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The ImageNet-S dataset for large-scale unsupervised semantic segmentation.

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ImageNet-S Dataset for Large-scale Unsupervised/Semi-supervised Semantic Segmentation

The ImageNet-S dataset and toolbox.

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image

Introduction

Powered by the ImageNet dataset, unsupervised learning on large-scale data has made significant advances for classification tasks. There are two major challenges to allowing such an attractive learning modality for segmentation tasks: i) a large-scale benchmark for assessing algorithms is missing; ii) unsupervised shape representation learning is difficult. We propose a new problem of large-scale unsupervised semantic segmentation (LUSS) with a newly created benchmark dataset to track the research progress. Based on the ImageNet dataset, we propose the ImageNet-S dataset with 1.2 million training images and 50k high-quality semantic segmentation annotations for evaluation. Our benchmark has a high data diversity and a clear task objective. We also present a simple yet effective baseline method that works surprisingly well for LUSS. In addition, we benchmark related un/weakly/fully supervised methods accordingly, identifying the challenges and possible directions of LUSS.

News

  • 2022.11.24. The semantic segmentation on the MMSegmentation codebase is released, better performance is observed thanks to the MMSegmentation MMSegmentation.
  • 2022.10.18. The code of baseline method (PASS) for unsupervised semantic segmentation on the ImageNet-S dataset is released on PASS.
  • 2022.9.21. The code of semi-supervised semantic segmentation on the ImageNet-S dataset is released on ImageNetSegModel.

Apps and Sourcecode

ImageNet-S Dataset Preparation

Prepare the ImageNet-S dataset with one command:

The ImageNet-S dataset is based on the ImageNet-1k dataset. You need to have a copy of ImageNet-1k dataset, and you can also get the rest of the ImageNet-S dataset (split/annotations) with the following command:

cd datapreparation
bash data_preparation.sh [your imagenet path] [the path to save ImageNet-S datasets] [split: 50 300 919 all] [whether to copy new images: false, true]

Get part of the ImageNet-S dataset:

The data_preparation.sh command is composed of the following steps, and you can run separate scripts if you only need parts of the ImageNet-S dataset:

  • Extract training datasets: To extract the training set from the existing ImageNet dataset, run:
    python datapreparation_train.py \
      --imagenet-dir [your imagenet path] \
      --save-dir [the path to save ImageNet-S datasets] \
      --mode [split: 50 300 919 all]

You can set the mode to 50, 300, and 919 to extract the ImageNet-S-50, ImageNet-S-300, and ImageNet-S datasets. To extract all datasets one time, set mode to all. The script uses soft links to create datasets by default. To copy new images, please add --copy.

  • Extract validation and test datasets: To extract the validation and test datasets from the existing ImageNet dataset, run:
    python datapreparation_val.py \
      --imagenet-dir [your imagenet path] \
      --save-dir [the path to save ImageNet-S datasets] \
      --mode [split: 50 300 919 all]

You can set mode to 50, 300, and 919 to extract the ImageNet-S-50, ImageNet-S-300 and ImageNet-S datasets. To extract all datasets one time, set mode to all. The script copy new images of validation and test set simultaneously.

  • Download semantic segmentation annotations:
bash datapreparation_anno.sh [the path to save ImageNet-S datasets] [split: 50 300 919 all]

Dataset Information

Structure

├── imagenet-s
    ├── ImageNetS919
        ├── train-full  # full imagenet-1k training set with 1000 classes.
        ├── train       # imagenet-s-919 training set with 919 classes.
        ├── train-semi  # imagenet-s-919 training images with pixel-level annotations (10 images for each class)
        ├── train-semi-segmentation # semantic segmentation mask of the train-semi images.
        ├── validation  # imagenet-s-919 validation set.
        ├── validation-segmentation # semantic segmentation mask of the validation images.
        └── test        # magenet-s-919 test set, the segmentation mask is stored on the online evalution server.
    ├── ImageNetS300        
        ├── train       # imagenet-s-300 training set with 300 classes.
        ├── train-semi  # imagenet-s-300 training images with pixel-level annotations (10 images for each class)
        ├── train-semi-segmentation # semantic segmentation mask of the train-semi images.
        ├── validation  # imagenet-s-300 validation set.
        ├── validation-segmentation # semantic segmentation mask of the validation images.
        └── test        # magenet-s-300 test set, the segmentation mask is stored on the online evalution server.                     
    └── ImageNetS50                            
        ├── train     # imagenet-s-50 training set with 50 classes.
        ├── train-semi  # imagenet-s-50 training images with pixel-level annotations (10 images for each class)
        ├── train-semi-segmentation # semantic segmentation mask of the train-semi images.
        ├── validation  # imagenet-s-50 validation set.
        ├── validation-segmentation # semantic segmentation mask of the validation images.
        └── test        # magenet-s-50 test set, the segmentation mask is stored on the online evalution server.   

Image Numbers

The ImageNet-S dataset contains 1183322 training, 12419 validation, and 27423 testing images from 919 categories. We annotate 39842 val/test images and 9190 training images with precise pixel-level masks.

Dataset category train val test
ImageNet-S_{50} 50 64431 752 1682
ImageNet-S_{300} 300 384862 4097 9088
ImageNet-S 919 1183322 12419 27423

Q&A

How to get the class id from the segmentation mask images?

