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HunyuanVideo: A Systematic Framework For Large Video Generation Model

               

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This repo contains PyTorch model definitions, pre-trained weights and inference/sampling code for our paper exploring HunyuanVideo. You can find more visualizations on our project page.

HunyuanVideo: A Systematic Framework For Large Video Generation Model

πŸŽ₯ Demo

demo.mp4

The video is heavily compressed due to compliance of GitHub policy. The high quality version can be downloaded from here.

πŸ”₯πŸ”₯πŸ”₯ News!!

  • Dec 7, 2024: πŸ€— We release the parallel inference code for HunyuanVideo powered by xDiT.
  • Dec 3, 2024: πŸ€— We release the inference code and model weights of HunyuanVideo.

πŸ“‘ Open-source Plan

  • HunyuanVideo (Text-to-Video Model)
    • Inference
    • Checkpoints
    • Multi-gpus Sequence Parallel inference (Faster inference speed on more gpus)
    • Penguin Video Benchmark
    • Web Demo (Gradio)
    • ComfyUI
    • Diffusers
    • Multi-gpus PipeFusion inference (Low memory requirmenets)
  • HunyuanVideo (Image-to-Video Model)
    • Inference
    • Checkpoints

Contents


Abstract

We present HunyuanVideo, a novel open-source video foundation model that exhibits performance in video generation that is comparable to, if not superior to, leading closed-source models. In order to train HunyuanVideo model, we adopt several key technologies for model learning, including data curation, image-video joint model training, and an efficient infrastructure designed to facilitate large-scale model training and inference. Additionally, through an effective strategy for scaling model architecture and dataset, we successfully trained a video generative model with over 13 billion parameters, making it the largest among all open-source models.

We conducted extensive experiments and implemented a series of targeted designs to ensure high visual quality, motion diversity, text-video alignment, and generation stability. According to professional human evaluation results, HunyuanVideo outperforms previous state-of-the-art models, including Runway Gen-3, Luma 1.6, and 3 top-performing Chinese video generative models. By releasing the code and weights of the foundation model and its applications, we aim to bridge the gap between closed-source and open-source video foundation models. This initiative will empower everyone in the community to experiment with their ideas, fostering a more dynamic and vibrant video generation ecosystem.

HunyuanVideo Overall Architecture

HunyuanVideo is trained on a spatial-temporally compressed latent space, which is compressed through a Causal 3D VAE. Text prompts are encoded using a large language model, and used as the conditions. Taking Gaussian noise and the conditions as input, our generative model produces an output latent, which is then decoded to images or videos through the 3D VAE decoder.

πŸŽ‰ HunyuanVideo Key Features

Unified Image and Video Generative Architecture

HunyuanVideo introduces the Transformer design and employs a Full Attention mechanism for unified image and video generation. Specifically, we use a "Dual-stream to Single-stream" hybrid model design for video generation. In the dual-stream phase, video and text tokens are processed independently through multiple Transformer blocks, enabling each modality to learn its own appropriate modulation mechanisms without interference. In the single-stream phase, we concatenate the video and text tokens and feed them into subsequent Transformer blocks for effective multimodal information fusion. This design captures complex interactions between visual and semantic information, enhancing overall model performance.

MLLM Text Encoder

Some previous text-to-video models typically use pretrained CLIP and T5-XXL as text encoders where CLIP uses Transformer Encoder and T5 uses an Encoder-Decoder structure. In contrast, we utilize a pretrained Multimodal Large Language Model (MLLM) with a Decoder-Only structure as our text encoder, which has the following advantages: (i) Compared with T5, MLLM after visual instruction finetuning has better image-text alignment in the feature space, which alleviates the difficulty of instruction following in diffusion models; (ii) Compared with CLIP, MLLM has been demonstrated superior ability in image detail description and complex reasoning; (iii) MLLM can play as a zero-shot learner by following system instructions prepended to user prompts, helping text features pay more attention to key information. In addition, MLLM is based on causal attention while T5-XXL utilizes bidirectional attention that produces better text guidance for diffusion models. Therefore, we introduce an extra bidirectional token refiner to enhance text features.

3D VAE

HunyuanVideo trains a 3D VAE with CausalConv3D to compress pixel-space videos and images into a compact latent space. We set the compression ratios of video length, space and channel to 4, 8 and 16 respectively. This can significantly reduce the number of tokens for the subsequent diffusion transformer model, allowing us to train videos at the original resolution and frame rate.

Prompt Rewrite

To address the variability in linguistic style and length of user-provided prompts, we fine-tune the Hunyuan-Large model as our prompt rewrite model to adapt the original user prompt to model-preferred prompt.

We provide two rewrite modes: Normal mode and Master mode, which can be called using different prompts. The prompts are shown here. The Normal mode is designed to enhance the video generation model's comprehension of user intent, facilitating a more accurate interpretation of the instructions provided. The Master mode enhances the description of aspects such as composition, lighting, and camera movement, which leans towards generating videos with a higher visual quality. However, this emphasis may occasionally result in the loss of some semantic details.

