English

The Recurrent Transformer: Greater Effective Depth and Efficient Decoding

Machine Learning 2026-04-24 v1

Abstract

Transformers process tokens in parallel but are temporally shallow: at position tt, each layer attends to key-value pairs computed based on the previous layer, yielding a depth capped by the number of layers. Recurrent models offer unbounded temporal depth but suffer from optimization instability and historically underutilize modern accelerators. We introduce the Recurrent Transformer, a simple architectural change where each layer attends to key-value pairs computed off its own activations, yielding layerwise recurrent memory while preserving standard autoregressive decoding cost. We show that the architecture can emulate both (i) a conventional Transformer and (ii) token-to-token recurrent updates under mild assumptions, while avoiding optimization instability. Naively, prefill/training appears bandwidth-bound with effective arithmetic intensity near 11 because keys and values are revealed sequentially; we give an exact tiling-based algorithm that preserves the mathematical computation while reducing HBM traffic from Θ(N2)\Theta(N^2) to Θ(NlogN)\Theta(N\log N), increasing effective arithmetic intensity to Θ(N/logN)\Theta(N/\log N) for sequence length NN. On 150M and 300M parameter C4 pretraining, Recurrent Transformers improve cross-entropy over a parameter-matched Transformer baseline and achieve the improvement with fewer layers (fixed parameters), suggesting that recurrence can trade depth for width, thus reducing KV cache memory footprint and inference latency.

Keywords

Cite

@article{arxiv.2604.21215,
  title  = {The Recurrent Transformer: Greater Effective Depth and Efficient Decoding},
  author = {Costin-Andrei Oncescu and Depen Morwani and Samy Jelassi and Alexandru Meterez and Mujin Kwun and Sham Kakade},
  journal= {arXiv preprint arXiv:2604.21215},
  year   = {2026}
}
R2 v1 2026-07-01T12:31:46.816Z