English

Eliminating Hidden Serialization in Multi-Node Megakernel Communication

Distributed, Parallel, and Cluster Computing 2026-05-04 v1

Abstract

Recent megakernel designs for Mixture-of-Experts (MoE) inference fuse expert computation with fine-grained, GPU-initiated communication into a single persistent GPU kernel, and outperform collective-based MoE on a single node by overlapping data transfer with compute at tile granularity. This benefit does not carry over cleanly to multi-node inference, where experts span many nodes connected by an RDMA fabric. Communication-bound MoE models regress by up to 10×10\times on 8 nodes, and the regression worsens with node count. We trace this regression to hidden serialization in proxy-based RDMA transports. The ordering requirement between each tile transfer and its completion signal forces a fence that drains the NIC pipeline, and its cost grows with the number of concurrent transfers. As a result, models whose per-expert compute is too small to absorb this inflated network latency expose communication on the critical path. We present \emph{Perseus}, which eliminates this serialization through two techniques. \emph{Decoupled signaling} batches fences at per-destination granularity, reducing fence count by 8×8\times. \emph{NIC-side ordering} replaces proxy stalls with hardware fence flags, so the proxy never blocks. On proxy-based transports, Perseus achieves up to 10.3×\times end-to-end speedup. Perseus on IBRC matches or exceeds IBGDA GPU-direct by up to 1.2×\times, which shows that serialization, rather than the choice between proxy-based and GPU-direct transport, is what bounds multi-node megakernel performance.

Cite

@article{arxiv.2605.00686,
  title  = {Eliminating Hidden Serialization in Multi-Node Megakernel Communication},
  author = {Byungsoo Oh and Rachee Singh},
  journal= {arXiv preprint arXiv:2605.00686},
  year   = {2026}
}
R2 v1 2026-07-01T12:45:17.137Z