Inter-GPU communication has become a major bottleneck for modern AI workloads as models scale and improvements in hardware compute throughput outpace improvements in interconnect bandwidth. Existing systems mitigate this through compute-communication overlap but often fail to meet theoretical peak performance across heterogeneous workloads and new accelerators. Instead of operator-specific techniques, we ask whether a small set of simple, reusable principles can systematically guide the design of optimal multi-GPU kernels. We present ParallelKittens (PK), a minimal CUDA framework that drastically simplifies the development of overlapped multi-GPU kernels. PK extends the ThunderKittens framework and embodies the principles of multi-GPU kernel design through eight core primitives and a unified programming template, derived from a comprehensive analysis of the factors that govern multi-GPU performance\unicodex2014data-transfer mechanisms, resource scheduling, and design overheads. We validate PK on both Hopper and Blackwell architectures. With fewer than 50 lines of device code, PK achieves up to 2.33× speedup for data- and tensor-parallel workloads, 4.08× for sequence-parallel workloads, and 1.22× for expert-parallel workloads.
@article{arxiv.2511.13940,
title = {ParallelKittens: Systematic and Practical Simplification of Multi-GPU AI Kernels},
author = {Stuart H. Sul and Simran Arora and Benjamin F. Spector and Christopher Ré},
journal= {arXiv preprint arXiv:2511.13940},
year = {2025}
}