English

Iris: First-Class Multi-GPU Programming Experience in Triton

Distributed, Parallel, and Cluster Computing 2025-11-18 v1 Machine Learning

Abstract

Multi-GPU programming traditionally requires developers to navigate complex trade-offs between performance and programmability. High-performance implementations typically rely on low-level HIP/CUDA communication libraries that demand substantial engineering effort for even basic overlap patterns, while simpler abstractions often sacrifice performance. We present Iris, a multi-GPU communication library implemented entirely in Python and Triton that eliminates this trade-off. Iris provides tile-based symmetric memory abstractions that naturally align with Triton's programming model, enabling developers to write single-source kernels that seamlessly interleave computation and communication. We demonstrate a taxonomy of compute-communication overlap patterns--from bulk-synchronous to fine-grained workgroup specialization--that can be implemented with minimal code changes in Iris, often requiring just a few additional lines within the same Triton kernel. Our evaluation shows that Iris achieves near-optimal bandwidth utilization in microbenchmarks and delivers up to 1.79x speedup over PyTorch and RCCL for GEMM+All-Scatter workloads, demonstrating that high-level implementations can match or exceed heavily-optimized libraries while dramatically simplifying multi-GPU programming.

Keywords

Cite

@article{arxiv.2511.12500,
  title  = {Iris: First-Class Multi-GPU Programming Experience in Triton},
  author = {Muhammad Awad and Muhammad Osama and Brandon Potter},
  journal= {arXiv preprint arXiv:2511.12500},
  year   = {2025}
}
R2 v1 2026-07-01T07:39:35.939Z