wiki:Python3

Version 76 (modified by chadwhitacre, at 2021-02-27T19:51:03Z) (diff)

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Porting to Python 3

Motivation

  • Make code behave the same on Python 2 and Python 3, insofar as one can, so e.g. map() is the same on Python 2 and Python 3 (i.e. lazy).
  • Reduce errors by relying on Python 2 behavior and tests as well as manual review.
  • Try to reduce grunt work.

How to set up your development environment

We use tox to standardize environments across developers and CI.

  1. Install tox (globally, probably; consider pipx).
  2. In your Tahoe-LAFS working copy, run tox -e py36 --notest to bootstrap the py36 virtualenv.
  3. Activate the environment with source .tox/py36/bin/activate or equivalent.
  4. Wire up for local dev with pip install -e .
  5. Run trial allmydata.test.test_python3 as a smoke test.
  6. Options for exercising the whole suite of ported tests (NB: test_python3 != python3_tests):
    1. trial allmydata.test.python3_tests
    2. python -m allmydata.test.python3_tests
    3. deactivate the virtualenv (or switch shells) and run tox -e py36

Worklist

Submodule† Status Assignee Notes
__init__ todo
_version todo
check_results todo
client todo
testing todo
windows todo
test doing
test_system doing Two more tests are skipped, blocked on web and cli being ported
util doing
frontends doing itamarst
scripts doing jaraco
__main__ done
_auto_deps done
blacklist done
codec done
control done
crypto done
deep_stats done
dirnode done
hashtree done
history done
immutable done
interfaces done
introducer done
monitor done
mutable done
node done
nodemaker done
stats done
storage_client done
storage done
unknown done
uri done
version_checks done
web done
webish done

† of allmydata

‡ Expect spaghetti (see below).

The porting process, big picture

For a module M, there is also a corresponding module T, the unittests for M. If the tests for M are embedded into a module that tests multiple modules, step one is to split off the tests so there's T that only tests M.

Then:

  1. Update T to run on both 2+3 (see below for what that looks like).
  2. Run T's tests on Python 2. They should still pass! If they don’t, something broke.
  3. Port the code module M.
  4. Now run T's tests on Python 3.
  5. Fix any problems caught by the tests.
  6. Add both M and T to allmydata/util/_python3.py.
  7. Run tox -e py36 (or equivalent) and verify that the module you ported is included and passing.
  8. Submit for code review.
  9. Check coverage report. If there are uncovered lines, see if you can add tests, or at least file a separate ticket for adding coverage.

When ports get harder due to spaghetti dependencies

As the port progresses, the simple "port module + its test module" gets difficult, since everything ends up depending on everything else. Here's one way to approach this:

  1. Port only the test module. This involves many Python 3 fixes to lots of other modules, but they are not officially ported, they're just inched along just enough to make the tests pass. Since the test module is officially ported, regressions to the Python 3 port still are prevented.
  2. Then, port the corresponding module.

When doing the incidental fixes to other modules, try to change as little as possible: no __future__ imports, no from future.builtins import all thte things, just enough changes to make the tests you care enough pass. This reduces chances of unintentional breakage and unintentional scope creep. You might even do temporary things like from past.builtins import unicode. Later on when specifically porting a you can Do All The Things the right way.

Porting a specific Python file

Zeroth, file a new ticket in milestone "Python 3", assign it to yourself.

First, add explicit byte or unicode annotations for strings where needed.

Second, run futurize --write --both-stages --all-imports path/to/file.py.

Third, fix the imports (automation below).

Delete this bit:

from future import standard_library
standard_library.install_aliases()
from builtins import str

And replace the from builtins import * variant, if any, with:

from future.utils import PY2
if PY2:
    from future.builtins import filter, map, zip, ascii, chr, hex, input, next, oct, open, pow, round, super, bytes, dict, list, object, range, str, max, min  # noqa: F401

This adds builtins that match Python 3's semantics. The #noqa: F401 keeps flake8/pyflakes from complaining about unused imports. We do unused imports so that people changing code later don't have to manually check if map() is old style or new style.

Then, delete any instances of from builtins import <name>.

Consider using this sed command to execute the above:

$ sed -ie '/from future import standard_library/d;/standard_library.install_aliases()/d;s/from builtins import \*/from future.utils import PY2\\nif PY2:\\n    from future.builtins import filter, map, zip, ascii, chr, hex, input, next, oct, open, pow, round, super, bytes, dict, list, object, range, str, max, min  # noqa: F401/;/from builtins import .*/d' path/to/file.py

Fourth, manually review the code. Futureize is nice, but it very definitely doesn't catch everything, or it makes wrong decisions.

In particular:

  • map(), filter(), etc. are now lazy.
  • dict.keys() and friends now return a view of the underlying data, rather than a list with a copy.

Fifth, add a note to the module docstring saying it was ported to Python 3.

Sixth, open a PR with the Python 3 Port label.

Known issues with future

The from builtins import <every builtin ever> thing gives a decent Python 3 layer for Python 2. For example it'll automatically create __nonzero__ to wrap a __bool__.

But there are caveats.

One of them is the bytes objects:

  1. builtins.bytes.translate are builtins.bytes.maketrans buggy on PyPy?. One way to fix this is with a if PY2: translate = string.translate else: translate = bytes.translate.
  2. The behavior with b"%s" % some_bytes_object works fine if both objects are Future builtins.bytes, or both objects are native Python 2 strings/bytes, but not if you combine them. This has caused bugs. One way to fix this is by exposing only native byte strings for now, see e.g. allmydata.util.base32.

Don't leak Future objects

Leaking Future objects (newints, new dicts, new bytes) in module API can break existing code on Python 2. So need to be careful not to do that. For that reason int isn't in the suggested from builtins import ... list above.

Dealing with utility modules

Often you will have some utility module with lots of random code, some of which doesn't work on Python 3, or which even involves imports of non-Python-3-compatbile code (Nevow, in this case).

Options:

  1. Create new util_py3.py module, move just the things you need, have util.py import code from there.
  2. Add conditional imports/declarations to util.py so it imports on Python 3 and at least some of the code can be made to work.

Originally we went with first approach, but plausibly second approach is better.

Serializing bytes with JSON

In Python 2 you can serialize bytes with json. In Python 3 you can't. Real Soon Now there will be utility module allmydata.util.jsonbytes that allows encoding bytes on Python 3, to minimize changes.

Dictionaries with bytes/unicode keys

In Python 2 a key can be bytes or unicode, and it will replace the other one. So the key b"foo" is the same as u"foo" from dict's perspective. In Python 3 they are different keys.

This can lead to bugs when porting, where you end up with two keys instead of one as some strings become Unicode strings.

The interim solution will likely be dicts that enforce key type to be only bytes or only Unicode (https://tahoe-lafs.org/trac/tahoe-lafs/ticket/3476#ticket).

Avoid massive changes

Sometimes it's easier to be a little more lenient in input (support both unicode and bytes), or to change some type to unicode, instead of having to change hundreds of lines of code from unicode to bytes when porting. When to do so is a judgement call, but if you are changing massive amounts of code to have b"" prefix _and_ byteness isn't important, consider alternative approaches.