English

TNT: Improving Chunkwise Training for Test-Time Memorization

Machine Learning 2025-11-11 v1 Artificial Intelligence

Abstract

Recurrent neural networks (RNNs) with deep test-time memorization modules, such as Titans and TTT, represent a promising, linearly-scaling paradigm distinct from Transformers. While these expressive models do not yet match the peak performance of state-of-the-art Transformers, their potential has been largely untapped due to prohibitively slow training and low hardware utilization. Existing parallelization methods force a fundamental conflict governed by the chunksize hyperparameter: large chunks boost speed but degrade performance, necessitating a fixed, suboptimal compromise. To solve this challenge, we introduce TNT, a novel training paradigm that decouples training efficiency from inference performance through a two-stage process. Stage one is an efficiency-focused pre-training phase utilizing a hierarchical memory. A global module processes large, hardware-friendly chunks for long-range context, while multiple parallel local modules handle fine-grained details. Crucially, by periodically resetting local memory states, we break sequential dependencies to enable massive context parallelization. Stage two is a brief fine-tuning phase where only the local memory modules are adapted to a smaller, high-resolution chunksize, maximizing accuracy with minimal overhead. Evaluated on Titans and TTT models, TNT achieves a substantial acceleration in training speed-up to 17 times faster than the most accurate baseline configuration - while simultaneously improving model accuracy. This improvement removes a critical scalability barrier, establishing a practical foundation for developing expressive RNNs and facilitating future work to close the performance gap with Transformers.

Keywords

Cite

@article{arxiv.2511.07343,
  title  = {TNT: Improving Chunkwise Training for Test-Time Memorization},
  author = {Zeman Li and Ali Behrouz and Yuan Deng and Peilin Zhong and Praneeth Kacham and Mahdi Karami and Meisam Razaviyayn and Vahab Mirrokni},
  journal= {arXiv preprint arXiv:2511.07343},
  year   = {2025}
}
R2 v1 2026-07-01T07:30:16.451Z