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Efficient Dataset Distillation using Random Feature Approximation
Code for the NeurIPS paper "Efficient Dataset Distillation using Random Feature Approximation"
Contact: Noel Loo
Abstract
Dataset distillation compresses large datasets into smaller synthetic coresets which retain performance with the aim of reducing the storage and computational burden of processing the entire dataset. Today's best-performing algorithm, Kernel Inducing Points (KIP), which makes use of the correspondence between infinite-width neural networks and kernel-ridge regression, is prohibitively slow due to the exact computation of the neural tangent kernel matrix, scaling O(|S|2), with |S| being the coreset size. To improve this, we propose a novel algorithm that uses a random feature approximation (RFA) of the Neural Network Gaussian Process (NNGP) kernel, which reduces the kernel matrix computation to O(|S|). Our algorithm provides at least a 100-fold speedup over KIP and can run on a single GPU. Our new method, termed an RFA Distillation (RFAD), performs competitively with KIP and other dataset condensation algorithms in accuracy over a range of large-scale datasets, both in kernel regression and finite-width network training. We demonstrate the effectiveness of our approach on tasks involving model interpretability and privacy preservation.
Example usage
To run generate a distilled set on cifar10, 10 samples per class, platt loss with label learning, for example:
python3 run_distillation.py --dataset cifar10 --save_path path/to/directory/ --samples_per_class 10 --platt --learn_labels
This does not automatically evaluate the dataset on the test set.
To evaluate a distilled set with NNGP/NTK kernel ridge regression with an already made distilled dataset on all datasets except celebA:
python3 eval_distilled_set.py --dataset fashion --save_path path/to/directory --run_krr
To evaluate a distilled set with a finite network trained with SGD on mnist, with an already made distilled dataset:
python3 eval_distilled_set.py --dataset mnist --save_path path/to/directory --run_finite --lr 1e-3 --weight_decay 1e-3 --label_scale 8` --centering
To automatically load the set of training hyperparameters used for finite training results in the paper, use the command "--use_best_hypers", i.e.
python3 eval_distilled_set.py --dataset cifar10 --save_path path/to/directory --run_finite --use_best_hypers
utils.py contains the best hyperparameters for finite network training
To use the empirical NNGP for inference on fashion-mnist:
python3 run_network_parameter_analysis.py --dataset fashion --save_path path/to/directory
To use the empirical NNGP for inference on fashion-mnist:
python3 run_network_parameter_analysis.py --dataset fashion --save_path path/to/directory
To run the time profiling experiment for model counts of 1,2,4,8, for samples per class in the coreset of 1,5,10,20,50:
python3 run_time_profile_exp.py --dataset cifar10 --n_models 1 2 4 8 --samples_per_class 1 5 10 20 50
To run corruption experiments on CelebA with corruption 0.8:
python3 run_distillation.py --dataset celeba --save_path path/to/directory/ --samples_per_class 1 --platt --n_batches 1 --init_strategy noise --corruption 0.8
To run CelebA experiments, make sure you are on the latest version of PyTorch, as older version have a bug where the test/train splis are incorrect.
To evaluate with NNGP KRR on CelebA:
python3 eval_distilled_set_batched.py --dataset celeba --save_path path/to/directory --run_krr
We additionally include some distilled dataset for cifar10 with 1,10, or 50 samples per class in ./distilled_images_final/cifar10 in the files 'best.npz'
Requirements
- pytorch
- neural-tangents
- torch_optimizer
- sklearn, matplotlib, numpy, scipy Note that some versions of pytorch have incorrect test/train splits for CelebA