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Large Language Models (LLMs) have profoundly changed the world. Their self-attention mechanism is the key to the success of transformers in LLMs. However, the quadratic computational cost O (n²) to the length n input sequence is the notorious obstacle for further improvement and scalability in the longer context. In this work, we leverage the convolution-like structure of attention matrices to develop an efficient approximation method for attention computation using convolution matrices. We propose a conv basis system, "similar" to the rank basis, and show that any lower triangular (attention) matrix can always be decomposed as a sum of k structured convolution matrices in this basis system. We then design an algorithm to quickly decompose the attention matrix into k convolution matrices. Thanks to Fast Fourier Transforms (FFT), the attention inference can be computed in O (knd n) time, where d is the hidden dimension. In practice, we have d n, i. e. , d=3, 072 and n=1, 000, 000 for Gemma. Thus, when kd = n^o (1), our algorithm achieve almost linear time, i. e. , n^1+o (1). Furthermore, the attention training forward and backward gradient can be computed in n^1+o (1) as well. Our approach can avoid explicitly computing the n n attention matrix, which may largely alleviate the quadratic computational complexity. Furthermore, our algorithm works on any input matrices. This work provides a new paradigm for accelerating attention computation in transformers to enable their application to longer contexts.
Gu et al. (Wed,) studied this question.