The PyUNLocBoX is a Python package which uses proximal splitting methods to solve non-differentiable convex optimization problems. The documentation is available on Read the Docs and development takes place on GitHub. A (mostly unmaintained) Matlab version exists.
The package is designed to be easy to use while allowing any advanced tasks. It is not meant to be a black-box optimization tool. You'll have to carefully design your solver. In exchange you'll get full control of what the package does for you, without the pain of rewriting the proximity operators and the solvers and with the added benefit of tested algorithms. With this package, you can focus on your problem and the best way to solve it rather that the details of the algorithms.
The following solvers are included:
- Gradient descent
- Forward-backward proximal splitting (FISTA and ISTA)
- Generalized forward-backward proximal splitting
- Douglas-Rachford proximal splitting
- Monotone+Lipschitz forward-backward-forward primal-dual
- Projection-based primal-dual
The following acceleration schemes are included:
- Backtracking acceleration based on a quadratic approximation of the objective
- FISTA acceleration for forward-backward solvers
- FISTA acceleration with backtracking for forward-backward solvers
- Regularized nonlinear acceleration (RNA) for gradient descent
To compose your objective, the following functions are included:
- L1-norm (eval, prox)
- L2-norm (eval, prox, grad)
- Nuclear-norm (eval, prox)
- TV-norm (eval, prox)
- Projection on the positive octant (eval, prox)
- Projection on the L2-ball (eval, prox)
- Structured sparsity (eval, prox)
Alternatively, you can easily define a custom function by implementing an evaluation method and a proximal operator or gradient method:
>>> from pyunlocbox import functions
>>> class myfunc(functions.func):
... def _eval(self, x):
... return 0 # Function evaluated at x.
... def _grad(self, x):
... return x # Gradient evaluated at x, if available.
... def _prox(self, x, T):
... return x # Proximal operator evaluated at x, if available.
Likewise, custom solvers are defined by inheriting from solvers.solver
and implementing _pre
, _algo
, and _post
.
Custom acceleration schemes are defined by inheriting from
acceleration.accel
and implementing _pre
, _update_step
,
_update_sol
, and _post
.
Following is a typical usage example that solves an optimization problem composed by the sum of two convex functions. The functions and solver objects are first instantiated with the desired parameters. The problem is then solved by a call to the solving function.
>>> from pyunlocbox import functions, solvers
>>> f1 = functions.norm_l2(y=[4, 5, 6, 7])
>>> f2 = functions.dummy()
>>> solver = solvers.forward_backward()
>>> ret = solvers.solve([f1, f2], [0., 0, 0, 0], solver, atol=1e-5)
Solution found after 9 iterations:
objective function f(sol) = 6.714385e-08
stopping criterion: ATOL
>>> ret['sol']
array([3.99990766, 4.99988458, 5.99986149, 6.99983841])
You can try it online, look at the tutorials to learn how to use it, or look at the reference guide for an exhaustive documentation of the API. Enjoy!
The PyUNLocBoX is available on PyPI:
$ pip install pyunlocbox
The PyUNLocBoX is available on conda-forge:
$ conda install -c conda-forge pyunlocbox
See the guidelines for contributing in CONTRIBUTING.rst
.
Other proximal based algorithms and operators can be found in:
Furthermore, many proximal operators are availlable in the proxop python library.
The PyUNLocBoX was started in 2014 as an academic open-source project for research purpose at the EPFL LTS2 laboratory.
It is released under the terms of the BSD 3-Clause license.
If you are using the library for your research, for the sake of reproducibility, please cite the version you used as indexed by Zenodo. Or cite the generic concept as:
@misc{pyunlocbox, title = {PyUNLocBoX: Optimization by Proximal Splitting}, author = {Defferrard, Micha\"el and Pena, Rodrigo and Perraudin, Nathana\"el}, doi = {10.5281/zenodo.1199081}, url = {https://github.com/epfl-lts2/pyunlocbox/}, }