Abstract-Application-specific multiprocessor systems-on-chip (MPSoCs) are usually designed by using a platform-based approach, where a wide range of customizable parameters can be tuned to find the best tradeoff in terms of the selected figures of merit (such as energy, delay, and area). This optimization phase is called design space exploration (DSE), and it usually consists of a multiobjective optimization problem with multiple constraints. So far, several heuristic techniques have been proposed to address the DSE problem for MPSoC, but they are not efficient enough for managing the application-specific constraints and for identifying the Pareto front. In this paper, an efficient DSE methodology for application-specific MPSoC is proposed. The methodology is efficient in the sense that it is capable of finding a set of good candidate architecture configurations by minimizing the number of simulations to be executed. The methodology combines the design of experiments (DoEs) and response surface modeling (RSM) techniques for managing system-level constraints. First, the DoE phase generates an initial plan of experiments used to create a coarse view of the target design space to be explored by simulations. Then, a set of RSM techniques is used to refine the simulation-based exploration by exploiting the application-specific constraints to identify the maximum number of feasible solutions. To trade off the accuracy and efficiency of the proposed techniques, a set of experimental results for the customization of a symmetric shared-memory on-chip multiprocessor with actual workloads has been reported in this paper.
Abstract. The evaluation of the best system-level architecture in terms of energy and performance is of mainly importance for a broad range of embedded SOC platforms. In this paper, we address the problem of the efficient exploration of the architectural design space for parameterized microprocessor-based systems. The architectural design space is multi-objective, so our aim is to find all the Pareto-optimal configurations representing the best power-performance design trade-offs by varying the architectural parameters of the target system. In particular, the paper presents a Design Space Exploration (DSE) framework tuned to efficiently derive Pareto-optimal curves. The main characteristics of the proposed framework consist of its flexibility and modularity, mainly in terms of target architecture, related system-level executable models, exploration algorithms and system-level metrics. The analysis of the proposed framework has been carried out for a parameterized superscalar architecture executing a selected set of benchmarks. The reported results have shown a reduction of the simulation time of up to three orders of magnitude with respect to the full search strategy, while maintaining a good level of accuracy (under 4% on average).
Technology trends enable the integration of many processor cores in a System-on-Chip (SoC). In these complex architectures, several architectural parameters can be tuned to find the best trade-off in terms of multiple metrics such as energy and delay. The main goal of the MULTICUBE project consists of the definition of an automatic Design Space Exploration framework to support the design of next generation many-core architectures 1 .
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