A Novel Phase-Based Low Overhead Fault Tolerance Approach for VLIW Processors

Because of technology scaling, the soft error rate has been increasing in digital circuits, which in turn affects system reliability. Therefore, modern processors, including VLIW architectures, must have means to mitigate such effects to guarantee reliable computation. In this scenario, our work proposes two new low overhead fault tolerance approaches, with zero latency detection, that correct soft errors in the pipelines of a configurable VLIW processor. Each approach has a distinct way to detect errors, but they both utilize the same rollback mechanism. The first utilizes redundant hardware by having specialized duplicated pipelines. The second uses idle issue slots to execute duplicated instructions and does this by first identifying phases within an application. Our implementation does not require changes to the binary code and has negligible performance losses. It has 50% of area overhead with 35% power dissipation for the full pipeline duplication, and only 7% of extra area when using idle resources. We compared our approach to related work and demonstrate that we are more efficient when one considers the area, performance, power dissipation and error coverage altogether.