English

WaferLLM: Large Language Model Inference at Wafer Scale

Machine Learning 2025-06-02 v3 Artificial Intelligence Hardware Architecture Distributed, Parallel, and Cluster Computing Emerging Technologies

Abstract

Emerging AI accelerators increasingly adopt wafer-scale manufacturing technologies, integrating hundreds of thousands of AI cores in a mesh architecture with large distributed on-chip memory (tens of GB in total) and ultra-high on-chip memory bandwidth (tens of PB/s). However, current LLM inference systems, optimized for shared memory architectures like GPUs, fail to exploit these accelerators fully. We introduce WaferLLM, the first wafer-scale LLM inference system. WaferLLM is guided by a novel PLMR model (pronounced as "Plummer") that captures the unique hardware characteristics of wafer-scale architectures. Leveraging this model, WaferLLM pioneers wafer-scale LLM parallelism, optimizing the utilization of hundreds of thousands of on-chip cores. It also introduces MeshGEMM and MeshGEMV, the first GEMM and GEMV implementations designed to scale effectively on wafer-scale accelerators. Evaluations show that WaferLLM achieves up to 200×\times higher accelerator utilization than state-of-the-art methods. Leveraging a wafer-scale accelerator (Cerebras WSE2), WaferLLM delivers GEMV operations 606×\times faster and 16×\times more energy-efficient than on an NVIDIA A100 GPU. For full LLM inference, WaferLLM achieves 10-20×\times speedups over A100 GPU clusters running SGLang and vLLM. These advantages are expected to grow as wafer-scale AI models, software, and hardware continue to mature. WaferLLM is open-sourced at https://github.com/MeshInfra/WaferLLM.

Keywords

Cite

@article{arxiv.2502.04563,
  title  = {WaferLLM: Large Language Model Inference at Wafer Scale},
  author = {Congjie He and Yeqi Huang and Pei Mu and Ziming Miao and Jilong Xue and Lingxiao Ma and Fan Yang and Luo Mai},
  journal= {arXiv preprint arXiv:2502.04563},
  year   = {2025}
}
R2 v1 2026-06-28T21:35:34.491Z