Rust is a systems programming language that runs blazingly fast, prevents segfaults, and guarantees thread safety.
Featuring
- zero-cost abstractions
- move semantics
- guaranteed memory safety
- threads without data races
- trait-based generics
- pattern matching
- type inference
- minimal runtime
- efficient C bindings
Taken from: from rust-lang.org
The better description of Rust I heard from Elias a member and the Rust Guru of the Rust Brazil Telegram Group
Rust is a language that allows you to build high level abstractions, but without giving up low level control - that is, control of how data is represented in memory, control of which threading model you want to use etc.
Rust is a language that can usually detect, during compilation, the worst parallelism and memory management errors (such as accessing data on different threads without synchronization, or using data after they have been deallocated), but gives you a hatch escape in the case you really know what you're doing.
Rust is a language that, because it has no runtime, can be used to integrate with any runtime; you can write a native extension in Rust that is called by a program node.js, or by a python program, or by a program in ruby, lua etc. and, on the other hand, you can script a program in Rust using these languages. -- "Elias Gabriel Amaral da Silva"
There are a bunch of Rust packages out there to help you extending Python with Rust.
I can mention Milksnake created by Armin Ronacher (the creator of Flask) and also PyO3 The Rust bindings for Python interpreter
See a complete reference list at the bottom.
For this post, I am going to use Rust Cpython, it's the only one I have tested, it is compatible with stable version of Rust and found it straightforward to use.
NOTE: PyO3 is a fork of rust-cpython, comes with many improvements, but works only with the nightly version of Rust, so I prefered to use the stable for this post, anyway the examples here must work also with PyO3.
Pros: It is really easy to write Rust functions and import from Python and as you will see by the benchmarks it worth in terms of performance.
Cons: The distribution of your project/lib/framework will demand the Rust module to be compiled on the target system because of variation of environment and architecture, there will be a compiling stage which you don't have when installing Pure Python libraries, you can make it easier using rust-setuptools or using the MilkSnake to embed binary data in Python Wheels.
Yes, Python is known for being "slow" in some cases and the good news is that this doesn't really matter depending on your project goals and priorities. For most projects this detail will not be very important.
However, you may face the rare case where a single function or module is taking too much time and is detected as the bottleneck of your project performance, often happens with string parsing and image processing.
Lets say you have a Python function which does some kind of string processing, take the following easy example of counting pairs of repeated chars
but have in mind that this example can be reproduced with other string processing
functions or any other generally slow process in Python.
# How many subsequent-repeated group of chars are in the given string?
abCCdeFFghiJJklmnopqRRstuVVxyZZ... {millions of chars here}
1 2 3 4 5 6
Python is pretty slow for doing large string
processing so you can use pytest-benchmark
to compare a Pure Python (with Iterator Zipping)
function versus a Regexp
implementation.
# Using a Python3.6 environment
$ pip3 install pytest pytest-benchmark
Then write a new Python program called doubles.py
import re
import string
import random
# Python ZIP version
def count_doubles(val):
total = 0
for c1, c2 in zip(val, val[1:]):
if c1 == c2:
total += 1
return total
# Python REGEXP version
double_re = re.compile(r'(?=(.)\1)')
def count_doubles_regex(val):
return len(double_re.findall(val))
# Benchmark it
# generate 1M of random letters to test it
val = ''.join(random.choice(string.ascii_letters) for i in range(1000000))
def test_pure_python(benchmark):
benchmark(count_doubles, val)
def test_regex(benchmark):
benchmark(count_doubles_regex, val)
Run pytest to compare:
$ pytest doubles.py
=============================================================================
platform linux -- Python 3.6.0, pytest-3.2.3, py-1.4.34, pluggy-0.4.
benchmark: 3.1.1 (defaults: timer=time.perf_counter disable_gc=False min_roun
rootdir: /Projects/rustpy, inifile:
plugins: benchmark-3.1.1
collected 2 items
doubles.py ..
