Contributing Guidelines

PyPy is a very large project that has a reputation of being hard to dive into. Some of this fame is warranted, some of it is purely accidental. There are three important lessons that everyone willing to contribute should learn:

  • PyPy has layers. There are many pieces of architecture that are very well separated from each other. More about this below, but often the manifestation of this is that things are at a different layer than you would expect them to be. For example if you are looking for the JIT implementation, you will not find it in the implementation of the Python programming language.

  • Because of the above, we are very serious about Test Driven Development. It’s not only what we believe in, but also that PyPy’s architecture is working very well with TDD in mind and not so well without it. Often development means progressing in an unrelated corner, one unittest at a time; and then flipping a giant switch, bringing it all together. (It generally works out of the box. If it doesn’t, then we didn’t write enough unit tests.) It’s worth repeating - PyPy’s approach is great if you do TDD, and not so great otherwise.

  • PyPy uses an entirely different set of tools - most of them included in the PyPy repository. There is no Makefile, nor autoconf. More below.

The first thing to remember is that PyPy project is very different than most projects out there. It’s also different from a classic compiler project, so academic courses about compilers often don’t apply or lead in the wrong direction. However, if you want to understand how designing & building a runtime works in the real world then this is a great project!

Getting involved

PyPy employs a relatively standard open-source development process. You are encouraged as a first step to join our pypy-dev mailing list and IRC channel, details of which can be found in our contact section. The folks there are very friendly, and can point you in the right direction.

We give out commit rights usually fairly liberally, so if you want to do something with PyPy, you can become a committer. We also run frequent coding sprints which are separately announced and often happen around Python conferences such as EuroPython or PyCon. Upcoming events are usually announced on the blog.

Further Reading: Contact

Your first contribution

The first and most important rule how not to contribute to PyPy is “just hacking a feature”. This won’t work, and you’ll find your PR will typically require a lot of re-work. There are a few reasons why not:

  • build times are large

  • PyPy has very thick layer separation

  • context of the cPython runtime is often required

Instead, reach out on the dev mailing list or the IRC channel, and we’re more than happy to help! :)

Some ideas for first contributions are:

  • Documentation - this will give you an understanding of the pypy architecture

  • Test failures - find a failing test in the nightly builds, and fix it

  • Missing language features - these are listed in our issue tracker

Source Control

PyPy’s main repositories are hosted here: https://foss.heptapod.net/pypy.

Heptapod is a friendly fork of GitLab Community Edition supporting Mercurial. https://foss.heptapod.net is a public instance for Free and Open-Source Software (more information here).

Thanks to Octobus and Clever Cloud for providing this service!

Octobus + Clever Cloud

If you are new with Mercurial and Heptapod, you can read this short tutorial

However, we recommend at this time you not use topic branches. We prefer the usual mercurial named branch model, as pointed out in the FAQ about why we didn’t move to git.

Get Access

The important take-away from that tutorial for experienced developers is that since the free hosting on foss.heptapod.net does not allow personal forks, you need permissions to push your changes directly to our repo. Once you sign in to https://foss.heptapod.net using either a new login or your GitHub or Atlassian logins, you can get developer status for pushing directly to the project (just ask by clicking the link at foss.heptapod.net/pypy just under the logo, and you’ll get it, basically). Once you have it you can rewrite your file .hg/hgrc to contain default = ssh://hg@foss.heptapod.net/pypy/pypy. Your changes will then be pushed directly to the official repo, but (if you follow these rules) they are still on a branch, and we can still review the branches you want to merge. With developer status, you can push topic branches. If you wish to push long-lived branches, you will need to ask for higher permissions.

Clone

  • Clone the PyPy repo to your local machine with the command hg clone https://foss.heptapod.net/pypy/pypy. It takes a minute or two operation but only ever needs to be done once. See also https://pypy.org/download.html#building-from-source . If you already cloned the repo before, even if some time ago, then you can reuse the same clone by editing the file .hg/hgrc in your clone to contain the line default = https://foss.heptapod.net/pypy/pypy, and then do hg pull && hg up. If you already have such a clone but don’t want to change it, you can clone that copy with hg clone /path/to/other/copy, and then edit .hg/hgrc as above and do hg pull && hg up.

  • Now you have a complete copy of the PyPy repo. Make a long-lived branch with a command like hg branch name_of_your_branch, or make a short- lived branch for a simple fix with a command like hg topic issueXXXX.

Edit

  • Edit things. Use hg diff to see what you changed. Use hg add to make Mercurial aware of new files you added, e.g. new test files. Use hg status to see if there are such files. Write and run tests! (See the rest of this page.)

