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Vision Transformer with Deformable Attention

This repository contains the code for the paper Vision Transformer with Deformable Attention (CVPR2022, Best Paper Finalists) [arXiv][video][poster][CVPR page], and DAT++: Spatially Dynamic Vision Transformerwith Deformable Attention (extended version)[arXiv].

This repository mainly includes the implementation for image classification experiments. For object detection and instance segmentation, please refer to DAT-Detection; for semantic segmentation, please see DAT-Segmentation for more details.

Introduction

Motivation

Motivation

(a) Vision Transformer(ViT) has proved its superiority over many tasks thanks to its large or even global receptive field. However, this global attention leads to excessive computational costs. (b) Swin Transformer proposes shifted window attention, which is a more efficient sparse attention mechanism with linear computation complexity. Nevertheless, this hand-crafted attention pattern is likely to drop important features outside one window, and shifting windows impedes the growth of the receptive field, limiting modeling the long-range dependencies. (c) DCN expands the receptive fields of the standard convolutions with the learned offsets for each different query. Howbeit, directly applying this technique to the Vision Transformer is non-trivial for the quadratic space complexity and the training difficulties. (d) Deformable Attention (DAT) is proposed to model the relations among tokens effectively under the guidance of the important regions in the feature maps. This flexible scheme enables the self-attention module to focus on relevant regions and capture more informative features.

Method

Deform_Attn

By learning several groups of offsets for the grid reference points, the deformed keys and values are sampled from these shifted locations. This deformable attention can capture the most informative regions in the image. On this basis, we present Deformable Attention Transformer (DAT) and DAT++, a general backbone model with deformable attention for both image classification and other dense prediction tasks.

Visualizations

Visualizations

Visualizations show the most important keys denotes in orange circles, where larger circles indicates higher attention scores in the 3rd column. The 4-th and 5-th columns display the important keys (orange circles) to some queries (red starts). The important keys cover the main parts of the objects, which demonstrates the effectiveness of DAT and DAT++.

Dependencies

Evaluate Pretrained Models on ImageNet-1K Classification

We provide the pretrained models in the tiny, small, and base versions of DAT++, as listed below.

modelresolutionacc@1configpretrained weights
DAT-T++224x22483.9configOneDrive / TsinghuaCloud
DAT-S++224x22484.6configOneDrive / TsinghuaCloud
DAT-B++224x22484.9configOneDrive / TsinghuaCloud
DAT-B++384x38485.9configOneDrive / TsinghuaCloud

To evaluate one model, please download the pretrained weights to your local machine and run the script evaluate.sh as follow.

Please notice: Before training or evaluation, please set the --data-path argument in train.sh or evaluate.sh to the path where ImageNet-1K data stores.

bash evaluate.sh <gpu_nums> <path-to-config> <path-to-pretrained-weights>

E.g., suppose evaluating the DAT-Tiny model (dat_pp_tiny_in1k_224.pth) with 8 GPUs, the command should be:

bash evaluate.sh 8 configs/dat_tiny.yaml dat_pp_tiny_in1k_224.pth

And the evaluation result should give:

[2023-09-04 17:18:15 dat_plus_plus] (main.py 301): INFO  * Acc@1 83.864 Acc@5 96.734
[2023-09-04 17:18:15 dat_plus_plus] (main.py 179): INFO Accuracy of the network on the 50000 test images: 83.9%

Train Models from Scratch

To train a model from scratch, we provide a simple script train.sh. E.g, to train a model with 8 GPUs on a single node, you can use this command:

bash train.sh 8 <path-to-config> <experiment-tag>

We also provide a training script train_slurm.sh for training models on multiple machines with a larger batch-size like 4096.

bash train_slurm.sh 32 <path-to-config> <slurm-job-name>

Remember to change the <path-to-imagenet> in the script files to your own ImageNet directory.

Future Updates

Acknowledgements

This code is developed on the top of Swin Transformer, we thank to their efficient and neat codebase. The computational resources supporting this work are provided by Hangzhou High-Flyer AI Fundamental Research Co.,Ltd.

Citation

If you find our work is useful in your research, please consider citing:

@article{xia2023dat,
    title={DAT++: Spatially Dynamic Vision Transformer with Deformable Attention}, 
    author={Zhuofan Xia and Xuran Pan and Shiji Song and Li Erran Li and Gao Huang},
    year={2023},
    journal={arXiv preprint arXiv:2309.01430},
}

@InProceedings{Xia_2022_CVPR,
    author    = {Xia, Zhuofan and Pan, Xuran and Song, Shiji and Li, Li Erran and Huang, Gao},
    title     = {Vision Transformer With Deformable Attention},
    booktitle = {Proceedings of the IEEE/CVF Conference on Computer Vision and Pattern Recognition (CVPR)},
    month     = {June},
    year      = {2022},
    pages     = {4794-4803}
}

Contact

If you have any questions or concerns, please send email to xzf23@mails.tsinghua.edu.cn.