A performant NumPy extension for Galois fields and their applications
Project description
The galois library is a Python 3 package that extends NumPy arrays to operate over finite fields.
The user creates a Galois field array class
using GF = galois.GF(p**m). The Galois field array class GF is a subclass of np.ndarray and its constructor x = GF(array_like)
mimics the call signature of np.array(). The Galois field array
x is operated on like any other NumPy array except all arithmetic is performed in GF(p^m), not R.
Internally, the finite field arithmetic is implemented by replacing NumPy ufuncs. The new ufuncs are written in pure Python and just-in-time compiled with Numba. The ufuncs can be configured to use either lookup tables (for speed) or explicit calculation (for memory savings).
| :warning: Disclaimer |
|---|
| The algorithms implemented in the NumPy ufuncs are not constant-time, but were instead designed for performance. As such, the library could be vulnerable to a side-channel timing attack. This library is not intended for production security, but instead for research & development, reverse engineering, cryptanalysis, experimentation, and general education. |
Features
- Supports all Galois fields
GF(p^m), even arbitrarily-large fields! - Faster than native NumPy!
GF(x) * GF(y)is faster than(x * y) % pforGF(p). - Seamless integration with NumPy -- normal NumPy functions work on Galois field arrays.
- Linear algebra over finite fields using normal
np.linalgfunctions. - Linear transforms over finite fields, such as the NTT with
galois.ntt()andgalois.intt(). - Functions to generate irreducible, primitive, and Conway polynomials.
- Univariate polynomials over finite fields with
galois.Poly. - Forward error correction codes with
galois.BCHandgalois.ReedSolomon. - Fibonacci and Galois linear-feedback shift registers over any finite field with
galois.FLFSRandgalois.GLFSR. - Various number theoretic functions.
- Integer factorization and accompanying algorithms.
- Prime number generation and primality testing.
Roadmap
- DFT over all finite fields
- Elliptic curves over finite fields
- Galois ring arrays
- GPU support
Documentation
The documentation for galois is located at https://galois.readthedocs.io/en/latest/.
Getting Started
The Getting Started guide is intended to assist the user in installing the library, creating two example arrays, and performing basic array arithmetic. See Basic Usage for more detailed discussions and examples.
Install the package
The latest version of galois can be installed from PyPI using pip.
$ python3 -m pip install galois
Import the galois package in Python.
In [1]: import galois
In [2]: galois.__version__
Out[2]: '0.0.26'
Create a Galois field array class
Next, create a Galois field array class
for the specific finite field you'd like to work in. This is created using the galois.GF() class factory. In this example, we are
working in GF(2^8).
In [3]: GF = galois.GF(2**8)
In [4]: GF
Out[4]: <class 'numpy.ndarray over GF(2^8)'>
In [5]: print(GF)
Galois Field:
name: GF(2^8)
characteristic: 2
degree: 8
order: 256
irreducible_poly: x^8 + x^4 + x^3 + x^2 + 1
is_primitive_poly: True
primitive_element: x
The Galois field array class GF is a subclass of np.ndarray that performs all arithmetic in the Galois field
GF(2^8), not in R.
In [6]: issubclass(GF, np.ndarray)
Out[6]: True
See Galois Field Classes for more details.
Create two Galois field arrays
Next, create a new Galois field array
x by passing an array-like object to the
Galois field array class GF.
In [7]: x = GF([45, 36, 7, 74, 135]); x
Out[7]: GF([ 45, 36, 7, 74, 135], order=2^8)
Create a second Galois field array y by converting an existing NumPy array (without copying it) by invoking .view(). When finished
working in the finite field, view it back as a NumPy array with .view(np.ndarray).
# y represents an array created elsewhere in the code
In [8]: y = np.array([103, 146, 186, 83, 112], dtype=int); y
Out[8]: array([103, 146, 186, 83, 112])
In [9]: y = y.view(GF); y
Out[9]: GF([103, 146, 186, 83, 112], order=2^8)
The Galois field array x is an instance of the Galois field array class GF (and also an instance of np.ndarray).
In [10]: isinstance(x, GF)
Out[10]: True
In [11]: isinstance(x, np.ndarray)
Out[11]: True
See Array Creation for more details.
Change the element representation
The display representation of finite field elements can be set to either the integer ("int"), polynomial ("poly"),
or power ("power") representation. The default representation is the integer representation since that is natural when
working with integer NumPy arrays.
Set the display mode by passing the display keyword argument to galois.GF() or by calling the galois.FieldClass.display() method.
Choose whichever element representation is most convenient for you.
# The default representation is the integer representation
In [12]: x
Out[12]: GF([ 45, 36, 7, 74, 135], order=2^8)
In [13]: GF.display("poly"); x
Out[13]:
GF([α^5 + α^3 + α^2 + 1, α^5 + α^2, α^2 + α + 1,
α^6 + α^3 + α, α^7 + α^2 + α + 1], order=2^8)
In [14]: GF.display("power"); x
Out[14]: GF([ α^18, α^225, α^198, α^37, α^13], order=2^8)
# Reset to the integer representation
In [15]: GF.display("int");
See Field Element Representation for more details.
Perform array arithmetic
Once you have two Galois field arrays, nearly any arithmetic operation can be performed using normal NumPy arithmetic. The traditional NumPy broadcasting rules apply.
Standard element-wise array arithmetic -- like addition, subtraction, multiplication, and division -- are easily preformed.
In [16]: x + y
Out[16]: GF([ 74, 182, 189, 25, 247], order=2^8)
In [17]: x - y
Out[17]: GF([ 74, 182, 189, 25, 247], order=2^8)
In [18]: x * y
Out[18]: GF([133, 197, 1, 125, 239], order=2^8)
In [19]: x / y
Out[19]: GF([ 99, 101, 21, 177, 97], order=2^8)
More complicated arithmetic, like square root and logarithm base alpha, are also supported.
In [20]: np.sqrt(x)
Out[20]: GF([ 58, 44, 134, 154, 218], order=2^8)
In [21]: np.log(x)
Out[21]: array([ 18, 225, 198, 37, 13])
See Array Arithmetic for more details.
Acknowledgements
The galois library is an extension of, and completely dependent on, NumPy. It also heavily
relies on Numba and the LLVM just-in-time compiler for optimizing performance
of the finite field arithmetic.
Frank Luebeck's compilation of Conway polynomials and Wolfram's compilation of primitive polynomials are used for efficient polynomial lookup, when possible.
Sage is used extensively for generating test vectors for finite field arithmetic and polynomial arithmetic. SymPy is used to generate some test vectors. Octave is used to generate test vectors for forward error correction codes.
This library would not be possible without all of the other libraries mentioned. Thank you to all their developers!
Citation
If this library was useful to you in your research, please cite us. Following the GitHub citation standards, here is the recommended citation.
BibTeX
@software{Hostetter_Galois_2020,
title = {{Galois: A performant NumPy extension for Galois fields}},
author = {Hostetter, Matt},
month = {11},
year = {2020},
url = {https://github.com/mhostetter/galois},
}
APA
Hostetter, M. (2020). Galois: A performant NumPy extension for Galois fields [Computer software]. https://github.com/mhostetter/galois
Release history Release notifications | RSS feed
Download files
Download the file for your platform. If you're not sure which to choose, learn more about installing packages.
