TY - GEN
T1 - Enhancing Static Task Scheduling for Pipelined Cyclic Executions on Heterogeneous Architectures
AU - Hollmann, Jonas
AU - Arndt, Jakob
AU - Kyriakopoulos, Ioannis
AU - Friedrich, Martin
AU - Blume, Holger
N1 - Publisher Copyright:
© 2025 IEEE.
PY - 2025/12/15
Y1 - 2025/12/15
N2 - Along with the increase in software complexity comes an increasing number of heterogeneous hardware systems, even in real-time safety-critical embedded systems. Programming these heterogeneous systems optimally with respect to resource utilization and overall latency poses a considerable challenge for the developers, and the limited resources in embedded systems only complicate matters. Static scheduling is a promising prospect for maximizing the safety compliance of the final schedule. In earlier work, we have shown that the static scheduling methods found in the literature are capable of calculating near-optimal schedules quickly using a theoretical graph representation of the software. These methods do, however, only schedule a single execution for minimum latency. In environments where the same software is executed continuously, pipelining subsequent executions can often lead to higher throughput. In this paper, we present a novel methodology leveraging known scheduling algorithms to calculate pipelined executions with higher throughput. We propose a model extension that interleaves frames of execution in the same graph in order to utilize parallelism and pipelining effects, and use this extended model to increase the throughput by up to 29.77 %. This method relies on a computationally hard-to-find cut through the graph representation. As such, we further present an approach to reduce the complexity of the problem and approximate the optimum with an error of only 6.3% in 4.7% of the runtime.
AB - Along with the increase in software complexity comes an increasing number of heterogeneous hardware systems, even in real-time safety-critical embedded systems. Programming these heterogeneous systems optimally with respect to resource utilization and overall latency poses a considerable challenge for the developers, and the limited resources in embedded systems only complicate matters. Static scheduling is a promising prospect for maximizing the safety compliance of the final schedule. In earlier work, we have shown that the static scheduling methods found in the literature are capable of calculating near-optimal schedules quickly using a theoretical graph representation of the software. These methods do, however, only schedule a single execution for minimum latency. In environments where the same software is executed continuously, pipelining subsequent executions can often lead to higher throughput. In this paper, we present a novel methodology leveraging known scheduling algorithms to calculate pipelined executions with higher throughput. We propose a model extension that interleaves frames of execution in the same graph in order to utilize parallelism and pipelining effects, and use this extended model to increase the throughput by up to 29.77 %. This method relies on a computationally hard-to-find cut through the graph representation. As such, we further present an approach to reduce the complexity of the problem and approximate the optimum with an error of only 6.3% in 4.7% of the runtime.
KW - heterogeneous safety-critical embedded systems
KW - periodic task scheduling
KW - pipelining
KW - task graph reduction
KW - task scheduling
UR - http://www.scopus.com/inward/record.url?scp=105032422800&partnerID=8YFLogxK
U2 - 10.1109/MCSoC67473.2025.00012
DO - 10.1109/MCSoC67473.2025.00012
M3 - Conference contribution
AN - SCOPUS:105032422800
SN - 979-8-3315-6572-5
T3 - IEEE International Symposium on Embedded Multicore/Many-core Systems-on-Chip, MCSoC
SP - 1
EP - 8
BT - Proceedings - 2025 IEEE 18th International Symposium on Embedded Multicore/Many-core Systems-on-Chip, MCSoC 2025
PB - Institute of Electrical and Electronics Engineers Inc.
T2 - 18th International Symposium on Embedded Multicore/Many-core Systems-on-Chip, MCSoC 2025
Y2 - 15 December 2025 through 18 December 2025
ER -