How Transformers Learn to Plan via Multi-Token Prediction
Abstract
While next-token prediction (NTP) has been the standard objective for training language models, it often struggles to capture global structure in reasoning tasks. Multi-token prediction (MTP) has recently emerged as a promising alternative, yet its underlying mechanisms remain poorly understood. In this paper, we study how MTP facilitates reasoning, with a focus on planning. Empirically, we show that MTP consistently outperforms NTP on both synthetic graph path-finding tasks and more realistic reasoning benchmarks, such as Countdown and boolean satisfiability problems. Theoretically, we analyze a simplified two-layer Transformer on a star graph task. We prove that MTP induces a two-stage reverse reasoning process: the model first attends to the end node and then reconstructs the path by tracing intermediate nodes backward. This behavior arises from a gradient decoupling property of MTP, which provides a cleaner training signal compared to NTP. Ultimately, our results highlight how multi-token objectives inherently bias optimization toward robust and interpretable reasoning circuits.
Cite
@article{arxiv.2604.11912,
title = {How Transformers Learn to Plan via Multi-Token Prediction},
author = {Jianhao Huang and Zhanpeng Zhou and Renqiu Xia and Baharan Mirzasoleiman and Weijie Su and Wei Huang},
journal= {arXiv preprint arXiv:2604.11912},
year = {2026}
}