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Pytorch implementation of our paper Classification-Then-Grounding: Reformulating Video Scene Graphs as Temporal Bipartite Graphs, which is accepted by CVPR2022

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Classification-Then-Grounding: Reformulating Video Scene Graphs as Temporal Bipartite Graphs

Pytorch implementation of our paper Classification-Then-Grounding: Reformulating Video Scene Graphs as Temporal Bipartite Graphs, which is accepted by CVPR2022. (arXiv)

cvpr2022-6703.png

We also won the 1st place of Video Relation Understanding (VRU) Grand Challenge in ACM Multimedia 2021, with a simplified version of our model.(The code for object tracklets generation is available at here)

Requirements

Python == 3.7 or later, Pytorch == 1.6 or later, for other basic packages, just run the project and download whatever needed.

Datasets

Download the ImageNet-VidVRD dataset and VidOR dataset, and put them in the following folder as

├── dataloaders
│   ├── dataloader_vidvrd.py
│   └── ...
├── datasets
│   ├── cache                       # cache file for our dataloaders
│   ├── vidvrd-dataset
│   │   ├── train
│   │   ├── test
│   │   └── videos
│   ├── vidor-dataset
│   │   ├── annotation
│   │   └── videos
│   └── GT_json_for_eval
│       ├── VidORval_gts.json       # GT josn for evlauate
│       └── VidVRDtest_gts.json
├── tracking_results                # tracklets data & features
│   ├── ...
│   ├── format_demo.py              
│   └── readme.md   
├── experiments   
├── models
├── ...

Verify tracklets data & feature preparation by running dataloader_demo

This section helps you download the tracklets data and place them correctly, as well as set the dataloader's config correctly. Successfully run the tools/dataloader_demo.py to verify all data & configs are set correctly.

NOTE we use the term proposal in our code to represent tracklet proposals in video-level, which is totally different with the concept of "proposal" in "proposal-based methods" in our paper. In our paper, we use "proposals to represent paired subject-object tracklet segments. In contrast, here the term proposal in our code represents long-term object tracklets in video-level (i.e., without sliding window or video segments).

Tracklet data for VidVRD

  1. Download the tracklet with features at here: train, test. And put them in tracking_results/. Refer to tracking_results/readme.md for more details about the tracklet data.

  2. Download the tracklet with features used in "Beyond Short-Term Snippet: Video Relation Detection with Spatio-Temporal Global Context" at the author's personal page here.

    Some Notes

    • we use the term pku (i.e., Peking University) in our code to refer to their tracklets & features)
    • The original data released by them only have 999 .npy files (maybe they have updated the link now), missing data for video ILSVRC2015_train_00884000. So we trained our own Faster-RCNN (same training setting as the above paper), and extract the tracklet & features. And the supplemental data can be find here.
  3. The tracklet with features are in VidVRD_test_every1frames (ours), VidVRD_train_every1frames (ours), preprocess_data/tracking/videovrd_detect_tracking (PKU, both train & test), in whcih each .npy file corresponds to a video and contains all the tracklets in that video. The I3D features of tracklets are in preprocess_data/tracking/videovrd_i3d (PKU, both train & test). Put them under the dir of this project (or any other position if you use absolute path).

  4. modify the config file at experiments/demo/config_.py, where proposal_dir is the dir of tracklet with features, i3d_dir is the dir of tracklets' I3D features, and ann_dir is datasets/vidvrd-dataset.

  5. Verify all data & configs are set correctly. e.g., for PKU's tracklets with I3D features, run the following commands: (refer to tools/dataloader_demo.py for more details.):

    python tools/dataloader_demo.py \
            --cfg_path experiments/demo/config_.py \
            --split test \
            --dataset_class pku_i3d
    

Tracklet data for VidOR

  • Download the I3D feature of train & val videos (used for grounding stage) at here

    • we extract the I3D feature by following this repo (and also use their released pre-trained I3D weight).
  • Download the pre-prepared cache data for VidOR-val (here, around 19G), VidOR-train (here, 14 parts in total, around 126G), and put them in datasets/cache. (these cached data includes classeme features)

  • Some Notes

    Ideally, you can prepare these cache data from .npy files (as did in VidVRD). However, due to some ancient coding reasons, we extract bbox RoI feature for each frame, which makes these .npy files too large (827G for VidOR-train and 90G for VidOR-val). Therefore, we only release pre-prepared cache data as above.

    Despite this, we still release the .npy files without RoI features, i.e., only box positions, (here, around 12G), and you can extract their RoI features based on the position by yourself. Refer to tracking_results/readme.md for more details about the tracklet data.

    Refer to this repository VidVRD-tracklets (last Section of README.md) for more details about extracting features based on the given bbox positions.

    As for classeme feature, For VidOR, we use the weighted average of category word embeddings, based on the classification probability vectors predicted by the detector. ("soft" classeme) For VidVRD, we just use the category word embeddings as classeme feature, i.e., "hard" classeme. refer to tools_draft/extract_classeme.py for more details.

Evaluation:

First, make sure you run tools/dataloader_demo.py successfully

  1. first generate the GT json file for evaluation:

    for vidvrd:

    python VidVRD-helper/prepare_gts_for_eval.py \
        --dataset_type vidvrd \
        --save_path datasets/GT_json_for_eval/VidVRDtest_gts.json
    

    for vidor:

    python VidVRD-helper/prepare_gts_for_eval.py \
        --dataset_type vidor \
        --save_path datasets/GT_json_for_eval/VidORval_gts.json
    
  2. Download model weights for different exps here, and put them in the experiments/ dir. Download pre-prepared data here, and put them in the prepared_data/ dir.

