Litcius/Paper detail

HMG: Extending Cache Coherence Protocols Across Modern Hierarchical Multi-GPU Systems

Xiaowei Ren, Daniel Lustig, Evgeny Bolotin, Aamer Jaleel, Oreste Villa, David Nellans

202035 citationsDOI

Abstract

Prior work on GPU cache coherence has shown that simple hardware-or software-based protocols can be more than sufficient. However, in recent years, features such as multi-chip modules have added deeper hierarchy and non-uniformity into GPU memory systems. GPU programming models have chosen to expose this non-uniformity directly to the end user through scoped memory consistency models. As a result, there is room to improve upon earlier coherence protocols that were designed only for flat single-GPU hierarchies and/or simpler memory consistency models. In this paper, we propose HMG, a cache coherence protocol designed for forward-looking multi-GPU systems. HMG strikes a balance between simplicity and performance: it uses a readily-implementable VI-like protocol to track coherence states, but it tracks sharers using a hierarchical scheme optimized for mitigating the bandwidth limitations of inter-GPU links. HMG leverages the novel scoped, non-multi-copy-atomic properties of modern GPU memory models, and it avoids the overheads of invalidation acknowledgments and transient states that were needed to support prior GPU memory models. On a 4-GPU system, HMG improves performance over a software-controlled, bulk invalidation-based coherence mechanism by 26% and over a non-hierarchical hardware cache coherence protocol by 18%, thereby achieving 97% of the performance of an idealized caching system.

Topics & Concepts

Computer scienceCache coherenceMemory hierarchyParallel computingProtocol (science)CacheCUDAMESI protocolCoherence (philosophical gambling strategy)SoftwareShared memoryConsistency modelConsistency (knowledge bases)ScalabilityDistributed computingCPU cacheCache algorithmsOperating systemData consistencyQuantum mechanicsMedicineAlternative medicinePhysicsArtificial intelligencePathologyParallel Computing and Optimization TechniquesFerroelectric and Negative Capacitance DevicesAdvanced Data Storage Technologies