The Prompt Rewrite Model can be directly deployed and inferred using the Hunyuan-Large original code. We release the weights of the Prompt Rewrite Model here.

πŸ“ˆ Comparisons

To evaluate the performance of HunyuanVideo, we selected five strong baselines from closed-source video generation models. In total, we utilized 1,533 text prompts, generating an equal number of video samples with HunyuanVideo in a single run. For a fair comparison, we conducted inference only once, avoiding any cherry-picking of results. When comparing with the baseline methods, we maintained the default settings for all selected models, ensuring consistent video resolution. Videos were assessed based on three criteria: Text Alignment, Motion Quality, and Visual Quality. More than 60 professional evaluators performed the evaluation. Notably, HunyuanVideo demonstrated the best overall performance, particularly excelling in motion quality. Please note that the evaluation is based on Hunyuan Video's high-quality version. This is different from the currently released fast version.

Model Open Source Duration Text Alignment Motion Quality Visual Quality Overall Ranking
HunyuanVideo (Ours) βœ” 5s 61.8% 66.5% 95.7% 41.3% 1
CNTopA (API) ✘ 5s 62.6% 61.7% 95.6% 37.7% 2
CNTopB (Web) ✘ 5s 60.1% 62.9% 97.7% 37.5% 3
GEN-3 alpha (Web) ✘ 6s 47.7% 54.7% 97.5% 27.4% 4
Luma1.6 (API)✘ 5s 57.6% 44.2% 94.1% 24.8% 6
CNTopC (Web) ✘ 5s 48.4% 47.2% 96.3% 24.6% 5

πŸ“œ Requirements

The following table shows the requirements for running HunyuanVideo model (batch size = 1) to generate videos:

Model Setting
(height/width/frame)
GPU Peak Memory
HunyuanVideo 720px1280px129f 60GB
HunyuanVideo 544px960px129f 45GB
  • An NVIDIA GPU with CUDA support is required.
    • The model is tested on a single 80G GPU.
    • Minimum: The minimum GPU memory required is 60GB for 720px1280px129f and 45G for 544px960px129f.
    • Recommended: We recommend using a GPU with 80GB of memory for better generation quality.
  • Tested operating system: Linux

πŸ› οΈ Dependencies and Installation

Begin by cloning the repository:

git clone https://github.com/tencent/HunyuanVideo
cd HunyuanVideo

Installation Guide for Linux

We provide an environment.yml file for setting up a Conda environment. Conda's installation instructions are available here.

We recommend CUDA versions 11.8 and 12.0+.

# 1. Prepare conda environment
conda env create -f environment.yml

# 2. Activate the environment
conda activate HunyuanVideo

# 3. Install pip dependencies
python -m pip install -r requirements.txt

# 4. Install flash attention v2 for acceleration (requires CUDA 11.8 or above)
python -m pip install ninja
python -m pip install git+https://github.com/Dao-AILab/[email protected]

Additionally, HunyuanVideo also provides a pre-built Docker image. Use the following command to pull and run the docker image.

# For CUDA 11
docker pull hunyuanvideo/hunyuanvideo:cuda_11
docker run -itd --gpus all --init --net=host --uts=host --ipc=host --name hunyuanvideo --security-opt=seccomp=unconfined --ulimit=stack=67108864 --ulimit=memlock=-1 --privileged hunyuanvideo/hunyuanvideo:cuda_11

# For CUDA 12
docker pull hunyuanvideo/hunyuanvideo:cuda_12
docker run -itd --gpus all --init --net=host --uts=host --ipc=host --name hunyuanvideo --security-opt=seccomp=unconfined --ulimit=stack=67108864 --ulimit=memlock=-1 --privileged hunyuanvideo/hunyuanvideo:cuda_12

🧱 Download Pretrained Models

The details of download pretrained models are shown here.

πŸ”‘ Single-gpu Inference

We list the height/width/frame settings we support in the following table.

Resolution h/w=9:16 h/w=16:9 h/w=4:3 h/w=3:4 h/w=1:1
540p 544px960px129f 960px544px129f 624px832px129f 832px624px129f 720px720px129f
720p (recommended) 720px1280px129f 1280px720px129f 1104px832px129f 832px1104px129f 960px960px129f

Using Command Line

cd HunyuanVideo

python3 sample_video.py \
    --video-size 720 1280 \
    --video-length 129 \
    --infer-steps 50 \
    --prompt "A cat walks on the grass, realistic style." \
    --flow-reverse \
    --use-cpu-offload \
    --save-path ./results

More Configurations

We list some more useful configurations for easy usage:

Argument Default Description
--prompt None The text prompt for video generation
--video-size 720 1280 The size of the generated video
--video-length 129 The length of the generated video
--infer-steps 50 The number of steps for sampling
--embedded-cfg-scale 6.0 Embeded Classifier free guidance scale
--flow-shift 7.0 Shift factor for flow matching schedulers
--flow-reverse False If reverse, learning/sampling from t=1 -> t=0
--seed None The random seed for generating video, if None, we init a random seed
--use-cpu-offload False Use CPU offload for the model load to save more memory, necessary for high-res video generation
--save-path ./results Path to save the generated video

πŸš€ Parallel Inference on Multiple GPUs by xDiT

xDiT is a Scalable Inference Engine for Diffusion Transformers (DiTs) on multi-GPU Clusters. It has successfully provided low-latency parallel inference solutions for a variety of DiTs models, including mochi-1, CogVideoX, Flux.1, SD3, etc. This repo adopted the Unified Sequence Parallelism (USP) APIs for parallel inference of the HunyuanVideo model.