-----------------------------------------------------------------------------
Name (time in ms) Min Max Mean
-----------------------------------------------------------------------------
test_regex 24.6824 (1.0) 32.3960 (1.0) 27.0167 (1.0)
test_pure_python 51.4964 (2.09) 62.5680 (1.93) 52.8334 (1.96)
-----------------------------------------------------------------------------
Lets take the Mean
for comparison:
- Regexp - 27.0167 <-- less is better
- Python Zip - 52.8334
crate is how we call Rust Packages.
Having rust installed (recommended way is https://www.rustup.rs/) Rust is also available on Fedora and RHEL rust-toolset
I used
rustc 1.21.0
In the same folder run:
cargo new pyext-myrustlib
It creates a new Rust project in that same folder called pyext-myrustlib
containing the Cargo.toml
(cargo is the Rust package manager) and also a src/lib.rs
(where we write our library implementation)
It will use the rust-cpython
crate as dependency and tell cargo to generate a dylib
to be imported from Python
[package]
name = "pyext-myrustlib"
version = "0.1.0"
authors = ["Bruno Rocha <rochacbruno@gmail.com>"]
[lib]
name = "myrustlib"
crate-type = ["dylib"]
[dependencies.cpython]
version = "0.1"
features = ["extension-module"]
What we need to do:
-
Import all macros from
cpython
crate -
Take
Python
andPyResult
types from cpython in to our lib scope -
Write the
count_doubles
function implementation inRust
, note that this is very similar to the Pure Python version except for:- It takes a
Python
as first argument, which is a reference to the Python Interpreter and allows Rust to use thePython GIL
- Receives a
&str
typedval
as reference - Returns a
PyResult
which is a type that allows the raise of Python exceptions - Returns a
PyResult
object inOk(total)
(Result is a enum type that represents either success (Ok) or failure (Err)) and as our function is expected to return aPyResult
the compiler will take care of wrapping ourOk
on that type. (note that our PyResult expects au64
as return value)
- It takes a
-
Using
py_module_initializer!
macro we register new attributes to the lib, including the__doc__
and also we add thecount_doubles
attribute referencing ourRust implementation of the function
- Attention to the names libmyrustlib, initlibmyrustlib and PyInit_myrustlib which is suffixed by our library name (defined in Cargo.toml)
- We also use the
try!
macro which is the equivalent to Python'stry.. except
- Return
Ok(())
- The()
is an empty result tuple, the equivalent ofNone
in Python
#[macro_use]
extern crate cpython;
use cpython::{Python, PyResult};
fn count_doubles(_py: Python, val: &str) -> PyResult<u64> {
let mut total = 0u64;
for (c1, c2) in val.chars().zip(val.chars().skip(1)) {
if c1 == c2 {
total += 1;
}
}
Ok(total)
}
py_module_initializer!(libmyrustlib, initlibmyrustlib, PyInit_myrustlib, |py, m | {
try!(m.add(py, "__doc__", "This module is implemented in Rust"));
try!(m.add(py, "count_doubles", py_fn!(py, count_doubles(val: &str))));
Ok(())
});
Now lets build it in cargo
$ cargo build --release
Finished release [optimized] target(s) in 0.0 secs
$ ls -la target/release/libmyrustlib*
target/release/libmyrustlib.d
target/release/libmyrustlib.so* <-- Our dylib is here
Now lets copy the generated .so
lib to the same folder where our doubles.py
is:
NOTE: on Fedora you must get a
.so
in other system you may get a.dylib
and you can rename it changing extension to.so
$ cd ..
$ ls
doubles.py pyext-myrustlib/
$ cp pyext-myrustlib/target/release/libmyrustlib.so myrustlib.so
$ ls
doubles.py myrustlib.so pyext-myrustlib/
Having the
myrustlib.so
in the same folder or added to your Python path allows it to be directly imported, transparently as it was a Python module.
