RustPython attracts developers with interest and experience in Rust, Python, or WebAssembly. Whether you are familiar with Rust, Python, or WebAssembly, the goal of this Development Guide is to give you the basics to get set up for developing RustPython and contributing to this project.
The contents of the Development Guide include:
- Setting up a development environment
- Code style
- Testing
- Profiling
- Code organization
- Understanding internals
- Questions
RustPython requires the following:
- Rust 1.36 or higher
- To check Rust version:
rustc --version
- If you have
rustup
on your system, enter to update to the latest stable version:rustup update stable
- If you do not have Rust installed, use rustup to do so.
- To check Rust version:
- CPython version 3.7.4 or higher
- CPython can be installed by your operating system's package manager, from the Python website, or using a third-party distribution, such as Anaconda.
- [Optional] The Python package,
pytest
, is used for testing Python code snippets. To install, enterpython3 -m pip install pytest
.
The Rust code style used is the default rustfmt codestyle. Please format your code accordingly. We also use clippy to detect rust code issues.
Python code should follow the PEP 8 style. We also use flake8 to check Python code style.
To test RustPython's functionality, a collection of Python snippets is located
in the tests/snippets
directory and can be run using pytest
:
$ cd tests
$ pytest -v
Rust unit tests can be run with cargo
:
$ cargo test --all
To profile RustPython, build it in release
mode with the flame-it
feature.
This will generate a file flamescope.json
, which can be viewed at
https://speedscope.app.
$ cargo run --release --features flame-it script.py
$ cat flamescope.json
{<json>}
You can specify another file name other than the default by using the
--output-file
option to specify a file name (or stdout
if you specify -
).
The --output-format
option determines the format of the output file.
The speedscope json format (default), text, or raw html can be passed. There
exists a raw html viewer which is currently broken, and we welcome a PR to fix it.
Understanding a new codebase takes time. Here's a brief view of the repository's structure:
bytecode/src
: python bytecode representation in rust structurescompiler/src
: python compilation to bytecodederive/src
: Rust language extensions and macros specific to rustpythonparser/src
: python lexing, parsing and astLib
: Carefully selected / copied files from CPython sourcecode. This is the python side of the standard library.vm/src
: python virtual machinebuiltins.rs
: Builtin functionscompile.rs
: the python compiler from ast to bytecodeobj
: python builtin typesstdlib
: Standard library parts implemented in rust.
src
: using the other subcrates to bring rustpython to life.docs
: documentation (work in progress)py_code_object
: CPython bytecode to rustpython bytecode converter (work in progress)wasm
: Binary crate and resources for WebAssembly buildtests
: integration test snippets
The RustPython workspace includes the rustpython
top-level crate. The Cargo.toml
file in the root of the repo provide configuration of the crate and the
implementation is found in the src
directory (specifically,
src/main.rs
).
The top-level rustpython
binary depends on several lower-level crates including:
rustpython-parser
(implementation inparser/src
)rustpython-compiler
(implementation incompiler/src
)rustpython-vm
(implementation invm/src
)
Together, these crates provide the functions of a programming language and enable a line of code to go through a series of steps:
- parse the line of source code into tokens
- determine if the tokens are valid syntax
- create an Abstract Syntax Tree (AST)
- compile the AST into bytecode
- execute the bytecode in the virtual machine (VM).
This crate contains the lexer and parser to convert a line of code to an Abstract Syntax Tree (AST):
- Lexer:
parser/lexer.rs
converts Python source code into tokens - Parser:
parser/parser.rs
takes the tokens generated by the lexer and parses the tokens into an AST (Abstract Syntax Tree) where the nodes of the syntax tree are Rust structs and enums.- The Parser relies on
LALRPOP
, a Rust parser generator framework. - More information on parsers and a tutorial can be found in the LALRPOP book.
- The Parser relies on
- AST:
parser/ast.rs
implements in Rust the Python types and expressions represented by the AST nodes.
The rustpython-compiler
crate's purpose is to transform the AST (Abstract Syntax
Tree) to bytecode. The implementation of the compiler is found in the
compiler/src
directory. The compiler implements Python's peephole optimizer
implementation, Symbol table, and streams in Rust.
Implementation of bytecode structure in Rust is found in the bytecode/src
directory. The bytecode/src/bytecode.rs
contains the representation of
instructions and operations in Rust. Further information about Python's
bytecode instructions can be found in the
Python documentation.
The rustpython-vm
crate has the important job of running the virtual machine that
executes Python's instructions. The vm/src
directory contains code to
implement the read and evaluation loop that fetches and dispatches
instructions. This directory also contains the implementation of the
Python Standard Library modules in Rust (vm/src/stdlib
). In Python
everything can be represented as an Object. vm/src/obj
directory holds
the Rust code used to represent a Python Object and its methods.
Have you tried these steps and have a question, please chat with us on gitter.