Install Dependencies Compatible with xDiT

# 1. Create a black conda environment
conda create -n hunyuanxdit python==3.10.9
conda activate hunyuanxdit

# 3. Install PyTorch component with CUDA 11.8
conda install pytorch==2.4.0 torchvision==0.19.0 torchaudio==2.4.0  pytorch-cuda=11.8 -c pytorch -c nvidia

# 3. Install pip dependencies
python -m pip install -r requirements_xdit.txt

You can skip the above steps and pull the pre-built docker image directly, which is built from docker/Dockerfile_xDiT

docker pull thufeifeibear/hunyuanvideo:latest

Using Command Line

For example, to generate a video with 8 GPUs, you can use the following command:

cd HunyuanVideo

torchrun --nproc_per_node=8 sample_video.py \
    --video-size 1280 720 \
    --video-length 129 \
    --infer-steps 50 \
    --prompt "A cat walks on the grass, realistic style." \
    --flow-reverse \
    --seed 42 \
    --ulysses-degree 8 \
    --ring-degree 1 \
    --save-path ./results

You can change the --ulysses-degree and --ring-degree to control the parallel configurations for the best performance. The valid parallel configurations are shown in the following table.

Supported Parallel Configurations (Click to expand)
--video-size --video-length --ulysses-degree x --ring-degree --nproc_per_node
1280 720 or 720 1280 129 8x1,4x2,2x4,1x8 8
1280 720 or 720 1280 129 1x5 5
1280 720 or 720 1280 129 4x1,2x2,1x4 4
1280 720 or 720 1280 129 3x1,1x3 3
1280 720 or 720 1280 129 2x1,1x2 2
1104 832 or 832 1104 129 4x1,2x2,1x4 4
1104 832 or 832 1104 129 3x1,1x3 3
1104 832 or 832 1104 129 2x1,1x2 2
960 960 129 6x1,3x2,2x3,1x6 6
960 960 129 4x1,2x2,1x4 4
960 960 129 3x1,1x3 3
960 960 129 1x2,2x1 2
960 544 or 544 960 129 6x1,3x2,2x3,1x6 6
960 544 or 544 960 129 4x1,2x2,1x4 4
960 544 or 544 960 129 3x1,1x3 3
960 544 or 544 960 129 1x2,2x1 2
832 624 or 624 832 129 4x1,2x2,1x4 4
624 832 or 624 832 129 3x1,1x3 3
832 624 or 624 832 129 2x1,1x2 2
720 720 129 1x5 5
720 720 129 3x1,1x3 3

Latency (Sec) for 1280x720 (129 frames 50 steps) on 8xGPU
1 4 8
1904.08 514.08 337.58

πŸ”— BibTeX

If you find HunyuanVideo useful for your research and applications, please cite using this BibTeX:

@misc{kong2024hunyuanvideo,
      title={HunyuanVideo: A Systematic Framework For Large Video Generative Models}, 
      author={Weijie Kong, Qi Tian, Zijian Zhang, Rox Min, Zuozhuo Dai, Jin Zhou, Jiangfeng Xiong, Xin Li, Bo Wu, Jianwei Zhang, Kathrina Wu, Qin Lin, Aladdin Wang, Andong Wang, Changlin Li, Duojun Huang, Fang Yang, Hao Tan, Hongmei Wang, Jacob Song, Jiawang Bai, Jianbing Wu, Jinbao Xue, Joey Wang, Junkun Yuan, Kai Wang, Mengyang Liu, Pengyu Li, Shuai Li, Weiyan Wang, Wenqing Yu, Xinchi Deng, Yang Li, Yanxin Long, Yi Chen, Yutao Cui, Yuanbo Peng, Zhentao Yu, Zhiyu He, Zhiyong Xu, Zixiang Zhou, Zunnan Xu, Yangyu Tao, Qinglin Lu, Songtao Liu, Dax Zhou, Hongfa Wang, Yong Yang, Di Wang, Yuhong Liu, and Jie Jiang, along with Caesar Zhong},
      year={2024},
      archivePrefix={arXiv preprint arXiv:2412.03603},
      primaryClass={cs.CV}
}

🧩 Projects that use HunyuanVideo

If you develop/use HunyuanVideo in your projects, welcome to let us know.

Acknowledgements

We would like to thank the contributors to the SD3, FLUX, Llama, LLaVA, Xtuner, diffusers and HuggingFace repositories, for their open research and exploration. Additionally, we also thank the Tencent Hunyuan Multimodal team for their help with the text encoder.

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