Edit your doubles.py
now importing our Rust implemented
version and also adding a benchmark
for it.
import re
import string
import random
import myrustlib # <-- Import the Rust implemented module (myrustlib.so)
def count_doubles(val):
"""Count repeated pair of chars ins a string"""
total = 0
for c1, c2 in zip(val, val[1:]):
if c1 == c2:
total += 1
return total
double_re = re.compile(r'(?=(.)\1)')
def count_doubles_regex(val):
return len(double_re.findall(val))
val = ''.join(random.choice(string.ascii_letters) for i in range(1000000))
def test_pure_python(benchmark):
benchmark(count_doubles, val)
def test_regex(benchmark):
benchmark(count_doubles_regex, val)
def test_rust(benchmark): # <-- Benchmark the Rust version
benchmark(myrustlib.count_doubles, val)
$ pytest doubles.py
==============================================================================
platform linux -- Python 3.6.0, pytest-3.2.3, py-1.4.34, pluggy-0.4.
benchmark: 3.1.1 (defaults: timer=time.perf_counter disable_gc=False min_round
rootdir: /Projects/rustpy, inifile:
plugins: benchmark-3.1.1
collected 3 items
doubles_rust.py ...
-----------------------------------------------------------------------------
Name (time in ms) Min Max Mean
-----------------------------------------------------------------------------
test_rust 2.5555 (1.0) 2.9296 (1.0) 2.6085 (1.0)
test_regex 25.6049 (10.02) 27.2190 (9.29) 25.8876 (9.92)
test_pure_python 52.9428 (20.72) 56.3666 (19.24) 53.9732 (20.69)
-----------------------------------------------------------------------------
Lets take the Mean
for comparison:
- Rust - 2.6085 <-- less is better
- Regexp - 25.8876
- Python Zip - 53.9732
Rust implementation can be 10x faster than Python Regex and 21x faster than Pure Python Version.
Interesting that Regex version is only 2x faster than Pure Python :)
NOTE: That numbers makes sense only for this particular scenario, for other cases that comparison may be different.
After this article has been published I got some comments on r/python and also on r/rust
The contributions come as Pull Requests and you can send a new if you think the functions can be improved.
Thanks to: Josh Stone we got a better implementarion for Rust which iterates the string only once and also the Python equivalent.
Thanks to: Purple Pixie we got a Python implementation using itertools
, however this version is not performing any better, needs improvements.
fn count_doubles_once(_py: Python, val: &str) -> PyResult<u64> {
let mut total = 0u64;
let mut chars = val.chars();
if let Some(mut c1) = chars.next() {
for c2 in chars {
if c1 == c2 {
total += 1;
}
c1 = c2;
}
}
Ok(total)
}
def count_doubles_once(val):
total = 0
chars = iter(val)
c1 = next(chars)
for c2 in chars:
if c1 == c2:
total += 1
c1 = c2
return total
import itertools
def count_doubles_itertools(val):
c1s, c2s = itertools.tee(val)
next(c2s, None)
total = 0
for c1, c2 in zip(c1s, c2s):
if c1 == c2:
total += 1
return total
Ok, that is not the purpose of this post, this post was never about comparing Rust
X other language
, this post was specifically about
how to use Rust to extend and speed up Python and by doing that it means you have a good reason to choose Rust instead of other language
or by its ecosystem or by its safety and tooling or just to follow the hype, or simply because you like Rust
doesn't matter the reason, this post is here to show how to use it with Python.
I (personally) may say that Rust is more future proof
as it is new and there are lots of improvements to come, also because of its ecosystem, tooling and community
and also because I feel comfortable with Rust syntax, I really like it!
So, as expected people started complaining about the use of other languages and it becomes a sort of benchmark, and I think it is cool!
So as part of my request for improvements some people on Hacker News also sent ideas, martinxyz sent an implementaion using C and SWIG that performed very well.
