ISBN : 978-1-4244-2748-2International audienceWe propose an automatic instrumentation method for embedded software annotation to enable performance modeling in high level hardware/software co-simulation environments. The proposed ldquocross-annotationrdquo technique consists of extending a retargetable compiler infrastructure to allow the automatic instrumentation of embedded software at the basic block level. Thus, target and annotated native binaries are guaranteed to have isomorphic control flow graphs (CFG). The proposed method takes into account the processor-specific optimizations at the compiler level and proves to be accurate with low simulation overhead
Heterogeneous MPSoC architectures can provide higher performance and flexibility with less power consumption and lower cost than homogeneous ones. However, as processor instruction sets of general heterogeneous MPSoCs are not identical, tasks migration between two heterogeneous processors is not possible. To enable this function, we propose to build one specific heterogeneous MPSoC platform in which all heterogeneous processors are based on the same core instruction set for the operating system realization. Different extended instructions can be added for different processors to improve the system performance. Tasks can be migrated from one processor to another only if the target processor has all instructions which can meet the execution requirement of this task. This paper concentrates on the infrastructure that is necessary to support the scheduling and migration of tasks between the processors. By using the Motion-JPEG case study, we confirm that our task migration framework can achieve higher processor usage rate and more flexibility.
ISBN 978-1-4244-7515-5International audienceAlthough high level simulation models are being increasingly used for digital electronic system validation, cycle accuracy is still required in some cases, such as hardware protocol validation or accurate power/energy estimation. Cycle-accurate simulation is however slow and acceleration approaches make the assumption of a single constant clock, which is not true anymore with the generalization of dynamic voltage and frequency scaling techniques. Fast cycle-accurate simulators supporting several clocks whose frequencies can change at run time are thus needed. This paper presents two algorithms we designed for this purpose and details their properties and implementations
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