Evolutionary Hyperband for Scalable, Robust and Efficient Hyperparameter Optimization
Project description
DEHB: Evolutionary Hyperband for Scalable, Robust and Efficient Hyperparameter Optimization
Welcome to DEHB, an algorithm for Hyperparameter Optimization (HPO). DEHB uses Differential Evolution (DE) under-the-hood as an Evolutionary Algorithm to power the black-box optimization that HPO problems pose.
dehb
is a python package implementing the DEHB algorithm. It offers an intuitive interface to optimize user-defined problems using DEHB.
Getting Started
Installation
pip install dehb
Using DEHB
DEHB allows users to either utilize the Ask & Tell interface for manual task distribution or leverage the built-in functionality (run
) to set up a Dask cluster autonomously. The following snippet offers a small look in to how to use DEHB. For further information, please refer to our getting started examples in our documentation.
optimizer = DEHB(
f=your_target_function,
cs=config_space,
dimensions=dimensions,
min_fidelity=min_fidelity,
max_fidelity=max_fidelity)
##### Using Ask & Tell
# Ask for next configuration to run
job_info = optimizer.ask()
# Run the configuration for the given fidelity. Here you can freely distribute the computation to any worker you'd like.
result = your_target_function(config=job_info["config"], fidelity=job_info["fidelity"])
# When you received the result, feed them back to the optimizer
optimizer.tell(job_info, result)
##### Using run()
# Run optimization for 1 bracket. Output files will be saved to ./logs
traj, runtime, history = optimizer.run(brackets=1, verbose=True)
Running DEHB in a parallel setting
For a more in-depth look in how-to run DEHB in a parallel setting, please have a look at our documentation.
Tutorials/Example notebooks
- 00 - A generic template to use DEHB for multi-fidelity Hyperparameter Optimization
- 01.1 - Using DEHB to optimize 4 hyperparameters of a Scikit-learn's Random Forest on a classification dataset
- 01.2 - Using DEHB to optimize 4 hyperparameters of a Scikit-learn's Random Forest on a classification dataset using Ask & Tell interface
- 02 - Optimizing Scikit-learn's Random Forest without using ConfigSpace to represent the hyperparameter space
- 03 - Hyperparameter Optimization for MNIST in PyTorch
To run PyTorch example: (note additional requirements)
python examples/03_pytorch_mnist_hpo.py \
--min_fidelity 1 \
--max_fidelity 3 \
--runtime 60 \
--verbose
Documentation
For more details and features, please have a look at our documentation.
Contributing
Any contribution is greaty appreciated! Please take the time to check out our contributing guidelines
DEHB Hyperparameters
We recommend the default settings. The default settings were chosen based on ablation studies over a collection of diverse problems and were found to be generally useful across all cases tested. However, the parameters are still available for tuning to a specific problem.
The Hyperband components:
- min_fidelity: Needs to be specified for every DEHB instantiation and is used in determining the fidelity spacing for the problem at hand.
- max_fidelity: Needs to be specified for every DEHB instantiation. Represents the full-fidelity evaluation or the actual black-box setting.
- eta: (default=3) Sets the aggressiveness of Hyperband's aggressive early stopping by retaining 1/eta configurations every round
The DE components:
- strategy: (default=
rand1_bin
) Chooses the mutation and crossover strategies for DE.rand1
represents the mutation strategy whilebin
represents the binomial crossover strategy.
Other mutation strategies include: {rand2
,rand2dir
,best
,best2
,currenttobest1
,randtobest1
}
Other crossover strategies include: {exp
}
Mutation and crossover strategies can be combined with a_
separator, for e.g.:rand2dir_exp
. - mutation_factor: (default=0.5) A fraction within [0, 1] weighing the difference operation in DE
- crossover_prob: (default=0.5) A probability within [0, 1] weighing the traits from a parent or the mutant
To cite the paper or code
@inproceedings{awad-ijcai21,
author = {N. Awad and N. Mallik and F. Hutter},
title = {{DEHB}: Evolutionary Hyberband for Scalable, Robust and Efficient Hyperparameter Optimization},
pages = {2147--2153},
booktitle = {Proceedings of the Thirtieth International Joint Conference on
Artificial Intelligence, {IJCAI-21}},
publisher = {ijcai.org},
editor = {Z. Zhou},
year = {2021}
}
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