On Improving Optimization Effectiveness In Interconnect-Driven Physical Synthesis

In modern designs, the delay of a net can vary significantly depending on its routing. This large estimation error during the pre-routing stage can often mislead the optimization of the netlist. We extend state-of-the-art interconnect-driven physical synthesis by introducing a new paradigm (namely, persistence) that relies on guaranteed net routes for the most sensitive nets while performing circuit optimization in the pre-route stage. We implemented our proposed approach in a cutting-edge industrial physical synthesis flow; this involved the automatic identification and routing of critical nets that were likely to be mispredicted, the automatic update of their routes during the subsequent pre-routing stage optimizations, and the guaranteed retention of their routes across the routing stage. Our approach achieves significant performance improvements on a suite of real-world 65nm designs, while ensuring that the impact on their mutability remains negligible. Furthermore, our experimental results scale very well with design size.