Many design optimization methods using machine learning (ML) techniques have been investigated to reduce the number of design iterations in the physical design flow. The demand for big data to… Click to show full abstract
Many design optimization methods using machine learning (ML) techniques have been investigated to reduce the number of design iterations in the physical design flow. The demand for big data to support ML research has been increasing, but the lack of place-and-route (P&R) benchmarks is one of the major problems. We propose a framework to construct realistic P&R benchmarks for use in training ML applications. The framework can organize the P&R database using an artificial netlist generator, which can create any gate-level netlist from user-specified input parameters that represent the topological characteristics of the circuit. We show that a training dataset that contains many artificial gate-level netlists can improve the generalizability of the model to predict the routability for unseen real circuits without using expensive real-world data. Compared to the model that had been trained with real-world circuits, we improved the F1 score in predicting the timing and routing failure by 26.4% and 54.5%, respectively.
               
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