adaptive
Adaptive: parallel active learning of mathematical functions.
adaptive is an open-source Python library designed to
make adaptive parallel function evaluation simple. With adaptive you
just supply a function with its bounds, and it will be evaluated at the
“best” points in parameter space. With just a few lines of code you can
evaluate functions on a computing cluster, live-plot the data as it
returns, and fine-tune the adaptive sampling algorithm.
Run the adaptive example notebook live on
Binder
to see examples of how to use adaptive or visit the
tutorial on Read the Docs.
WARNING: adaptive is still in a beta development stage
Implemented algorithms
The core concept in adaptive is that of a learner. A learner
samples a function at the best places in its parameter space to get
maximum “information” about the function. As it evaluates the function
at more and more points in the parameter space, it gets a better idea of
where the best places are to sample next.
Of course, what qualifies as the “best places” will depend on your
application domain! adaptive makes some reasonable default choices,
but the details of the adaptive sampling are completely customizable.
The following learners are implemented:
Learner1D, for 1D functionsf: ℝ → ℝ^N,Learner2D, for 2D functionsf: ℝ^2 → ℝ^N,LearnerND, for ND functionsf: ℝ^N → ℝ^M,AverageLearner, For stochastic functions where you want to average the result over many evaluations,IntegratorLearner, for when you want to intergrate a 1D functionf: ℝ → ℝ,BalancingLearner, for when you want to run several learners at once, selecting the “best” one each time you get more points.
In addition to the learners, adaptive also provides primitives for
running the sampling across several cores and even several machines,
with built-in support for
concurrent.futures,
mpi4py,
loky,
ipyparallel and
distributed.
Examples
Adaptively learning a 1D function (the gif below) and live-plotting the process in a Jupyter notebook is as easy as
from adaptive import notebook_extension, Runner, Learner1D
notebook_extension()
def peak(x, a=0.01):
return x + a**2 / (a**2 + x**2)
learner = Learner1D(peak, bounds=(-1, 1))
runner = Runner(learner, goal=lambda l: l.loss() < 0.01)
runner.live_info()
runner.live_plot()
Installation
adaptive works with Python 3.6 and higher on Linux, Windows, or Mac,
and provides optional extensions for working with the Jupyter/IPython
Notebook.
The recommended way to install adaptive is using conda:
conda install -c conda-forge adaptiveadaptive is also available on PyPI:
pip install adaptive[notebook]The [notebook] above will also install the optional dependencies for
running adaptive inside a Jupyter notebook.
To use Adaptive in Jupyterlab, you need to install the following labextensions.
jupyter labextension install @jupyter-widgets/jupyterlab-manager
jupyter labextension install @pyviz/jupyterlab_pyvizDevelopment
Clone the repository and run setup.py develop to add a link to the
cloned repo into your Python path:
git clone git@github.com:python-adaptive/adaptive.git
cd adaptive
python3 setup.py developWe highly recommend using a Conda environment or a virtualenv to manage
the versions of your installed packages while working on adaptive.
In order to not pollute the history with the output of the notebooks, please setup the git filter by executing
python ipynb_filter.pyin the repository.
We implement several other checks in order to maintain a consistent code style. We do this using pre-commit, execute
pre-commit installin the repository.
Citing
If you used Adaptive in a scientific work, please cite it as follows.
@misc{Nijholt2019,
doi = {10.5281/zenodo.1182437},
author = {Bas Nijholt and Joseph Weston and Jorn Hoofwijk and Anton Akhmerov},
title = {\textit{Adaptive}: parallel active learning of mathematical functions},
publisher = {Zenodo},
year = {2019}
}Credits
We would like to give credits to the following people:
- Pedro Gonnet for his implementation of CQUAD, “Algorithm 4” as described in “Increasing the Reliability of Adaptive Quadrature Using Explicit Interpolants”, P. Gonnet, ACM Transactions on Mathematical Software, 37 (3), art. no. 26, 2010.
- Pauli Virtanen for his
AdaptiveTriSamplingscript (no longer available online since SciPy Central went down) which served as inspiration for the ~adaptive.Learner2D.
For general discussion, we have a Gitter chat channel. If you find any bugs or have any feature suggestions please file a GitHub issue or submit a pull request.
