Abstract
This paper proposes a multiobjective application mapping technique targeted for large-scale network-on-chip (NoC). As the number of intellectual property (IP) cores in multiprocessor system-on-chip (MPSoC) increases, NoC application mapping to find optimum core-to-topology mapping becomes more challenging. Besides, the conflicting cost and performance trade-off makes multiobjective application mapping techniques even more complex. This paper proposes an application mapping technique that incorporates domain knowledge into genetic algorithm (GA). The initial population of GA is initialized with network partitioning (NP) while the crossover operator is guided with knowledge on communication demands. NP reduces the large-scale application mapping complexity and provides GA with a potential mapping search space. The proposed genetic operator is compared with state-of-the-art genetic operators in terms of solution quality. In this work, multiobjective optimization of energy and thermal-balance is considered. Through simulation, knowledge-based initial mapping shows significant improvement in Pareto front compared to random initial mapping that is widely used. The proposed knowledge-based crossover also shows better Pareto front compared to state-of-the-art knowledge-based crossover.
Highlights
The advancement in submicron technology allows more intellectual property (IP) cores to be integrated into a single chip which increases the system complexity
network partitioning (NP)-based initial mapping gives better solution mapping regardless of the genetic operators applied for optimization
This paper presented NP-DKGA that uses network partitioning as initial mapping and multiobjective genetic algorithm with DK crossover for NoC application mapping
Summary
The advancement in submicron technology allows more intellectual property (IP) cores to be integrated into a single chip which increases the system complexity. Without a proper application mapping algorithm, NoC performance may be afflicted with traffic congestion, hotspot, and higher energy consumption. It is an NP-hard problem such that exhaustive algorithms cannot be applied. For large-scale NoC problem, to speed up the convergence and improve the solution quality, a proper initialization method is needed. This paper proposes an application mapping technique that incorporates domain knowledge into genetic algorithm (NP-DKGA) to minimize the energy consumption and obtain thermal balance on NoC. The first phase is to perform k-way partitioning of a large MPSoC application to map all the cores into assigned partitions in the mesh-based network as the knowledge-based initial population.
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