C Code (swig boilerplate ommited)
uint64_t count_byte_doubles(char * str) {
uint64_t count = 0;
while (str[0] && str[1]) {
if (str[0] == str[1]) count++;
str++;
}
return count;
}
And our fellow Red Hatter Josh Stone improved the Rust implementation again by replacing chars
with bytes
so it is a fair competition with C
as
C is comparing bytes instead of unicode chars.
fn count_doubles_once_bytes(_py: Python, val: &str) -> PyResult<u64> {
let mut total = 0u64;
let mut chars = val.bytes();
if let Some(mut c1) = chars.next() {
for c2 in chars {
if c1 == c2 {
total += 1;
}
c1 = c2;
}
}
Ok(total)
}
There are also ideas to compare Python list comprehension
and numpy
so I included here
Numpy:
import numpy as np
def count_double_numpy(val):
ng=np.fromstring(val,dtype=np.byte)
return np.sum(ng[:-1]==ng[1:])
List comprehension
def count_doubles_comprehension(val):
return sum(1 for c1, c2 in zip(val, val[1:]) if c1 == c2)
The complete test case is on repository test_all.py
file.
-------------------------------------------------------------------------------------------------
Name (time in us) Min Max Mean
-------------------------------------------------------------------------------------------------
test_rust_bytes_once 476.7920 (1.0) 830.5610 (1.0) 486.6116 (1.0)
test_c_swig_bytes_once 795.3460 (1.67) 1,504.3380 (1.81) 827.3898 (1.70)
test_rust_once 985.9520 (2.07) 1,483.8120 (1.79) 1,017.4251 (2.09)
test_numpy 1,001.3880 (2.10) 2,461.1200 (2.96) 1,274.8132 (2.62)
test_rust 2,555.0810 (5.36) 3,066.0430 (3.69) 2,609.7403 (5.36)
test_regex 24,787.0670 (51.99) 26,513.1520 (31.92) 25,333.8143 (52.06)
test_pure_python_once 36,447.0790 (76.44) 48,596.5340 (58.51) 38,074.5863 (78.24)
test_python_comprehension 49,166.0560 (103.12) 50,832.1220 (61.20) 49,699.2122 (102.13)
test_pure_python 49,586.3750 (104.00) 50,697.3780 (61.04) 50,148.6596 (103.06)
test_itertools 56,762.8920 (119.05) 69,660.0200 (83.87) 58,402.9442 (120.02)
-------------------------------------------------------------------------------------------------
- The
new Rust implementation comparing bytes
is 2x better than the old comparing unicodechars
- The
Rust
version is still better than theC
using SWIG Rust
comparingunicode chars
is still better thannumpy
- However
Numpy
is better than thefirst Rust implementation
which had the problem of double iteration over the unicode chars - Using a
list comprehension
does not make significative difference than usingpure Python
NOTE: If you want to propose changes or improvements send a PR here: https://github.com/rochacbruno/rust-python-example/
I received more contributions as Pull Requests one of then was by Jason Knight to improve Rust
using
RUSTFLAGS="-C target-cpu=native" cargo build --release
And for those who were curious about a comparison with numba
so Shyba implemented it and it is available in the numba branch https://github.com/rochacbruno/rust-python-example/tree/numba.
