Dynamic IPC/clock rate optimization

Abstract

Current microprocessor designs set the functionality and clock rate of the chip at design time based on the configuration that achieves the best overall performance over a range of target applications. The result may be poor performance when running applications whose requirements are not well-matched to the particular hardware organization chosen. We present a new approach called Complexity-Adaptive Processors (CAPs) in which the IPC/clock rate tradeoff can be altered at runtime to dynamically match the changing requirements of the instruction stream. By exploiting repeater methodologies used increasingly in deep sub-micron designs, CAPs achieve this flexibility with potentially no cycle time impact compared to a fixed architecture. Our preliminary results in applying this approach to on-chip caches and instruction queues indicate that CAPs have the potential to significantly outperform conventional approaches on workloads containing both general-purpose and scientific applications.