  • Commit regularly with hg commit. A one-line commit message is fine. We love to have tons of commits; make one as soon as you have some progress, even if it is only some new test that doesn’t pass yet, or fixing things even if not all tests pass. Step by step, you are building the history of your changes, which is the point of a version control system. (There are commands like hg log and hg up that you should read about later, to learn how to navigate this history.)

  • The commits stay on your machine until you do hg push to “push” them back to the repo named in the file .hg/hgrc. Repos are basically just collections of commits (a commit is also called a changeset): there is one repo per url, plus one for each local copy on each local machine. The commands hg push and hg pull copy commits around, with the goal that all repos in question end up with the exact same set of commits. By opposition, hg up only updates the “working copy” by reading the local repository, i.e. it makes the files that you see correspond to the latest (or any other) commit locally present.

  • You should push often; there is no real reason not to. Remember that even if they are pushed, with the setup above, the commits are only in the branch you named. Yes, they are publicly visible, but don’t worry about someone walking around the many branches of PyPy saying “hah, look at the bad coding style of that person”. Try to get into the mindset that your work is not secret and it’s fine that way. We might not accept it as is for PyPy, asking you instead to improve some things, but we are not going to judge you unless you don’t write tests.

Merge Request

  • The final step is to open a merge request, so that we know that you’d like to merge that branch back to the original pypy/pypy repo. This can also be done several times if you have interesting intermediate states, but if you get there, then we’re likely to proceed to the next stage, which is…

  • If you get closer to the regular day-to-day development, you’ll notice that we generally push small changes as one or a few commits directly to the branch default or py3.6. Also, we often collaborate even if we are on other branches, which do not really “belong” to anyone. At this point you’ll need hg merge and learn how to resolve conflicts that sometimes occur when two people try to push different commits in parallel on the same branch. But it is likely an issue for later :-)

Architecture

PyPy has layers. Just like ogres or onions. Those layers help us keep the respective parts separated enough to be worked on independently and make the complexity manageable. This is, again, just a sanity requirement for such a complex project. For example writing a new optimization for the JIT usually does not involve touching a Python interpreter at all or the JIT assembler backend or the garbage collector. Instead it requires writing small tests in rpython/jit/metainterp/optimizeopt/test/test_* and fixing files there. After that, you can just compile PyPy and things should just work.

Further Reading: architecture

Where to start?

PyPy is made from parts that are relatively independent of each other. You should start looking at the part that attracts you most (all paths are relative to the PyPy top level directory). You may look at our directory reference or start off at one of the following points:

Building

For building PyPy, we recommend installing a pre-built PyPy first (see Downloading and Installing PyPy). It is possible to build PyPy with CPython, but it will take a lot longer to run – depending on your architecture, between two and three times as long.

Further Reading: Build

Coding Guide

As well as the usual pep8 and formatting standards, there are a number of naming conventions and coding styles that are important to understand before browsing the source.

Further Reading: Coding Guide

Testing

Test driven development

Instead, we practice a lot of test driven development. This is partly because of very high quality requirements for compilers and partly because there is simply no other way to get around such complex project, that will keep you sane. There are probably people out there who are smart enough not to need it, we’re not one of those. You may consider familiarizing yourself with pytest, since this is a tool we use for tests. This leads to the next issue:

py.test and the py lib

The py.test testing tool drives all our testing needs.

We use the py library for filesystem path manipulations, terminal writing, logging and some other support functionality.

You don’t necessarily need to install these two libraries because we also ship them inlined in the PyPy source tree.

Running PyPy’s unit tests

PyPy development always was and is still thoroughly test-driven. We use the flexible py.test testing tool which you can install independently and use for other projects.

The PyPy source tree comes with an inlined version of py.test which you can invoke by typing:

python pytest.py -h

This is usually equivalent to using an installed version:

py.test -h

If you encounter problems with the installed version make sure you have the correct version installed which you can find out with the --version switch.

You will need the build requirements to run tests successfully, since many of them compile little pieces of PyPy and then run the tests inside that minimal interpreter. The cpyext tests also require pycparser, and many tests build cases with hypothesis.

Now on to running some tests. PyPy has many different test directories and you can use shell completion to point at directories or files:

py.test pypy/interpreter/test/test_pyframe.py

# or for running tests of a whole subdirectory
py.test pypy/interpreter/

See py.test usage and invocations for some more generic info on how you can run tests.

