O2C: occasional two-cycle operations for dynamic thermal management in high performance in-order microprocessors

In this paper, we propose O2C, a novel non-speculative adaptive thermal management technique that reduces the temperature during die-overheating using supply voltage scaling, while maintaining the rated clock frequency. This is accomplished by (a) scaling down the supply voltage, (b) isolating and predicting the set of critical paths, (c) ensuring (by design) that they are activated rarely, and (d) getting around occasional delay failures (at reduced voltage during die-overheating) in these paths by two-cycle operations (assuming all standard operations are single-cycle). Two-cycle operation is achieved by stalling the pipeline for extra clock cycles whenever the set of critical paths are activated. The rare two-cycle operation results in a small decrease in IPC (instructions per cycle). Since called O²C maintains the rated clock frequency and does not require pipeline stalling during supply voltage ramp-up/ramp-down, it achieves high throughput in a thermally constrained environment. We applied called O²C to the integer execution units of an in-order superscalar pipeline. Standard full-chip Dynamic Voltage-Frequency Scaling (DVFS) is very effective in bringing down the temperature, however; it is associated with large throughput loss due to pipeline stalling and slow operating frequency during thermal management. We integrated "O²C with standard DVFS" (called O²C^α) to demonstrate that it can act as a "first step" before full-scale thermal management is required. Our simulations indeed reveal that called O²C^α policy can avoid the requirement of full-scale DVFS during execution of programs.