This repository contains the source code of Prismer and PrismerZ from the paper, Prismer: A Vision-Language Model with Multi-Task Experts. Check out our official demo at HuggingFace Space and a third-party demo at Replicate.
transformers
package.The implementation is based on PyTorch 1.13
, and highly integrated with Huggingface accelerate
toolkit for readable and optimised multi-node multi-gpu training.
First, let's install all package dependencies by running
pip install -r requirements.txt
Then we generate the corresponding accelerate
config based on your training server configuration. For both single-node multi-gpu and multi-node multi-gpu training, simply run and follow the instructions with,
accelerate config
We pre-train Prismer/PrismerZ with a combination of five widely used image-alt/text datasets, with pre-organised data lists provided below.
The web datasets (CC3M, SGU, CC12M) is composed with image urls. It is highly recommended to use img2dataset, a highly optimised toolkit for large-scale web scraping to download these images. An example bash script of using img2dataset
to download cc12m
dataset is provided below.
img2dataset --url_list filtered_cc12m.json --input_format "json" --url_col "url" --caption_col "caption" --output_folder cc12m --processes_count 16 --thread_count 64 --image_size 256
Note: It is expected that the number of downloaded images is less than the number of images in the json file, because some urls might not be valid or require long loading time.
We evaluate image captioning performance on two datasets, COCO 2014 and NoCaps; and VQA performance on VQAv2 dataset. In VQA tasks, we additionally augment the training data with Visual Genome QA, following BLIP. Again, we have prepared and organised the training and evaluation data lists provided below.
Before starting any experiments with Prismer, we need to first pre-generate the modality expert labels, so we may construct a multi-label dataset. In experts
folder, we have included all 6 experts we introduced in our paper. We have organised each expert's codebase with a shared and simple API.
Note: Specifically for segmentation experts, please first install deformable convolution operations by cd experts/segmentation/mask2former/modeling/pixel_decoder/ops
and run sh make.sh
.
To download pre-trained modality experts, run
python download_checkpoints.py --download_experts=True
To generate the expert labels, simply edit the configs/experts.yaml
with the corresponding data paths, and run
export PYTHONPATH=.
accelerate launch experts/generate_{EXPERT_NAME}.py
Note: Expert label generation is only required for Prismer models, not for PrismerZ models.
We have provided both Prismer and PrismerZ for pre-trained checkpoints (for zero-shot image captioning), as well as fined-tuned checkpoints on VQAv2 and COCO datasets. With these checkpoints, it should be expected to reproduce the exact performance listed below.
Model | Pre-trained [Zero-shot] | COCO [Fine-tuned] | VQAv2 [Fine-tuned] |
---|---|---|---|
PrismerZ-BASE | COCO CIDEr [109.6] | COCO CIDEr [133.7] | test-dev [76.58] |
Prismer-BASE | COCO CIDEr [122.6] | COCO CIDEr [135.1] | test-dev [76.84] |
PrismerZ-LARGE | COCO CIDEr [124.8] | COCO CIDEr [135.7] | test-dev [77.49] |
Prismer-LARGE | COCO CIDEr [129.7] | COCO CIDEr [136.5] | test-dev [78.42] |
To download pre-trained/fined-tuned checkpoints, run
# to download all model checkpoints (12 models in total)
python download_checkpoints.py --download_models=True
# to download specific checkpoints (Prismer-Base for fine-tuned VQA) in this example
python download_checkpoints.py --download_models="vqa_prismer_base"
Note: Remember to install java via sudo apt-get install default-jre
which is required to run the official COCO caption evaluation scripts.
To evaluate the model checkpoints, please run
# zero-shot image captioning (remember to remove caption prefix in the config files)
accelerate launch train_caption.py --exp_name {MODEL_NAME} --evaluate
# fine-tuned image captioning
accelerate launch train_caption.py --exp_name {MODEL_NAME} --from_checkpoint --evaluate
# fine-tuned VQA
accelerate launch train_vqa.py --exp_name {MODEL_NAME} --from_checkpoint --evaluate
To pre-train or fine-tune any model with or without checkpoints, please run
# to train/fine-tuning from scratch
accelerate launch train_{TASK}.py --exp_name {MODEL_NAME}
# to train/fine-tuning from the latest checkpoints (saved every epoch)
accelerate launch train_{TASK}.py --exp_name {MODEL_NAME} --from_checkpoint
We have also included model sharding in the current training script via PyTorch's official FSDP plugin. With the same training commands, additionally add --shard_grad_op
for ZeRO-2 Sharding (Gradients + Optimiser States), or --full_shard
for ZeRO-3 Sharding (ZeRO-2 + Network Parameters).
Note: You should expect the error range for VQAv2 Acc. to be less than 0.1; for COCO/NoCAPs CIDEr score to be less than 1.0.
Finally, we have offered a minimal example to perform image captioning in a single GPU with our fine-tuned Prismer/PrismerZ checkpoint. Simply put your images under helpers/images
(support .jpg
, .jpeg
, and .png
images), and run
python demo.py --exp_name {MODEL_NAME}
You then can see all generated modality expert labels in the helpers/labels
folder and the generated captions in the helpers/images
folder.
Particularly for the Prismer models, we have also offered a simple script to prettify the generated expert labels. To prettify and visualise the expert labels as well as its predicted captions, run
python demo_vis.py
Note: Remember to set up the corresponding config in the configs/caption.yaml
demo section. The default demo model config is for Prismer-Base.
If you found this code/work to be useful in your own research, please considering citing the following:
@article{liu2024prismer,
title={Prismer: A Vision-Language Model with Multi-Task Experts},
author={Liu, Shikun and Fan, Linxi and Johns, Edward and Yu, Zhiding and Xiao, Chaowei and Anandkumar, Anima},
journal={Transactions on Machine Learning Research},
year={2024}
}
Copyright © 2023, NVIDIA Corporation. All rights reserved.
This work is made available under the Nvidia Source Code License-NC.
The model checkpoints are shared under CC-BY-NC-SA-4.0. If you remix, transform, or build upon the material, you must distribute your contributions under the same license as the original.
For business inquiries, please visit our website and submit the form: NVIDIA Research Licensing.
We would like to thank all the researchers who open source their works to make this project possible. @bjoernpl for contributing an automated checkpoint download script.
If you have any questions, please contact sk.lorenmt@gmail.com
.