Beware trying to run “all” pypy tests by pointing to the root directory or even the top level subdirectory pypy. It takes hours and uses huge amounts of RAM and is not recommended.

To run CPython regression tests, you should start with a translated PyPy and run the tests as you would with CPython (see below). You can, however, also attempt to run the tests before translation, but be aware that it is done with a hack that doesn’t work in all cases and it is usually extremely slow: py.test lib-python/2.7/test/test_datetime.py. Usually, a better idea is to extract a minimal failing test of at most a few lines, and put it into one of our own tests in pypy/*/test/.

Testing After Translation

While the usual invocation of pytest runs app-level tests on an untranslated PyPy that runs on top of CPython, we have a test extension to run tests directly on the host python. This is very convenient for modules such as cpyext, to compare and contrast test results between CPython and PyPy.

App-level tests run directly on the host interpreter when passing -D or –direct-apptest to pytest:

pypy3 -m pytest -D pypy/interpreter/test/apptest_pyframe.py

Mixed-level tests are invoked by using the -A or –runappdirect option to pytest:

python2 pytest.py -A pypy/module/cpyext/test

where python2 can be either python2 or pypy2. On the py3 branch, the collection phase must be run with python2 so untranslated tests are run with:

cpython2 pytest.py -A pypy/module/cpyext/test --python=path/to/pypy3

To run a test from the standard CPython regression test suite, use the regular Python way, i.e. (replace “pypy” with the exact binary name, if needed):

pypy -m test.test_datetime

Tooling & Utilities

If you are interested in the inner workings of the PyPy Python interpreter, there are some features of the untranslated Python interpreter that allow you to introspect its internals.

Interpreter-level console

To start interpreting Python with PyPy, install a C compiler that is supported by distutils and use Python 2.7 or greater to run PyPy:

cd pypy
python bin/pyinteractive.py

After a few seconds (remember: this is running on top of CPython), you should be at the PyPy prompt, which is the same as the Python prompt, but with an extra “>”.

If you press <Ctrl-C> on the console you enter the interpreter-level console, a usual CPython console. You can then access internal objects of PyPy (e.g. the object space) and any variables you have created on the PyPy prompt with the prefix w_:

>>>> a = 123
>>>> <Ctrl-C>
*** Entering interpreter-level console ***
>>> w_a
W_IntObject(123)

The mechanism works in both directions. If you define a variable with the w_ prefix on the interpreter-level, you will see it on the app-level:

>>> w_l = space.newlist([space.wrap(1), space.wrap("abc")])
>>> <Ctrl-D>
*** Leaving interpreter-level console ***

KeyboardInterrupt
>>>> l
[1, 'abc']

Note that the prompt of the interpreter-level console is only ‘>>>’ since it runs on CPython level. If you want to return to PyPy, press <Ctrl-D> (under Linux) or <Ctrl-Z>, <Enter> (under Windows).

Also note that not all modules are available by default in this mode (for example: _continuation needed by greenlet) , you may need to use one of --withmod-... command line options.

You may be interested in reading more about the distinction between interpreter-level and app-level.

pyinteractive.py options

To list the PyPy interpreter command line options, type:

cd pypy
python bin/pyinteractive.py --help

pyinteractive.py supports most of the options that CPython supports too (in addition to a large amount of options that can be used to customize pyinteractive.py). As an example of using PyPy from the command line, you could type:

python pyinteractive.py --withmod-time -c "from test import pystone; pystone.main(10)"

Alternatively, as with regular Python, you can simply give a script name on the command line:

python pyinteractive.py --withmod-time ../../lib-python/2.7/test/pystone.py 10

The --withmod-xxx option enables the built-in module xxx. By default almost none of them are, because initializing them takes time. If you want anyway to enable all built-in modules, you can use --allworkingmodules.

See our configuration sections for details about what all the commandline options do.

Tracing bytecode and operations on objects

You can use a simple tracing mode to monitor the interpretation of bytecodes. To enable it, set __pytrace__ = 1 on the interactive PyPy console:

>>>> __pytrace__ = 1
Tracing enabled
>>>> x = 5
        <module>:           LOAD_CONST    0 (5)
        <module>:           STORE_NAME    0 (x)
        <module>:           LOAD_CONST    1 (None)
        <module>:           RETURN_VALUE    0
>>>> x
        <module>:           LOAD_NAME    0 (x)
        <module>:           PRINT_EXPR    0
5
        <module>:           LOAD_CONST    0 (None)
        <module>:           RETURN_VALUE    0
>>>>

Demos

The example-interpreter repository contains an example interpreter written using the RPython translation toolchain.