from numba import jit
@jit(nopython=True, cache=True)
def count_doubles_once_numba(val):
total = 0
chars = iter(val)
c1 = next(chars)
for c2 in chars:
if c1 == c2:
total += 1
c1 = c2
return total
Look the new results with numba at the top, pretty close to Rust
----------------------------------------------------------------------------------------------------
Name (time in us) Min Max Mean
----------------------------------------------------------------------------------------------------
test_pure_python_once_numba 292.0990 (1.0) 317.7590 (1.0) 296.7477 (1.0)
test_numpy_numba 326.2470 (1.12) 526.1350 (1.66) 338.1704 (1.14)
test_rust_bytes_once 336.0620 (1.15) 1,053.0090 (3.31) 342.5122 (1.15)
test_c_swig_bytes_once 375.6310 (1.29) 1,389.9070 (4.37) 388.9181 (1.31)
test_rust_once 986.0360 (3.38) 2,498.5850 (7.86) 1,006.5819 (3.39)
test_numpy 1,137.1750 (3.89) 2,000.5430 (6.30) 1,167.2551 (3.93)
test_rust 2,555.1400 (8.75) 3,645.3900 (11.47) 2,592.0419 (8.73)
test_regex 22,597.1750 (77.36) 25,027.2820 (78.76) 22,851.8456 (77.01)
test_pure_python_once 32,418.8830 (110.99) 34,818.0800 (109.57) 32,756.3244 (110.38)
test_pure_python 43,823.5140 (150.03) 45,961.8460 (144.64) 44,367.1028 (149.51)
test_python_comprehension 46,360.1640 (158.71) 50,578.1740 (159.17) 46,986.8058 (158.34)
test_itertools 49,080.8640 (168.03) 51,016.5230 (160.55) 49,405.2562 (166.49)
----------------------------------------------------------------------------------------------------
And there is also a Cython implementation by MIke Fletcher in the branch cython
https://github.com/rochacbruno/rust-python-example/tree/cython
with the results:
----------------------------------------------------------------------------------------------------
Name (time in us) Min Max Mean
----------------------------------------------------------------------------------------------------
test_rust_bytes_once 336.7590 (1.0) 806.2610 (1.0) 346.5317 (1.0)
test_cython 756.1610 (2.25) 2,343.3680 (2.91) 785.6455 (2.27)
test_c_swig_bytes_once 802.4250 (2.38) 1,632.4290 (2.02) 840.8603 (2.43)
----------------------------------------------------------------------------------------------------
Back to the purpose of this post How to Speed Up your Python with Rust we started with:
- Pure Python function taking **102 **.
- Improved with Numpy (which is implemented in C) to take 3.
- Ended with Rust taking 1 (just like numba version).
In this example Rust performed 100x faster than our Pure Python.
Rust
will not magically save you, you must know the language to be able to implement the clever solution and once implemented in the right it worth as much as C in terms of performance and also comes with amazing tooling, ecosystem, community and safety bonuses.
Rust
may not be yet the general purpose language
of choice by its level of complexity and may not be the better choice yet to write common simple applications
such as web
sites and test automation
scripts.
However, for specific parts
of the project where Python is known to be the bottleneck and your natural choice would be implementing a C/C++
extension, writing this extension in Rust seems easy and better to maintain.
There are still many improvements to come in Rust and lots of others crates to offer Python <--> Rust
integration. Even if your are not including the language in your tool belt right now, it is really worth to keep an eye open to the future!
The examples on this publication are inspired by Extending Python with Rust
talk by Samuel Cormier-Iijima in Pycon Canada.
video here: https://www.youtube.com/watch?v=-ylbuEzkG4M
And also by My Python is a little Rust-y
by Dan Callahan in Pycon Montreal.
video here: https://www.youtube.com/watch?v=3CwJ0MH-4MA
Other references:
- https://github.com/mitsuhiko/snaek
- https://github.com/PyO3/pyo3
- https://pypi.python.org/pypi/setuptools-rust
- https://github.com/mckaymatt/cookiecutter-pypackage-rust-cross-platform-publish
- http://jakegoulding.com/rust-ffi-omnibus/
- https://github.com/urschrei/polylabel-rs/blob/master/src/ffi.rs
- https://bheisler.github.io/post/calling-rust-in-python/
- https://github.com/saethlin/rust-lather
Join Community:
Join Rust community, you can find group links in https://www.rust-lang.org/en-US/community.html
If you speak Portuguese I recommend you to join https://t.me/rustlangbr and there is also the http://bit.ly/canalrustbr on Youtube.
Bruno Rocha
- Senior Quality Enginner at Red Hat
- Teaching Python at CursoDePython.com.br
- Fellow Member of Python Software Foundation
More info: http://about.me/rochacbruno and http://brunorocha.org