- [Model Release] Jan 2023, released implementation of BLIP-2
Paper, Project Page,
A generic and efficient pre-training strategy that easily harvests development of pretrained vision models and large language models (LLMs) for vision-language pretraining. BLIP-2 beats Flamingo on zero-shot VQAv2 (65.0 vs 56.3), establishing new state-of-the-art on zero-shot captioning (on NoCaps 121.6 CIDEr score vs previous best 113.2). In addition, equipped with powerful LLMs (e.g. OPT, FlanT5), BLIP-2 also unlocks the new zero-shot instructed vision-to-language generation capabilities for various interesting applications!
- Jan 2023, LAVIS is now available on PyPI for installation!
- [Model Release] Dec 2022, released implementation of Img2LLM-VQA (CVPR 2023, "From Images to Textual Prompts: Zero-shot VQA with Frozen Large Language Models", by Jiaxian Guo et al)
Paper, Project Page,
A plug-and-play module that enables off-the-shelf use of Large Language Models (LLMs) for visual question answering (VQA). Img2LLM-VQA surpasses Flamingo on zero-shot VQA on VQAv2 (61.9 vs 56.3), while in contrast requiring no end-to-end training!
- [Model Release] Oct 2022, released implementation of PNP-VQA (EMNLP Findings 2022, "Plug-and-Play VQA: Zero-shot VQA by Conjoining Large Pretrained Models with Zero Training", by Anthony T.M.H. et al),
Paper, Project Page, )
A modular zero-shot VQA framework that requires no PLMs training, achieving SoTA zero-shot VQA performance.
- Introduction
- Installation
- Getting Started
- Jupyter Notebook Examples
- Resources and Tools
- Documentations
- Ethical and Responsible Use
- Technical Report and Citing LAVIS
- License
LAVIS is a Python deep learning library for LAnguage-and-VISion intelligence research and applications. This library aims to provide engineers and researchers with a one-stop solution to rapidly develop models for their specific multimodal scenarios, and benchmark them across standard and customized datasets. It features a unified interface design to access
- 10+ tasks (retrieval, captioning, visual question answering, multimodal classification etc.);
- 20+ datasets (COCO, Flickr, Nocaps, Conceptual Commons, SBU, etc.);
- 30+ pretrained weights of state-of-the-art foundation language-vision models and their task-specific adaptations, including ALBEF, BLIP, ALPRO, CLIP.
Key features of LAVIS include:
-
Unified and Modular Interface: facilitating to easily leverage and repurpose existing modules (datasets, models, preprocessors), also to add new modules.
-
Easy Off-the-shelf Inference and Feature Extraction: readily available pre-trained models let you take advantage of state-of-the-art multimodal understanding and generation capabilities on your own data.
-
Reproducible Model Zoo and Training Recipes: easily replicate and extend state-of-the-art models on existing and new tasks.
-
Dataset Zoo and Automatic Downloading Tools: it can be a hassle to prepare the many language-vision datasets. LAVIS provides automatic downloading scripts to help prepare a large variety of datasets and their annotations.
The following table shows the supported tasks, datasets and models in our library. This is a continuing effort and we are working on further growing the list.
Tasks | Supported Models | Supported Datasets |
---|---|---|
Image-text Pre-training | ALBEF, BLIP | COCO, VisualGenome, SBU ConceptualCaptions |
Image-text Retrieval | ALBEF, BLIP, CLIP | COCO, Flickr30k |
Text-image Retrieval | ALBEF, BLIP, CLIP | COCO, Flickr30k |
Visual Question Answering | ALBEF, BLIP | VQAv2, OKVQA, A-OKVQA |
Image Captioning | BLIP | COCO, NoCaps |
Image Classification | CLIP | ImageNet |
Natural Language Visual Reasoning (NLVR) | ALBEF, BLIP | NLVR2 |
Visual Entailment (VE) | ALBEF | SNLI-VE |
Visual Dialogue | BLIP | VisDial |
Video-text Retrieval | BLIP, ALPRO | MSRVTT, DiDeMo |
Text-video Retrieval | BLIP, ALPRO | MSRVTT, DiDeMo |
Video Question Answering (VideoQA) | BLIP, ALPRO | MSRVTT, MSVD |
Video Dialogue | VGD-GPT | AVSD |
Multimodal Feature Extraction | ALBEF, CLIP, BLIP, ALPRO | customized |
Text-to-image Generation | [COMING SOON] |
- (Optional) Creating conda environment
conda create -n lavis python=3.8
conda activate lavis
- install from PyPI
pip install salesforce-lavis
- Or, for development, you may build from source
git clone https://github.com/salesforce/LAVIS.git
cd LAVIS
pip install -e .
