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Learning to Remember, Learn, and Forget in Attention-Based Models

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arxiv 2602.09075 v4 pith:BTT56JT5 submitted 2026-02-09 cs.LG cs.AI

Learning to Remember, Learn, and Forget in Attention-Based Models

classification cs.LG cs.AI
keywords palimpsaattentionlearningmemorymodelsassociativecapacitygated
verification ladder T0 review T1 audit T2 compute T3 formal T4 reserved
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In-Context Learning (ICL) in transformers acts as an online associative memory and is believed to underpin their high performance on complex sequence processing tasks. However, in gated linear attention models, this memory has a fixed capacity and is prone to interference, especially for long sequences. We propose Palimpsa, a self-attention model that views ICL as a continual learning problem that must address a stability-plasticity dilemma. Palimpsa uses Bayesian metaplasticity, where the plasticity of each attention state is tied to an importance state grounded by a prior distribution that captures accumulated knowledge. We demonstrate that various gated linear attention models emerge as specific architecture choices and posterior approximations, and that Mamba2 is a special case of Palimpsa where forgetting dominates. This theoretical link enables the transformation of any non-metaplastic model into a metaplastic one, significantly expanding its memory capacity. Our experiments show that Palimpsa consistently outperforms baselines on the Multi-Query Associative Recall (MQAR) benchmark and on Commonsense Reasoning tasks.

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