dragonfly/dragonfly
An open source python library for scalable Bayesian optimisation.
repo name | dragonfly/dragonfly |
repo link | https://github.com/dragonfly/dragonfly |
homepage | |
language | Python |
size (curr.) | 1079 kB |
stars (curr.) | 462 |
created | 2018-04-20 |
license | MIT License |
Dragonfly is an open source python library for scalable Bayesian optimisation.
Bayesian optimisation is used for optimising black-box functions whose evaluations are usually expensive. Beyond vanilla optimisation techniques, Dragonfly provides an array of tools to scale up Bayesian optimisation to expensive large scale problems. These include features/functionality that are especially suited for high dimensional optimisation (optimising for a large number of variables), parallel evaluations in synchronous or asynchronous settings (conducting multiple evaluations in parallel), multi-fidelity optimisation (using cheap approximations to speed up the optimisation process), and multi-objective optimisation (optimising multiple functions simultaneously).
Dragonfly is compatible with Python2 (>= 2.7) and Python3 (>= 3.5) and has been tested on Linux, macOS, and Windows platforms. For documentation, installation, and a getting started guide, see our readthedocs page. For more details, see our paper.
Installation
See here for detailed instructions on installing Dragonfly and its dependencies.
Quick Installation:
If you have done this kind of thing before, you should be able to install
Dragonfly via pip
.
$ sudo apt-get install python-dev python3-dev gfortran # On Ubuntu/Debian
$ pip install numpy
$ pip install dragonfly-opt -v
Testing the Installation: You can import Dragonfly in python to test if it was installed properly. If you have installed via source, make sure that you move to a different directory to avoid naming conflicts.
$ python
>>> from dragonfly import minimise_function
>>> # The first argument below is the function, the second is the domain, and the third is the budget.
>>> min_val, min_pt, history = minimise_function(lambda x: x ** 4 - x**2 + 0.1 * x, [[-10, 10]], 10);
...
>>> min_val, min_pt
(-0.32122746026750953, array([-0.7129672]))
Due to stochasticity in the algorithms, the above values for min_val
, min_pt
may be
different. If you run it for longer (e.g.
min_val, min_pt, history = minimise_function(lambda x: x ** 4 - x**2 + 0.1 * x, [[-10, 10]], 100)
),
you should get more consistent values for the minimum.
If the installation fails or if there are warning messages, see detailed instructions here.
Quick Start
Dragonfly can be
used directly in the command line by calling
dragonfly-script.py
or be imported in python code via the maximise_function
function in the main library
or in ask-tell mode.
To help get started, we have provided some examples in the
examples
directory.
See our readthedocs getting started pages
(command line,
Python,
Ask-Tell)
for examples and use cases.
Command line: Below is an example usage in the command line.
$ cd examples
$ dragonfly-script.py --config synthetic/branin/config.json --options options_files/options_example.txt
In Python code:
The main APIs for Dragonfly are defined in
dragonfly/apis
.
For their definitions and arguments, see
dragonfly/apis/opt.py
and
dragonfly/apis/moo.py
.
You can import the main API in python code via,
from dragonfly import minimise_function, maximise_function
func = lambda x: x ** 4 - x**2 + 0.1 * x
domain = [[-10, 10]]
max_capital = 100
min_val, min_pt, history = minimise_function(func, domain, max_capital)
print(min_val, min_pt)
max_val, max_pt, history = maximise_function(lambda x: -func(x), domain, max_capital)
print(max_val, max_pt)
Here, func
is the function to be maximised,
domain
is the domain over which func
is to be optimised,
and max_capital
is the capital available for optimisation.
The domain can be specified via a JSON file or in code.
See
here,
here,
here,
here,
here,
here,
here,
here,
here,
here,
and
here
for more detailed examples.
In Ask-Tell Mode: Ask-tell mode provides you more control over your experiments where you can supply past results to our API in order to obtain a recommendation. See the following example for more details.
For a comprehensive list of uses cases, including multi-objective optimisation, multi-fidelity optimisation, neural architecture search, and other optimisation methods (besides Bayesian optimisation), see our readthe docs pages (command line, Python, Ask-Tell)).
Contributors
Kirthevasan Kandasamy: github,
webpage
Karun Raju Vysyaraju: github,
linkedin
Anthony Yu: github,
linkedin
Willie Neiswanger: github,
webpage
Biswajit Paria: github,
webpage
Chris Collins: github,
webpage
Acknowledgements
Research and development of the methods in this package were funded by DOE grant DESC0011114, NSF grant IIS1563887, the DARPA D3M program, and AFRL.
Citation
If you use any part of this code in your work, please cite this manuscript.
@article{kandasamy2019tuning,
title={{Tuning Hyperparameters without Grad Students: Scalable and Robust Bayesian
Optimisation with Dragonfly}},
author={Kandasamy, Kirthevasan and Vysyaraju, Karun Raju and Neiswanger,
Willie and Paria, Biswajit and Collins, Christopher R. and Schneider, Jeff and
Poczos, Barnabas and Xing, Eric P},
journal={arXiv preprint arXiv:1903.06694},
year={2019}
}
License
This software is released under the MIT license. For more details, please refer LICENSE.txt.
For questions, please email kandasamy@cs.cmu.edu.
“Copyright 2018-2019 Kirthevasan Kandasamy”