On the Computational Power of Transformers and its Implications in Sequence Modeling
June 16, 2020 ยท Declared Dead ยท ๐ Conference on Computational Natural Language Learning
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Authors
Satwik Bhattamishra, Arkil Patel, Navin Goyal
arXiv ID
2006.09286
Category
cs.LG: Machine Learning
Cross-listed
cs.CL,
stat.ML
Citations
84
Venue
Conference on Computational Natural Language Learning
Last Checked
4 months ago
Abstract
Transformers are being used extensively across several sequence modeling tasks. Significant research effort has been devoted to experimentally probe the inner workings of Transformers. However, our conceptual and theoretical understanding of their power and inherent limitations is still nascent. In particular, the roles of various components in Transformers such as positional encodings, attention heads, residual connections, and feedforward networks, are not clear. In this paper, we take a step towards answering these questions. We analyze the computational power as captured by Turing-completeness. We first provide an alternate and simpler proof to show that vanilla Transformers are Turing-complete and then we prove that Transformers with only positional masking and without any positional encoding are also Turing-complete. We further analyze the necessity of each component for the Turing-completeness of the network; interestingly, we find that a particular type of residual connection is necessary. We demonstrate the practical implications of our results via experiments on machine translation and synthetic tasks.
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