Coherence controller architectures for scalable shared-memory multiprocessors

Scalable distributed shared-memory architectures rely on coherence controllers on each processing node to synthesize cache-coherent shared memory across the entire machine. The coherence controllers execute coherence protocol handlers that may be hardwired in custom hardware or programmed in a protocol processor within each coherence controller. Although custom hardware runs faster, a protocol processor allows the coherence protocol to be tailored to specific application needs and may shorten hardware development time. Previous research shows minimal increase in application execution time due to protocol processors over custom hardware. With the advent of SMP nodes and faster processors and networks, the trade-off between custom hardware and protocol processors needs to be reexamined. This paper studies the performance of custom hardware and protocol-processor-based coherence controllers in SMP-node-based CC-NUMA systems on applications from the SPLASH-2 suite. Using realistic parameters and detailed models of state-of-the-art system components, it shows that the occupancy of coherence controllers can limit the performance of applications with high communication requirements, where the execution time using commodity protocol processors can be twice as long as using custom hardware. We also investigate the effect of varying several architectural parameters that influence the communication characteristics of the applications and the underlying system on coherence controller performance. We identify measures of applications´ communication requirements and their impact on performance. We also study the potential of improving the performance of coherence controllers by separating or duplicating critical components