In modern Commercial Off-The-Shelf (COTS) multicore systems, each core can
generate many parallel memory requests at a time. The processing of these
parallel requests in the DRAM controller greatly affects the memory
interference delay experienced by running tasks on the platform. In this paper,
we model a modern COTS multicore system which has a nonblocking last-level
cache (LLC) and a DRAM controller that prioritizes reads over writes. To
minimize interference, we focus on LLC and DRAM bank partitioned systems. Based
on the model, we propose an analysis that computes a safe upper bound for the
worst-case memory interference delay. We validated our analysis on a real COTS
multicore platform with a set of carefully designed synthetic benchmarks as
well as SPEC2006 benchmarks. Evaluation results show that our analysis is more
accurately capture the worst-case memory interference delay and provides safer
upper bounds compared to a recently proposed analysis which significantly
under-estimate the delay.Comment: Technical Repor