Writeback-aware bandwidth partitioning for multi-core systems with PCM

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Phase-Change Memory (PCM) has emerged as a promising low-power candidate to replace DRAM in main memory. Hybrid memory architecture comprised of a large PCM and a small DRAM is a popular solution to mitigate undesirable characteristics of PCM writes. Because PCM writes are much slower than reads, writebacks from the last-level cache consume a large portion of memory bandwidth, and thus, impact performance. Effectively utilizing shared resources, such as the last-level cache and the memory bandwidth, is crucial to achieving high performance for multi-core systems. Although existing memory bandwidth allocation schemes improve system performance, no current approach uses writeback information to partition bandwidth for hybrid memory. We use a writeback-aware analytic model to derive the allocation strategy for bandwidth partitioning of phase-change memory. From the derivation of the model, Writeback-aware Bandwidth Partitioning (WBP) is proposed as a new runtime mechanism to partition PCM service cycles among applications. WBP uses a partitioning weight to indicate the importance of writebacks (in addition to LLC misses) to bandwidth allocation. A companion Dynamic Weight Adjustment (DWA) scheme dynamically selects the partitioning weight to maximize system performance. Simulation results show that WBP and DWA improve performance by 24.9% (weighted speedup) over bandwidth partitioning schemes that do not take writebacks into consideration in a 8-core system.