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Robustness evaluation and Adaptation of ImageNet models

This repo contains a growing collection of helper functions, tools and methods for robustness evaluation and adaptation of ImageNet scale models. The focus is on simple methods that work at scale.

We currently have the following features available:

Planned features for future releases are (please open an issue if you can think of additional interesting parts to add):

News

☕ The robusta toolbox for Robustness and Adaptation

Motivation

Besides reference implementations, this repo is mainly intended to provide a quick and easy way to adapt your own code. In particular, when developing new methods for improving robustness on deep learning models, we find it interesting to report results after adapting your model to the test datasets. This paints a more holistic image of model robustness: Some people might be interested in ad-hoc model performance, other might be interested in the performance obtained in a transductive inference setting.

Note that the package is not intended for general purpose domain adaptation. Instead, we focus on providing simple methods that prove to be effective for ImageNet scale model adaptation at test time. The package provides helper functions that are "minimally invasive" and can easily be added to existing source code for model evaluation.

Quick Start

You can install the package by running

pip install robusta

Depending on your system setup, it can make sense to first manually install the correct torch and torchvision versions as described on the PyTorch website.

Here is an example for how to use robusta for batchnorm adaptation & robust pseudo-labeling.

    model = torchvision.models.resnet50(pretrained=True)

    # We provide implementations for ImageNet-val, ImageNetC, ImageNetR,
    # ImageNetA and ImageNetD:
    val_dataset = robusta.datasets.imagenetc.ImageNetC(
        root=dataset_folder, corruption="gaussian_blur", severity=1,
        transform=transforms.Compose([transforms.ToTensor()])
        )
    val_loader = torch.utils.data.DataLoader(
        val_dataset, batch_size=batch_size, shuffle=True)

    # We offer different options for batch norm adaptation;
    # alternatives are "ema", "batch_wise_prior", ...
    robusta.batchnorm.adapt(model, adapt_type="batch_wise")

    # The accuracy metric can be specific to the dataset:
    # For example, ImageNet-R requires remapping into 200 classes.
    accuracy_metric = val_dataset.accuracy

    # You can also easily use self-learning in your model.
    # Self-learning adaptation can be combined with batch norm adaptation, example:
    parameters = robusta.selflearning.adapt(model, adapt_type="affine")
    optimizer = torch.optim.SGD(parameters, lr=1e-3)

    # You can choose from a set of adaptation losses (GCE, Entropy, ...)
    rpl_loss = robusta.selflearning.GeneralizedCrossEntropy(q=0.8)

    acc1_sum, acc5_sum, num_samples = 0., 0., 0.
    for epoch in range(num_epochs):
        predictions = []
        for images, targets in val_loader:

            logits = model(images)
            predictions = logits.argmax(dim=1)

            # Predictions are optional. If you do not specify them,
            # they will be computed within the loss function.
            loss = rpl_loss(logits, predictions)

            # When using self-learning, you need to add an additional optimizer
            # step in your evaluation loop.
            optimizer.zero_grad()
            loss.backward()
            optimizer.step()

            acc1_sum, acc5_sum += accuracy_metric(predictions, targets, topk=(1,5))
            num_samples += len(targets)
            print(f"Top-1: {acc1_sum/num_samples}, Top-5: {acc5_sum/num_samples}")

Example Implementations

Batch Norm Adaptation

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[Paper] [Web] [README] [Implementation]

We propose to go beyond the assumption of a single sample from the target domain when evaluating robustness. Re-computing BatchNorm statistics is a simple baseline algorithm for improving the corruption error up to 14% points over a wide range of models, when access to more than a single sample is possible.

Self-Learning

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[Paper] [Web] [README] [Implementation]

Test-time adaptation with self-learning improves robustness of large-scale computer vision models on ImageNet-C, -R, and -A.

Robustness evaluation of DINO models

[Blog Post] [Implementation coming soon]

License

Unless noted otherwise, code in this repo is released under an Apache 2.0 license. Some parts of the implementation use third party code. We typically indicate this in the file header or in the methods directly, and include the original license in the NOTICE file.

This repo does not contain the full code-base used in Rusak, Schneider et al. (2021) and is instead currently limited to a reference re-implementation for robust-pseudo labeling and entropy minimization. A full version of the codebase might be independently released in the future.

If you want to use part of this code commercially, please carefully check the involved parts. Part of the third-party implementations might be released under licences with a non-commercial use clause such as CC-NC. If in doubt, please reach out.

Contact

Please reach out for feature requests. Contributions welcome!

Note: The current version of this code base is a work in progress. We still decided to do this pre-release since the core methods are conceptually easy to use in your own code (batch norm adaptation, self-learning, ... and the current state might already be a useful place to start.