Model zoo summarizes supported models in LAVIS, to view:
from lavis.models import model_zoo
print(model_zoo)
# ==================================================
# Architectures Types
# ==================================================
# albef_classification ve
# albef_feature_extractor base
# albef_nlvr nlvr
# albef_pretrain base
# albef_retrieval coco, flickr
# albef_vqa vqav2
# alpro_qa msrvtt, msvd
# alpro_retrieval msrvtt, didemo
# blip_caption base_coco, large_coco
# blip_classification base
# blip_feature_extractor base
# blip_nlvr nlvr
# blip_pretrain base
# blip_retrieval coco, flickr
# blip_vqa vqav2, okvqa, aokvqa
# clip_feature_extractor ViT-B-32, ViT-B-16, ViT-L-14, ViT-L-14-336, RN50
# clip ViT-B-32, ViT-B-16, ViT-L-14, ViT-L-14-336, RN50
# gpt_dialogue base
Let’s see how to use models in LAVIS to perform inference on example data. We first load a sample image from local.
import torch
from PIL import Image
# setup device to use
device = torch.device("cuda" if torch.cuda.is_available() else "cpu")
# load sample image
raw_image = Image.open("docs/_static/merlion.png").convert("RGB")
This example image shows Merlion park (source), a landmark in Singapore.
In this example, we use the BLIP model to generate a caption for the image. To make inference even easier, we also associate each
pre-trained model with its preprocessors (transforms), accessed via load_model_and_preprocess()
.
import torch
from lavis.models import load_model_and_preprocess
device = torch.device("cuda" if torch.cuda.is_available() else "cpu")
# loads BLIP caption base model, with finetuned checkpoints on MSCOCO captioning dataset.
# this also loads the associated image processors
model, vis_processors, _ = load_model_and_preprocess(name="blip_caption", model_type="base_coco", is_eval=True, device=device)
# preprocess the image
# vis_processors stores image transforms for "train" and "eval" (validation / testing / inference)
image = vis_processors["eval"](raw_image).unsqueeze(0).to(device)
# generate caption
model.generate({"image": image})
# ['a large fountain spewing water into the air']
BLIP model is able to answer free-form questions about images in natural language.
To access the VQA model, simply replace the name
and model_type
arguments
passed to load_model_and_preprocess()
.
from lavis.models import load_model_and_preprocess
model, vis_processors, txt_processors = load_model_and_preprocess(name="blip_vqa", model_type="vqav2", is_eval=True, device=device)
# ask a random question.
question = "Which city is this photo taken?"
image = vis_processors["eval"](raw_image).unsqueeze(0).to(device)
question = txt_processors["eval"](question)
model.predict_answers(samples={"image": image, "text_input": question}, inference_method="generate")
# ['singapore']
LAVIS provides a unified interface to extract features from each architecture. To extract features, we load the feature extractor variants of each model. The multimodal feature can be used for multimodal classification. The low-dimensional unimodal features can be used to compute cross-modal similarity.