  3. Refer to experiments/readme.md for the correspondence between the exp ids and the table ids in our paper.

  4. For VidVRD, run the following commands to evaluate different exps: (refer to tools/eval_vidvrd.py for more details)

    e.g., for exp1

    python tools/eval_vidvrd.py \
        --cfg_path experiments/exp1/config_.py \
        --ckpt_path experiments/exp1/model_epoch_80.pth \
        --use_pku \
        --cuda 1 \
        --save_tag debug
    
  5. For VidOR, refer to tools/eval_vidor.py for more details.

    Run the following commands to evaluate BIG-C (i.e., only the classification stage):

    python tools/eval_vidor.py \
        --eval_cls_only \
        --cfg_path experiments/exp4/config_.py \
        --ckpt_path experiments/exp4/model_epoch_60.pth \
        --save_tag epoch60_debug \
        --cuda 1
    

    Run the following commands to evaluate BIG based on the output of cls stage (you need run BIG-C first and save the infer_results).

    python tools/eval_vidor.py \
        --cfg_path experiments/grounding_weights/config_.py \
        --ckpt_path experiments/grounding_weights/model_epoch_70.pth \
        --output_dir experiments/exp4_with_grounding \
        --cls_stage_result_path experiments/exp4/VidORval_infer_results_topk3_epoch60_debug.pkl \
        --save_tag with_grd_epoch70 \
        --cuda 1
    

    Run the following commands to evaluate the fraction recall (refer to table-6 in our paper, you need run BIG first and save the hit_infos).

    python tools/eval_fraction_recall.py \
        --cfg_path experiments/grounding_weights/config_.py \
        --hit_info_path  experiments/exp5_with_grounding/VidORval_hit_infos_aft_grd_with_grd_epoch70.pkl
    

NOTE

  • We also provide another evaluation scripts (i.e., tools/eval_vidvrd_our_gt.py and tools/eval_vidor_our_gt.py). The main difference lies in the process of constructing GT tracklets (i.e., from frame-level bbox annotations to video-level tracklets GTs). Compared to VidVRD-helper's GTs, here we perform linear interpolation for fragmented GT tracklets. Consequently the evaluation results have slight differences.
  • Nevertheless, the results reported in our paper are evaluated with VidVRD-helper's GTs (i.e., tools/eval_vidvrd.py and tools/eval_vidor.py) to ensure fair comparisons.
  • In our paper, all scores are truncated to 4 decimal places (not rounded)

Training

  1. For VidVRD, run the following commands to train for different exps: (refer to tools/train_vidvrd.py for more details)

    e.g., for exp1

    CUDA_VISIBLE_DEVICES=0,1 python tools/train_vidvrd.py \
        --cfg_path experiments/exp1/config_.py \
        --use_pku \
        --save_tag retrain
    
  2. For VidOR, refer to tools/train_vidor.py.py for more details

    Run the following commands to train BIG-C (i.e., only the classification stage). e.g., for exp4

    CUDA_VISIBLE_DEVICES=0,1 python tools/train_vidor.py \
        --cfg_path experiments/exp4/config_.py \
        --save_tag retrain
    

    Note that we pre-assign all the labels for Base-C (exp6) since it does not require bipartite matching between predicate and GTs. The label assignment takes around 1.5 hours.

    Run the following commands to train the grounding stage:

    CUDA_VISIBLE_DEVICES=2,3 python tools/train_vidor.py \
        --train_grounding \
        --cfg_path experiments/grounding_weights/config_.py \
        --save_tag retrain
    

Data Release Summarize

  • model weights for all exps (google drive, here)

  • pre-prepared data (statical prior & category text Glove embddings) (dcd MEGA cloud, here)

  • I3D feature of VidOR train & val around 3.3G (dcd MEGA cloud, here)

  • VidOR traj .npy files (OnlyPos) (this has been released, around 12G) here (gkf google drive).refer to this repository: VidVRD-tracklets

  • VidVRD traj .npy files (with feature) around 20G

    • VidVRD-test , gkf zju cloud, here (3.87G) (deprecated)
    • VidVRD-test, MEGA cloud, here (1.42G) (same file as that in zju cloud, but is zipped).
    • VidVRD-train dcd MEGA cloud here (13G)
  • cache file for train & val (for vidor)

    • v9 for val (around 19G) (dcd MEGA cloud here)
    • v7 for train (14 parts, around 126G in total here)
  • [Update]: Because the link of pku data provided by pku's author isn't available anymore. We upload their data into our MEGA cloud: here (6.21G)

  • [Update]: For the Tracklet detector's weight:

    • for VidOR dataset, it has been released in our previous repo: VidVRD-tracklets, and can be downloaded here
    • for VidVRD dataset, download here (NOTE that this weight is the re-trained version, not the same as that was used in our paper)
    • for the training data of the Tracklet detector, refer to the Appendix of our paper

(dcd is just the name of MEGA cloud account of our Lab :) )

Citation

If our work is helpful for your research, please cite our publication:

@inproceedings{gao2021classification,
  title={Classification-Then-Grounding: Reformulating Video Scene Graphs as Temporal Bipartite Graphs},
  author={Gao, Kaifeng and Chen, Long and Niu, Yulei and Shao, Jian and Xiao, Jun},
  booktitle={Proceedings of the IEEE/CVF conference on computer vision and pattern recognition},
  year={2022}
}

Others

I have been working on this project for more than one year. So when learning and using pytorch, I wrote a lot of APIs (utils/utils_func.py), in which some of them might be interesting and useful, e.g., unique_with_idx_nd. So I opened a new repo to collect them, here

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Pytorch implementation of our paper Classification-Then-Grounding: Reformulating Video Scene Graphs as Temporal Bipartite Graphs, which is accepted by CVPR2022

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