Hyperopt is a Python library for serial and parallel optimization over awkward search spaces, which may include real-valued, discrete, and conditional dimensions.
Install hyperopt from PyPI
pip install hyperopt
to run your first example
# define an objective function
def objective(args):
case, val = args
if case == 'case 1':
return val
else:
return val ** 2
# define a search space
from hyperopt import hp
space = hp.choice('a',
[
('case 1', 1 + hp.lognormal('c1', 0, 1)),
('case 2', hp.uniform('c2', -10, 10))
])
# minimize the objective over the space
from hyperopt import fmin, tpe, space_eval
best = fmin(objective, space, algo=tpe.suggest, max_evals=100)
print(best)
# -> {'a': 1, 'c2': 0.01420615366247227}
print(space_eval(space, best))
# -> ('case 2', 0.01420615366247227}
If you're a developer and wish to contribute, please follow these steps.
Setup (based on this)
-
Create an account on GitHub if you do not already have one.
-
Fork the project repository: click on the ‘Fork’ button near the top of the page. This creates a copy of the code under your account on the GitHub user account. For more details on how to fork a repository see this guide.
-
Clone your fork of the hyperopt repo from your GitHub account to your local disk:
git clone https://github.com/<github username>/hyperopt.git cd hyperopt
-
Create environment with:
$ python3 -m venv my_env
or$ python -m venv my_env
or with conda:
$ conda create -n my_env python=3
-
Activate the environment:
$ source my_env/bin/activate
or with conda:
$ conda activate my_env
-
Install dependencies for extras (you'll need these to run pytest): Linux/UNIX:
$ pip install -e '.[MongoTrials, SparkTrials, ATPE, dev]'
or Windows:
pip install -e .[MongoTrials] pip install -e .[SparkTrials] pip install -e .[ATPE] pip install -e .[dev]
-
Add the upstream remote. This saves a reference to the main hyperopt repository, which you can use to keep your repository synchronized with the latest changes:
$ git remote add upstream https://github.com/hyperopt/hyperopt.git
You should now have a working installation of hyperopt, and your git repository properly configured. The next steps now describe the process of modifying code and submitting a PR:
-
Synchronize your master branch with the upstream master branch:
git checkout master git pull upstream master
-
Create a feature branch to hold your development changes:
$ git checkout -b my_feature
and start making changes. Always use a feature branch. It’s good practice to never work on the master branch!
-
We recommend to use Black to format your code before submitting a PR which is installed automatically in step 6.
-
Then, once you commit ensure that git hooks are activated (Pycharm for example has the option to omit them). This can be done using pre-commit, which is installed automatically in step 6, as follows:
pre-commit install
This will run black automatically when you commit on all files you modified, failing if there are any files requiring to be blacked. In case black does not run execute the following:
black {source_file_or_directory}
-
Develop the feature on your feature branch on your computer, using Git to do the version control. When you’re done editing, add changed files using git add and then git commit:
git add modified_files git commit -m "my first hyperopt commit"
-
The tests for this project use PyTest and can be run by calling
pytest
. -
Record your changes in Git, then push the changes to your GitHub account with:
git push -u origin my_feature
Note that dev dependencies require python 3.6+.
Currently three algorithms are implemented in hyperopt:
Hyperopt has been designed to accommodate Bayesian optimization algorithms based on Gaussian processes and regression trees, but these are not currently implemented.
All algorithms can be parallelized in two ways, using:
Hyperopt documentation can be found here, but is partly still hosted on the wiki. Here are some quick links to the most relevant pages:
See projects using hyperopt on the wiki.
If you use this software for research, please cite the paper (http://proceedings.mlr.press/v28/bergstra13.pdf) as follows:
Bergstra, J., Yamins, D., Cox, D. D. (2013) Making a Science of Model Search: Hyperparameter Optimization in Hundreds of Dimensions for Vision Architectures. TProc. of the 30th International Conference on Machine Learning (ICML 2013), June 2013, pp. I-115 to I-23.
This project has received support from
- National Science Foundation (IIS-0963668),
- Banting Postdoctoral Fellowship program,
- National Science and Engineering Research Council of Canada (NSERC),
- D-Wave Systems, Inc.