| # MiniGPT-4: Enhancing Vision-language Understanding with Advanced Large Language Models | |
| [Deyao Zhu](https://tsutikgiau.github.io/)* (On Job Market!), [Jun Chen](https://junchen14.github.io/)* (On Job Market!), [Xiaoqian Shen](https://xiaoqian-shen.github.io), [Xiang Li](https://xiangli.ac.cn), and [Mohamed Elhoseiny](https://www.mohamed-elhoseiny.com/). *Equal Contribution | |
| **King Abdullah University of Science and Technology** | |
| ## Online Demo | |
| Click the image to chat with MiniGPT-4 around your images | |
| [](https://minigpt-4.github.io) | |
| ## Examples | |
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| :-------------------------:|:-------------------------: | |
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| More examples can be found in the [project page](https://minigpt-4.github.io). | |
| ## Introduction | |
| - MiniGPT-4 aligns a frozen visual encoder from BLIP-2 with a frozen LLM, Vicuna, using just one projection layer. | |
| - We train MiniGPT-4 with two stages. The first traditional pretraining stage is trained using roughly 5 million aligned image-text pairs in 10 hours using 4 A100s. After the first stage, Vicuna is able to understand the image. But the generation ability of Vicuna is heavilly impacted. | |
| - To address this issue and improve usability, we propose a novel way to create high-quality image-text pairs by the model itself and ChatGPT together. Based on this, we then create a small (3500 pairs in total) yet high-quality dataset. | |
| - The second finetuning stage is trained on this dataset in a conversation template to significantly improve its generation reliability and overall usability. To our surprise, this stage is computationally efficient and takes only around 7 minutes with a single A100. | |
| - MiniGPT-4 yields many emerging vision-language capabilities similar to those demonstrated in GPT-4. | |
|  | |
| ## Getting Started | |
| ### Installation | |
| **1. Prepare the code and the environment** | |
| Git clone our repository, creating a python environment and ativate it via the following command | |
| ```bash | |
| git clone https://github.com/Vision-CAIR/MiniGPT-4.git | |
| cd MiniGPT-4 | |
| conda env create -f environment.yml | |
| conda activate minigpt4 | |
| ``` | |
| **2. Prepare the pretrained Vicuna weights** | |
| The current version of MiniGPT-4 is built on the v0 versoin of Vicuna-13B. | |
| Please refer to our instruction [here](PrepareVicuna.md) | |
| to prepare the Vicuna weights. | |
| The final weights would be in a single folder with the following structure: | |
| ``` | |
| vicuna_weights | |
| βββ config.json | |
| βββ generation_config.json | |
| βββ pytorch_model.bin.index.json | |
| βββ pytorch_model-00001-of-00003.bin | |
| ... | |
| ``` | |
| Then, set the path to the vicuna weight in the model config file | |
| [here](minigpt4/configs/models/minigpt4.yaml#L16) at Line 16. | |
| **3. Prepare the pretrained MiniGPT-4 checkpoint** | |
| To play with our pretrained model, download the pretrained checkpoint | |
| [here](https://drive.google.com/file/d/1a4zLvaiDBr-36pasffmgpvH5P7CKmpze/view?usp=share_link). | |
| Then, set the path to the pretrained checkpoint in the evaluation config file | |
| in [eval_configs/minigpt4_eval.yaml](eval_configs/minigpt4_eval.yaml#L10) at Line 11. | |
| ### Launching Demo Locally | |
| Try out our demo [demo.py](demo.py) on your local machine by running | |
| ``` | |
| python demo.py --cfg-path eval_configs/minigpt4_eval.yaml --gpu-id 0 | |
| ``` | |
| Here, we load Vicuna as 8 bit by default to save some GPU memory usage. | |
| Besides, the default beam search width is 1. | |
| Under this setting, the demo cost about 23G GPU memory. | |
| If you have a more powerful GPU with larger GPU memory, you can run the model | |
| in 16 bit by setting low_resource to False in the config file | |
| [minigpt4_eval.yaml](eval_configs/minigpt4_eval.yaml) and use a larger beam search width. | |
| ### Training | |
| The training of MiniGPT-4 contains two alignment stages. | |
| **1. First pretraining stage** | |
| In the first pretrained stage, the model is trained using image-text pairs from Laion and CC datasets | |
| to align the vision and language model. To download and prepare the datasets, please check | |
| our [first stage dataset preparation instruction](dataset/README_1_STAGE.md). | |
| After the first stage, the visual features are mapped and can be understood by the language | |
| model. | |
| To launch the first stage training, run the following command. In our experiments, we use 4 A100. | |
| You can change the save path in the config file | |
| [train_configs/minigpt4_stage1_pretrain.yaml](train_configs/minigpt4_stage1_pretrain.yaml) | |
| ```bash | |
| torchrun --nproc-per-node NUM_GPU train.py --cfg-path train_configs/minigpt4_stage1_pretrain.yaml | |
| ``` | |
| A MiniGPT-4 checkpoint with only stage one training can be downloaded | |
| [here](https://drive.google.com/file/d/1u9FRRBB3VovP1HxCAlpD9Lw4t4P6-Yq8/view?usp=share_link). | |
| Compared to the model after stage two, this checkpoint generate incomplete and repeated sentences frequently. | |
| **2. Second finetuning stage** | |
| In the second stage, we use a small high quality image-text pair dataset created by ourselves | |
| and convert it to a conversation format to further align MiniGPT-4. | |
| To download and prepare our second stage dataset, please check our | |
| [second stage dataset preparation instruction](dataset/README_2_STAGE.md). | |
| To launch the second stage alignment, | |
| first specify the path to the checkpoint file trained in stage 1 in | |
| [train_configs/minigpt4_stage1_pretrain.yaml](train_configs/minigpt4_stage2_finetune.yaml). | |
| You can also specify the output path there. | |
| Then, run the following command. In our experiments, we use 1 A100. | |
| ```bash | |
| torchrun --nproc-per-node NUM_GPU train.py --cfg-path train_configs/minigpt4_stage2_finetune.yaml | |
| ``` | |
| After the second stage alignment, MiniGPT-4 is able to talk about the image coherently and user-friendly. | |
| ## Acknowledgement | |
| + [BLIP2](https://huggingface.co/docs/transformers/main/model_doc/blip-2) The model architecture of MiniGPT-4 follows BLIP-2. Don't forget to check this great open-source work if you don't know it before! | |
| + [Lavis](https://github.com/salesforce/LAVIS) This repository is built upon Lavis! | |
| + [Vicuna](https://github.com/lm-sys/FastChat) The fantastic language ability of Vicuna with only 13B parameters is just amazing. And it is open-source! | |
| If you're using MiniGPT-4 in your research or applications, please cite using this BibTeX: | |
| ```bibtex | |
| @misc{zhu2022minigpt4, | |
| title={MiniGPT-4: Enhancing Vision-language Understanding with Advanced Large Language Models}, | |
| author={Deyao Zhu and Jun Chen and Xiaoqian Shen and xiang Li and Mohamed Elhoseiny}, | |
| year={2023}, | |
| } | |
| ``` | |
| ## License | |
| This repository is under [BSD 3-Clause License](LICENSE.md). | |
| Many codes are based on [Lavis](https://github.com/salesforce/LAVIS) with | |
| BSD 3-Clause License [here](LICENSE_Lavis.md). | |