The image annotation (eg. an image in validation-segmentation) is stored in the png form with RGB channels, you can get the class id by R+G*256.
The ignored part is annotated as 1000, and the other category is annotated as 0.

segmentation = Image.open(path) # RGB
segmentation_id = segmentation[:, :, 1] * 256 + segmentation[:, :, 0] # R+G*256

How to match the class id in ImageNet-S with the ImageNet tag id?

The imagenet-s class id is obtained by sorting the imagenet tag id:

with open('ImageNetS_categories_im919.txt') as f:
    msg = f.read().splitlines()

msg = sorted(msg) # sort tags to get the imagenet-s class id.
msg = '\n'.join(msg)

with open('ImageNetS_categories_im919_sort.txt', 'w') as f:
    f.write(msg)

We provide a matching table between imagenet-s class id and imagenet tag id as follows (The i-th row is the class id of imagenet-s (start from 1)): imagenet-s-919 imagenet-s-300 imagenet-s-50

Note: for imagenet-s-919, we merge some categories as follows:

# key is merged into the value, eg. merge n04356056 into n04355933.
merge = {'n04356056': 'n04355933',
         'n04493381': 'n02808440',
         'n03642806': 'n03832673',
         'n04008634': 'n03773504',
         'n03887697': 'n15075141'}

If you have any other question, open an issue or email us via [email protected]

Evaluation

Before evaluation, note that given the I-th category, the value of pixels that belong to the I-th category should be set to (I % 256, I / 256, 0) with the order of RGB.

    cd evaluation

Matching

We provide a default matching algorithm, run:

    python match.py \ 
      --predict-dir [the path to validation ground truth] \
      --gt-dir [the path to validation prediction] \
      --mode [split: 50 300 919] \
      --workers [the number of workers for dataloader] \
      --session-name [the file name of saved matching]

The matching will be saved under the directory of results.

Evaluation on val set

With the segmentation results of your algorithm, you can evaluate the quality of your results by running:

    python evaluator.py \ 
      --predict-dir [the path to validation ground truth] \
      --gt-dir [the path to validation prediction] \
      --mode [split: 50 300 919] \
      --workers [the number of workers for dataloader]

You can also use a matching between your prediction and ground truth for evaluation by adding --match [the file name of saved matching]. However, the script defaults that the prediction has been matched to the ground truth.

Online benchmark

Due to the lack of ground-truth (GT) category labels during training, LUSS models cannot be directly evaluated like in the supervised setting. We present three evaluation protocols for LUSS, including the fully unsupervised evaluation, semi-supervised evaluation, and distance matching evaluation. To explore the upper bound of ImageNet-S semantic segmentation, we also present a free evaluation benchmark with no limitations.

  • Fully unsupervised protocol link
  • Distance matching protocol link
  • Semi-supervised protocol link
  • Free protocol link

Submission rules

The submission file has the following structure:

├── submission.zip
    ├── n...                              // prediction
    ├── n...                              // prediction
    ├── n...                              // prediction
    ├── match.json                        // optional
    └── method.txt                        // description of method

submission example

You must submit your results to the corresponding protocols, and miss-matched submissions will be deleted. We summarize a table for different protocols:

Actions Fully unsupervised Distance matching Semi-supervised Free
ImageNet-S~{50/300/full} only^{note1}
Only unsupervised pre-training
Label generation and fine-tuning
Fine-tune with 1% training image annotation
Supervised pre-trained weights?
Extra training data?
Supervised edge/saliency?

Note1: Pre-training on the ImageNet-S~{full} and fine-tuning on the ImageNet~{300/50} is not allowed.

Fully unsupervised protocol link

The fully unsupervised evaluation protocol requires no human-annotated labels during training and only needs the validation/test set for evaluation. Unlike the supervised tasks, categories are generated by the model in the LUSS task, which needs to match with GT categories during evaluation. We present the default image-level matching scheme in the ImageNet-S toolbox, while an effective matching scheme should improve LUSS evaluation performance. You need to match the generated categories with GT categories, and assign matched categories to the test images.

Distance matching protocol link

In distance matching evaluation protocol, we directly get the embeddings of GT categories with the pixel-level labeled training images and match them with embeddings in the validation/testing set to assign labels. You don't need to care about the label generation in LUSS and only need to provide an unsupervised pre-trained model. The inference code for distance matching is in the ImageNet-S toolbox.

Semi-supervised protocol link

We can conduct semi-supervised fine-tuning to evaluate LUSS models as we annotate about 1% of training images with pixel-level labels. The semi-supervised evaluation protocol requires fine-tuning the trained LUSS models with the 1% pixel-level human-labeled training images. Therefore, this protocol does not need matching generated and GT category. Also, this protocol is suitable for real-world applications where a small part of images are human-labeled and many images are unlabeled.

Free protocol link

In this protocol, you can do whatever you want to improve the semantic segmentation performance on ImageNet-S, e.g. ImageNet-21K supervised pretraining, image-level annotations, and pixel-level annotations. The only rule is donot use image-level or pixel-level annotations of val/test sets.

Citation

@article{gao2022luss,
  title={Large-scale Unsupervised Semantic Segmentation},
  author={Gao, Shanghua and Li, Zhong-Yu and Yang, Ming-Hsuan and Cheng, Ming-Ming and Han, Junwei and Torr, Philip},
  journal=TPAMI,
  year={2022}
}

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The ImageNet-S dataset for large-scale unsupervised semantic segmentation.

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