Bristol Fashion Circuit Library (BFCL) for working with circuit definitions represented using the Bristol Fashion.
This library includes data structures and associated methods for working with logical circuits typically used in secure multi-party computation (MPC) applications. The data structures follow in their organization the Bristol Fashion format, extrapolating and generalizing where necessary in order to support a wider variety of features and operations.
The package is available on PyPI:
python -m pip install bfcl
The library can be imported in the usual way:
import bfcl from bfcl import *
This library makes it possible to parse a circuit definition that conforms to the Bristol Fashion syntax:
>>> ss = ['7 36', '2 4 4', '1 1'] >>> ss += ['2 1 0 1 15 AND', '2 1 2 3 16 AND'] >>> ss += ['2 1 15 16 8 AND', '2 1 4 5 22 AND'] >>> ss += ['2 1 6 7 23 AND', '2 1 22 23 9 AND'] >>> ss += ['2 1 8 9 35 AND'] >>> c = bfc('\n'.join(ss))
A string representation that conforms to the Bristol Fashion syntax can be emitted:
>>> for line in c.emit().split('\n'): ... print(line) ... 7 36 2 4 4 1 1 2 1 0 1 15 AND 2 1 2 3 16 AND 2 1 15 16 8 AND 2 1 4 5 22 AND 2 1 6 7 23 AND 2 1 22 23 9 AND 2 1 8 9 35 AND
It is possible to evaluate a circuit on a sequence of input bit vectors. The circuit defined in the example above takes two 4-bit input vectors and returns the logical conjunction of all the bits. In the example below, it is evaluated on a few pairs of input bit vectors. The result is organized into a list of output bit vectors according to the original circuit definition (in the example below, the result consists of only a single output bit vector that contains a single bit):
>>> c.evaluate([[1, 0, 1, 1], [1, 1, 1, 0]]) [[0]] >>> c.evaluate([[1, 1, 1, 1], [1, 1, 1, 1]]) [[1]]
As an alternative to using a string representation to define a circuit, it is also possible to construct a circuit using the circuit library. In the example below, the constructor for the circuit
class found in the bfcl library is applied to an object built using the classes and methods exported by the circuit library (note the use of a synonym to avoid a conflict with the circuit
class defined in the bfcl library):
>>> import circuit as circuit_ >>> c = circuit_.circuit() >>> g0 = c.gate(circuit_.op.id_, is_input=True) >>> g1 = c.gate(circuit_.op.id_, is_input=True) >>> g2 = c.gate(circuit_.op.and_, [g0, g1]) >>> g3 = c.gate(circuit_.op.id_, [g2], is_output=True) >>> bfc(c).emit().split('\n') ['2 4', '1 2', '1 1', '2 1 0 1 2 AND', '1 1 2 3 LID']
The documentation can be generated automatically from the source files using Sphinx:
cd docs python -m pip install -r requirements.txt sphinx-apidoc -f -E --templatedir=_templates -o _source .. ../setup.py && make html
All unit tests are executed and their coverage is measured when using pytest (see setup.cfg
for configuration details):
python -m pip install pytest pytest-cov python -m pytest
Alternatively, all unit tests are included in the module itself and can be executed using doctest:
python bfcl/bfcl.py -v
Style conventions are enforced using Pylint:
python -m pip install pylint python -m pylint bfcl
In order to contribute to the source code, open an issue or submit a pull request on the GitHub page for this library.
Beginning with version 0.2.0, the version number format for this library and the changes to the library associated with version number increments conform with Semantic Versioning 2.0.0.
This library can be published as a package on PyPI by a package maintainer. Install the wheel package, remove any old build/distribution files, and package the source into a distribution archive:
python -m pip install wheel rm -rf dist *.egg-info python setup.py sdist bdist_wheel
Next, install the twine package and upload the package distribution archive to PyPI:
python -m pip install twine python -m twine upload dist/*