DeCoR: A Delayed Commit and Rollback mechanism for handling inductive noise in processors

Abstract: Increases in peak current draw and reductions in the operating voltage of processors stress the importance of dealing with voltage fluctuations in processors. Noise-margin violations lead to undesired effects, like timing violations, which may result in incorrect execution of applications. Several recent architectural solutions for inductive noise have been proposed that, unfortunately, have a strong correlation to the underlying power-delivery package model and require a feedback loop that is largely constrai… Show more

“…It allows for coarser and simpler detection mechanisms, but requires more sophisticated recovery support due to longer detection latencies. We base the remainder of our discussion on a previous proposal by Gupta et al for CPUs [17]. They divide processors into rollback protected and timing-margin protected regions, using both a re-order buffer and store queue to recover from voltage mis-speculation only in the rollback protected regions (pipeline regions).…”

“…In traditional CPUs, speculation recovery support is used for multiple purposes ranging from out-of-order execution [38] and branch prediction [42], to hardware fault recovery [30] and circuit-level speculation [17]. However, modern GPUs implement simple, in-order cores to maximize throughput, and hence have little or no hardware support for speculative execution.…”

“…As a concrete example, this section focuses specifically on the iGPU mechanisms to support speculative circuitlevel techniques, which have received much attention in recent years [3,8,12,16,17,31]. These circuit-level techniques speculatively assume common-case timing and voltage conditions, with occasional recovery employed under worst-case conditions.…”

“…However, we argue that even with a 1 The compiler region formation is an IR-level analysis that does not directly modify generated device code and hence incurs no overhead. DeCoR [17] 1% 10% Emergency Prediction [31] 0.01% 10% Razor [12] 1% 15% Razor II [8] 0.1% 15% Table 2: Circuit speculation techniques and their corresponding error rate and V dd reduction (approximate).…”

“…Shortly after the development of exception support in CPUs, speculation was developed as a mechanism to transparently handle "difficult" code, and a recent study claims that GPUs must similarly begin incorporating techniques like speculation to expand the domains they can target [6]. Speculation support has also increasingly been proposed for handling recovery from hardware reliability problems in CPUs [4,17,30]. Such problems, which include variability, noise, and excessive guard-banding, are also emerging problems for GPUs [7].…”

iGPU: Exception support and speculative execution on GPUs

“…It allows for coarser and simpler detection mechanisms, but requires more sophisticated recovery support due to longer detection latencies. We base the remainder of our discussion on a previous proposal by Gupta et al for CPUs [17]. They divide processors into rollback protected and timing-margin protected regions, using both a re-order buffer and store queue to recover from voltage mis-speculation only in the rollback protected regions (pipeline regions).…”

“…In traditional CPUs, speculation recovery support is used for multiple purposes ranging from out-of-order execution [38] and branch prediction [42], to hardware fault recovery [30] and circuit-level speculation [17]. However, modern GPUs implement simple, in-order cores to maximize throughput, and hence have little or no hardware support for speculative execution.…”

“…As a concrete example, this section focuses specifically on the iGPU mechanisms to support speculative circuitlevel techniques, which have received much attention in recent years [3,8,12,16,17,31]. These circuit-level techniques speculatively assume common-case timing and voltage conditions, with occasional recovery employed under worst-case conditions.…”

“…However, we argue that even with a 1 The compiler region formation is an IR-level analysis that does not directly modify generated device code and hence incurs no overhead. DeCoR [17] 1% 10% Emergency Prediction [31] 0.01% 10% Razor [12] 1% 15% Razor II [8] 0.1% 15% Table 2: Circuit speculation techniques and their corresponding error rate and V dd reduction (approximate).…”

“…Shortly after the development of exception support in CPUs, speculation was developed as a mechanism to transparently handle "difficult" code, and a recent study claims that GPUs must similarly begin incorporating techniques like speculation to expand the domains they can target [6]. Speculation support has also increasingly been proposed for handling recovery from hardware reliability problems in CPUs [4,17,30]. Such problems, which include variability, noise, and excessive guard-banding, are also emerging problems for GPUs [7].…”

iGPU: Exception support and speculative execution on GPUs

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