from lavis.models import load_model_and_preprocess
model, vis_processors, txt_processors = load_model_and_preprocess(name="blip_feature_extractor", model_type="base", is_eval=True, device=device)
caption = "a large fountain spewing water into the air"
image = vis_processors["eval"](raw_image).unsqueeze(0).to(device)
text_input = txt_processors["eval"](caption)
sample = {"image": image, "text_input": [text_input]}
features_multimodal = model.extract_features(sample)
print(features_multimodal.multimodal_embeds.shape)
# torch.Size([1, 12, 768]), use features_multimodal[:,0,:] for multimodal classification tasks
features_image = model.extract_features(sample, mode="image")
features_text = model.extract_features(sample, mode="text")
print(features_image.image_embeds.shape)
# torch.Size([1, 197, 768])
print(features_text.text_embeds.shape)
# torch.Size([1, 12, 768])
# low-dimensional projected features
print(features_image.image_embeds_proj.shape)
# torch.Size([1, 197, 256])
print(features_text.text_embeds_proj.shape)
# torch.Size([1, 12, 256])
similarity = features_image.image_embeds_proj[:,0,:] @ features_text.text_embeds_proj[:,0,:].t()
print(similarity)
# tensor([[0.2622]])
LAVIS inherently supports a wide variety of common language-vision datasets by providing automatic download tools to help download and organize these datasets. After downloading, to load the datasets, use the following code:
from lavis.datasets.builders import dataset_zoo
dataset_names = dataset_zoo.get_names()
print(dataset_names)
# ['aok_vqa', 'coco_caption', 'coco_retrieval', 'coco_vqa', 'conceptual_caption_12m',
# 'conceptual_caption_3m', 'didemo_retrieval', 'flickr30k', 'imagenet', 'laion2B_multi',
# 'msrvtt_caption', 'msrvtt_qa', 'msrvtt_retrieval', 'msvd_caption', 'msvd_qa', 'nlvr',
# 'nocaps', 'ok_vqa', 'sbu_caption', 'snli_ve', 'vatex_caption', 'vg_caption', 'vg_vqa']
After downloading the images, we can use load_dataset()
to obtain the dataset.
from lavis.datasets.builders import load_dataset
coco_dataset = load_dataset("coco_caption")
print(coco_dataset.keys())
# dict_keys(['train', 'val', 'test'])
print(len(coco_dataset["train"]))
# 566747
print(coco_dataset["train"][0])
# {'image': <PIL.Image.Image image mode=RGB size=640x480>,
# 'text_input': 'A woman wearing a net on her head cutting a cake. ',
# 'image_id': 0}
If you already host a local copy of the dataset, you can pass in the vis_path
argument to change the default location to load images.
coco_dataset = load_dataset("coco_caption", vis_path=YOUR_LOCAL_PATH)
See examples for more inference examples, e.g. captioning, feature extraction, VQA, GradCam, zeros-shot classification.
- Benchmarks: see Benchmark for instructions to evaluate and train supported models.
- Dataset Download and Browsing: see Dataset Download for instructions and automatic tools on download common language-vision datasets.
- GUI Demo: to run the demo locally, run
bash run_scripts/run_demo.sh
and then follow the instruction on the prompts to view in browser. A web demo is coming soon.
For more details and advanced usages, please refer to documentation.
We note that models in LAVIS provide no guarantees on their multimodal abilities; incorrect or biased predictions may be observed. In particular, the datasets and pretrained models utilized in LAVIS may contain socioeconomic biases which could result in misclassification and other unwanted behaviors such as offensive or inappropriate speech. We strongly recommend that users review the pre-trained models and overall system in LAVIS before practical adoption. We plan to improve the library by investigating and mitigating these potential biases and inappropriate behaviors in the future.
You can find more details in our technical report.
If you're using LAVIS in your research or applications, please cite using this BibTeX:
@misc{li2022lavis,
title={LAVIS: A Library for Language-Vision Intelligence},
author={Dongxu Li and Junnan Li and Hung Le and Guangsen Wang and Silvio Savarese and Steven C. H. Hoi},
year={2022},
eprint={2209.09019},
archivePrefix={arXiv},
primaryClass={cs.CV}
}
If you have any questions, comments or suggestions, please do not hesitate to contact us at [email protected].