This is the official PyTorch implementation of the Adversarial Continual Learning at ECCV 2020. .
Continual learning aims to learn new tasks without forgetting previously learned ones. We hypothesize that representations learned to solve each task in a sequence have shared structure while containing some task-specific properties. We show that shared features are significantly less prone to forgetting and propose a novel hybrid continual learning framework that learns a disjoint representation for task-invariant and task-specific features required to solve a sequence of tasks. Our model combines architecture growth to prevent forgetting of task-specific skills and an experience replay approach to preserve shared skills. We demonstrate our hybrid approach is effective in avoiding forgetting and show it is superior to both architecture-based and memory-based approaches on class incrementally learning of a single dataset as well as a sequence of multiple datasets in image classification.
Sayna Ebrahimi (UC Berkeley, FAIR), Franziska Meier (FAIR), Roberto Calandra (FAIR), Trevor Darrell (UC Berkeley), Marcus Rohrbach (FAIR)
If using this code, parts of it, or developments from it, please cite our paper:
@article{ebrahimi2020adversarial,
title={Adversarial Continual Learning},
author={Ebrahimi, Sayna and Meier, Franziska and Calandra, Roberto and Darrell, Trevor and Rohrbach, Marcus},
journal={arXiv preprint arXiv:2003.09553},
year={2020}
}
- Linux-64
- Python 3.6
- PyTorch 1.3.1
- CPU or NVIDIA GPU + CUDA10 CuDNN7.5
- Create a conda environment and install required packages:
conda create -n <env> python=3.6
conda activate <env>
pip install -r requirements.txt
- Clone this repo:
mkdir ACL
cd ACL
git clone [email protected]:facebookresearch/Adversarial-Continual-Learning.git
- The following structure is expected in the main directory:
./src : main directory where all scripts are placed in
./data : data directory
./src/checkpoints : results are saved in here
For each datasest run the following commands from src
directory. Config file for each experiment contains the hyperparameters we used in the paper:
Split MNIST (5 Tasks):
python main.py --config ./configs/config_mnist5.yml
Permuted MNIST (10 Tasks):
python main.py --config ./configs/config_pmnist.yml
Split CIFAR100 (20 Tasks):
python main.py --config ./configs/config_cifar100.yml
Split MiniImageNet (20 Tasks):
python main.py --config ./configs/config_miniimagenet.yml
Sequence of 5 Tasks (CIFAR10, MNIST, notMNIST, Fashion MNIST, SVHN)
python main.py --config ./configs/config_multidatasets.yml
See here.
miniImageNet data should be downloaded and pickled as a dictionary (data.pkl
) with images
and labels
keys and placed in a sub-folder in ags.data_dir
named as miniimagenet
. The script used to split data.pkl
into training and test sets is included in data dorectory (data/
)
notMNIST dataset is included here in ./data/notMNIST
as it was used in our experiments.
Other datasets will be automatically downloaded and extracted to ./data
if they do not exist.
- For questions/bugs, contact the author Sayna Ebrahimi via email [email protected]
This source code is released under The MIT License found in the LICENSE file in the root directory of this source tree.
Our code structure is inspired by HAT.