3to2 -.. _Cheeseshop: PyPI_ -.. _coverage: https://pypi.python.org/pypi/coverage -.. _future: http://python-future.org/ -.. _modernize: https://github.com/mitsuhiko/python-modernize -.. _Porting to Python 3: http://python3porting.com/ -.. _PyPI: https://pypi.python.org/pypi -.. _Python 3 Packages: https://pypi.python.org/pypi?:action=browse&c=533&show=all -.. _Python 3 Q & A: http://ncoghlan-devs-python-notes.readthedocs.org/en/latest/python3/questions_and_answers.html +.. _python-future: http://python-future.org/ .. _python-porting: https://mail.python.org/mailman/listinfo/python-porting .. _six: https://pypi.python.org/pypi/six .. _tox: https://pypi.python.org/pypi/tox -.. _trove classifiers: https://pypi.python.org/pypi?%3Aaction=list_classifiers +.. _trove classifier: https://pypi.python.org/pypi?%3Aaction=list_classifiers +.. _"What's New": https://docs.python.org/3/whatsnew/index.html