ifBO 0.3.13

In-context Freeze-Thaw Bayesian Optimization for Hyperparameter Optimization

ifBO: In-context Freeze-Thaw Bayesian Optimization for Hyperparameter Optimization

This repository contains the official code for our ICML 2024 paper. ifBO is an efficient Bayesian Optimization algorithm that dynamically selects and incrementally evaluates candidates during the optimization process. It uses a model called the Freeze-Thaw surrogate (FT-PFN) to predict the performance of candidate configurations as more resources are allocated. The main branch includes the necessary API to use FT-PFN. Refer to the following sections:

• Surrogate API: to learn how to initialize and use the surrogate model.
• Bayesian Optimization with ifBO: to understand how to use ifBO for Hyperparameter Optimization.

To reproduce experiments from the above paper version, please refer to the branch icml-2024.

Installation

Requires Python 3.11.

pip install -U ifBO

Usage

Surrogate API

Checkout out this notebook.

Initializing the model

from ifbo.surrogate import FTPFN
from ifbo import Curve, PredictionResult

model = FTPFN(version="0.0.1")

This creates a .model/ directory in the current working directory for the surrogate model. To have control over this, specify a target_path: Path when initializing.

Supported versions:

Version	Identifier	Notes
0.0.1	ICML '24 submission	Supports up to 1000 unique configurations in the context, with each configuration having a maximum of 10 dimensions.

Creating context and query points

The code snippet below demonstrates how to create instances of learning curves using ifbo.Curve class. Each curve represents the performance over time of a configuration (vector of hyperparameter values). These instances are used to form the context and query points for the model:

• context: known data points with both time (t) and observed values (y).
• query: points where predictions are needed, with only time (t) provided.

Note: All values (hyperparameters, performances, and times) must be normalized to the range $[0, 1]$.

import torch

context = [
  Curve(
    hyperparameters=torch.tensor([0.2, 0.1, 0.5]), 
    t=torch.tensor([0.1, 0.2, 0.3]), 
    y=torch.tensor([0.1, 0.15, 0.3])
  ),
  Curve(
    hyperparameters=torch.tensor([0.2, 0.3, 0.25]), 
    t=torch.tensor([0.1, 0.2, 0.3, 0.4]), 
    y=torch.tensor([0.2, 0.5, 0.6, 0.75])
  ),
]
query = [
  Curve(
    hyperparameters=torch.tensor([0.2, 0.1, 0.5]), 
    t=torch.tensor([0.3, 0.4, 0.5, 0.6, 0.7, 0.9])
  ),
  Curve(
    hyperparameters=torch.tensor([0.2, 0.3, 0.25]), 
    t=torch.tensor([0.4, 0.5, 0.6, 0.7, 0.8, 0.9])
  ),
]

Making predictions

Use the model to predict performances at the query points.

predictions: list[PredictionResult] = model.predict(context=context, query=query)

# Get predictions for the first curve
prediction: PredictionResult = predictions[0]

# Print the 5% and 95% percentiles of the predictive posterior distribution
print(prediction.quantile(0.05), prediction.quantile(0.95))

Following the PFN approach, the FT-PFN model outputs the Predictive Posterior Distribution (PPD) of the performances for each query point. Each PPD is encapsulated in an ifbo.PredictionResult object, which provides an interface to compute various quantities from the distribution, including:

• likelihood(y_test: torch.Tensor): Computes the negative log-likelihood of the test targets (y_test).
• ucb(): Computes the upper confidence bound.
• ei(y_best: torch.Tensor): Computes the expected improvement over y_best.
• pi(y_best: torch.Tensor): Computes the probability of improvement over y_best.
• quantile(q: float): Computes the value at the specified quantile level q.

Bayesian Optimization with ifBO

To use the ifBO algorithm in practice, refer to NePS, a package for hyperparameter optimization that includes the latest and improved version of ifBO. Below is a template example of how to use ifBO with NePS. For a complete Python script, see the full example.

import neps

def training_pipeline(
    num_layers,
    num_neurons,
    epochs,
    learning_rate,
    weight_decay
):
    # Training logic and checkpoint loading here
    pass

pipeline_space = {
    "learning_rate": neps.Float(1e-5, 1e-1, log=True),
    "num_layers": neps.Integer(1, 5),
    "num_neurons": neps.Integer(64, 128),
    "weight_decay": neps.Float(1e-5, 0.1, log=True),
    "epochs": neps.Integer(1, 10, is_fidelity=True),
}

neps.run(
    pipeline_space=pipeline_space,
    run_pipeline=training_pipeline,
    searcher="ifbo",
    max_evaluations_total=50,
    step_size=1,
    surrogate_model_args=dict(
        version="0.0.1",
        target_path=None,
    ),
)

Citation

If using our surrogate, code, experiment setup, kindly cite using:

@inproceedings{
  rakotoarison-icml24,
  title={In-Context Freeze-Thaw Bayesian Optimization for Hyperparameter Optimization},
  author={H. Rakotoarison and S. Adriaensen and N. Mallik and S. Garibov and E. Bergman and F. Hutter},
  booktitle={Forty-first International Conference on Machine Learning},
  year={2024},
  url={https://openreview.net/forum?id=VyoY3Wh9Wd}
}