TY - GEN
T1 - Shedding the Shackles of Time-Division Multiplexing
AU - Hebbache, Farouk
AU - Jan, Mathieu
AU - Brandner, Florian
AU - Pautet, Laurent
N1 - Publisher Copyright:
© 2018 IEEE.
PY - 2019/1/4
Y1 - 2019/1/4
N2 - Multi-core architectures pose many challenges in real-time systems, which arise from contention between concurrent accesses to shared memory. Among the available memory arbitration policies, Time Division Multiplexing (TDM) ensures a predictable behavior by bounding access latencies and guaranteed bandwidth to tasks independently from the other tasks. To do so, TDM guarantees exclusive access to the shared memory in a fixed time window. TDM, however, provides a low resource utilization as it is non-work-conserving. Besides, it is very inefficient for resources having highly variable latencies, such as sharing the access to a DRAM memory. The constant length of a TDM slot is, hence, highly pessimistic and causes an underutilization of the memory. To address these limitations, we present dynamic arbitration schemes that are based on TDM. However, instead of arbitrating at the level of TDM slots, our approach operates at the granularity of clock cycles by exploiting slack time accumulated from preceding requests. This allows the arbiter to reorder memory requests, exploit the actual access latencies of requests, and thus improve memory utilization. We demonstrate that our policies are analyzable as they preserve the guarantees of TDM in the worst case, while our experiments show an improved memory utilization on average.
AB - Multi-core architectures pose many challenges in real-time systems, which arise from contention between concurrent accesses to shared memory. Among the available memory arbitration policies, Time Division Multiplexing (TDM) ensures a predictable behavior by bounding access latencies and guaranteed bandwidth to tasks independently from the other tasks. To do so, TDM guarantees exclusive access to the shared memory in a fixed time window. TDM, however, provides a low resource utilization as it is non-work-conserving. Besides, it is very inefficient for resources having highly variable latencies, such as sharing the access to a DRAM memory. The constant length of a TDM slot is, hence, highly pessimistic and causes an underutilization of the memory. To address these limitations, we present dynamic arbitration schemes that are based on TDM. However, instead of arbitrating at the level of TDM slots, our approach operates at the granularity of clock cycles by exploiting slack time accumulated from preceding requests. This allows the arbiter to reorder memory requests, exploit the actual access latencies of requests, and thus improve memory utilization. We demonstrate that our policies are analyzable as they preserve the guarantees of TDM in the worst case, while our experiments show an improved memory utilization on average.
KW - Dynamic Arbitration
KW - Mixed-Criticality Systems
KW - Predictable Computing
KW - Time-Division Multiplexing
U2 - 10.1109/RTSS.2018.00059
DO - 10.1109/RTSS.2018.00059
M3 - Conference contribution
AN - SCOPUS:85061530791
T3 - Proceedings - Real-Time Systems Symposium
SP - 456
EP - 468
BT - Proceedings - 39th IEEE Real-Time Systems Symposium, RTSS 2018
PB - Institute of Electrical and Electronics Engineers Inc.
T2 - 39th IEEE Real-Time Systems Symposium, RTSS 2018
Y2 - 11 December 2018 through 14 December 2018
ER -