General-purpose, long-context autoregressive modeling with Perceiver AR
Abstract
Real-world data is high-dimensional: a book, image, or musical performance can easily contain hundreds of thousands of elements even after compression. However, the most commonly used autoregressive models, Transformers, are prohibitively expensive to scale to the number of inputs and layers needed to capture this long-range structure. We develop Perceiver AR, an autoregressive, modality-agnostic architecture which uses cross-attention to map long-range inputs to a small number of latents while also maintaining end-to-end causal masking. Perceiver AR can directly attend to over a hundred thousand tokens, enabling practical long-context density estimation without the need for hand-crafted sparsity patterns or memory mechanisms. When trained on images or music, Perceiver AR generates outputs with clear long-term coherence and structure. Our architecture also obtains state-of-the-art likelihood on long-sequence benchmarks, including 64 x 64 ImageNet images and PG-19 books.
Cite
@article{arxiv.2202.07765,
title = {General-purpose, long-context autoregressive modeling with Perceiver AR},
author = {Curtis Hawthorne and Andrew Jaegle and Cătălina Cangea and Sebastian Borgeaud and Charlie Nash and Mateusz Malinowski and Sander Dieleman and Oriol Vinyals and Matthew Botvinick and Ian Simon and Hannah Sheahan and Neil Zeghidour and Jean-Baptiste Alayrac and João Carreira and Jesse Engel},
journal= {arXiv preprint arXiv:2202.07765},
year = {2022}
}
Comments
ICML 2022