dit
is a Python package for information theory.
Information theory is a powerful extension to probability and statistics, quantifying dependencies
among arbitrary random variables in a way that is consistent and comparable across systems and
scales. Information theory was originally developed to quantify how quickly and reliably information
could be transmitted across an arbitrary channel. The demands of modern, data-driven science have
been coopting and extending these quantities and methods into unknown, multivariate settings where
the interpretation and best practices are not known. For example, there are at least four reasonable
multivariate generalizations of the mutual information, none of which inherit all the
interpretations of the standard bivariate case. Which is best to use is context-dependent. dit
implements a vast range of multivariate information measures in an effort to allow information
practitioners to study how these various measures behave and interact in a variety of contexts. We
hope that having all these measures and techniques implemented in one place will allow the
development of robust techniques for the automated quantification of dependencies within a system
and concrete interpretation of what those dependencies mean.
If you use dit in your research, please cite it as:
@article{dit, Author = {James, R. G. and Ellison, C. J. and Crutchfield, J. P.}, Title = {{dit}: a {P}ython package for discrete information theory}, Journal = {The Journal of Open Source Software}, Volume = {3}, Number = {25}, Pages = {738}, Year = {2018}, Doi = {https://doi.org/10.21105/joss.00738} }
Dependencies |
---|
|
- colorama: colored column heads in PID indicating failure modes
- cython: faster sampling from distributions
- hypothesis: random sampling of distributions
- matplotlib, python-ternary: plotting of various information-theoretic expansions
- numdifftools: numerical evaluation of gradients and hessians during optimization
- pint: add units to informational values
- scikit-learn: faster nearest-neighbor lookups during entropy/mutual information estimation from samples
The easiest way to install is:
pip install dit
Alternatively, you can clone this repository, move into the newly created
dit
directory, and then install the package:
git clone https://github.com/dit/dit.git
cd dit
pip install .
Note
The cython extensions are currently not supported on windows. Please install
using the --nocython
option.
$ git clone https://github.com/dit/dit.git
$ cd dit
$ pip install -r requirements_testing.txt
$ py.test
BSD 3-Clause, see LICENSE.txt for details.
dit
implements the following information measures. Most of these are implemented in multivariate & conditional
generality, where such generalizations either exist in the literature or are relatively obvious --- for example,
though it is not in the literature, the multivariate conditional exact common information is implemented here.
Entropies
|
Mutual Informations
|
Divergences
|
Other Measures
|
||
Common Informations
|
Partial Information Decomposition
|
|
Secret Key Agreement Bounds
|
The basic usage of dit
corresponds to creating distributions, modifying them
if need be, and then computing properties of those distributions. First, we
import:
>>> import dit
Suppose we have a really thick coin, one so thick that there is a reasonable
chance of it landing on its edge. Here is how we might represent the coin in
dit
.
>>> d = dit.Distribution(['H', 'T', 'E'], [.4, .4, .2])
>>> print(d)
Class: Distribution
Alphabet: ('E', 'H', 'T') for all rvs
Base: linear
Outcome Class: str
Outcome Length: 1
RV Names: None
x p(x)
E 0.2
H 0.4
T 0.4
Calculate the probability of H
and also of the combination H or T
.
>>> d['H']
0.4
>>> d.event_probability(['H','T'])
0.8
Calculate the Shannon entropy and extropy of the joint distribution.
>>> dit.shannon.entropy(d)
1.5219280948873621
>>> dit.other.extropy(d)
1.1419011889093373
Create a distribution where Z = xor(X, Y)
.
>>> import dit.example_dists
>>> d = dit.example_dists.Xor()
>>> d.set_rv_names(['X', 'Y', 'Z'])
>>> print(d)
Class: Distribution
Alphabet: ('0', '1') for all rvs
Base: linear
Outcome Class: str
Outcome Length: 3
RV Names: ('X', 'Y', 'Z')
x p(x)
000 0.25
011 0.25
101 0.25
110 0.25
Calculate the Shannon mutual informations I[X:Z]
, I[Y:Z]
, and
I[X,Y:Z]
.
>>> dit.shannon.mutual_information(d, ['X'], ['Z'])
0.0
>>> dit.shannon.mutual_information(d, ['Y'], ['Z'])
0.0
>>> dit.shannon.mutual_information(d, ['X', 'Y'], ['Z'])
1.0
Calculate the marginal distribution P(X,Z)
.
Then print its probabilities as fractions, showing the mask.
>>> d2 = d.marginal(['X', 'Z'])
>>> print(d2.to_string(show_mask=True, exact=True))
Class: Distribution
Alphabet: ('0', '1') for all rvs
Base: linear
Outcome Class: str
Outcome Length: 2 (mask: 3)
RV Names: ('X', 'Z')
x p(x)
0*0 1/4
0*1 1/4
1*0 1/4
1*1 1/4
Convert the distribution probabilities to log (base 3.5) probabilities, and access its probability mass function.
>>> d2.set_base(3.5)
>>> d2.pmf
array([-1.10658951, -1.10658951, -1.10658951, -1.10658951])
Draw 5 random samples from this distribution.
>>> dit.math.prng.seed(1)
>>> d2.rand(5)
['01', '10', '00', '01', '00']
If you'd like to feature added to dit
, please file an issue. Or, better yet, open a pull request. Ideally, all code should be tested and documented, but pleast don't let this be a barrier to contributing. We'll work with you to ensure that all pull requests are in a mergable state.
If you'd like to get in contact about anything, you can reach us through our slack channel.