The Performance Vulnerability of Architectural and Non-architectural Arrays to Permanent Faults

Hardy, Damien; Sideris, Isidoros; Ladas, Nikolas; Sazeides, Yiannakis

doi:10.1109/micro.2012.14

Cited by 20 publications

(15 citation statements)

References 35 publications

(62 reference statements)

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“…The impact of faults on software timing was studied in a series of research papers [6], [18], [7]. Paper [6] addresses the impact of permanent faults and disabling of resources on application performance for non real-time applications. They concentrate on average-case performance instead of worstcase performance, and do not propose any additional hardware to limit the impact of faults on performance.…”

Section: Related Workmentioning

confidence: 99%

“…We are going to enter a new era: functionally correct chips with variable performance among a population of chips, and with varying performance over time resulting from aging. A recent study [6] has analyzed the effect of fine-grained disabling resulting from permanent faults on average performance. It reveals that caches, which take most of the die real-estate in current processors and contain numerous SRAM cells, will be a non-negligible source of performance degradation in the near future.…”

Section: Introductionmentioning

confidence: 99%

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Probabilistic WCET Estimation in Presence of Hardware for Mitigating the Impact of Permanent Faults

Hardy¹,

Puaut²,

Sazeides³

2016

Proceedings of the 2016 Design, Automation &Amp; Test in Europe Conference &Amp; Exhibition (DATE)

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Fine-grained disabling and reconfiguration of hardware elements (functional units, cache blocks) will become economically necessary to recover from permanent failures, whose rate is expected to increase dramatically in the near future. This fine-grained disabling will lead to degraded performance as compared to a fault-free execution. Until recently, all static worst-case execution time (WCET) estimations methods were assuming fault-free processors, resulting in unsafe estimates in the presence of faults. The first static WCET estimation technique dealing with the presence of permanent faults in instruction caches was proposed in [1]. This study probabilistically quantified the impact of permanent faults on WCET estimates. It demonstrated that the probabilistic WCET (pWCET) estimates of tasks increase rapidly with the probability of faults as compared to fault-free WCET estimates. In this paper, we show that very simple reliability mechanisms allow mitigating the impact of faulty cache blocks on pWCETs. Two mechanisms, that make part of the cache resilient to faults are analyzed. Experiments show that the gain in pWCET for these two mechanisms are on average 48% and 40% as compared to an architecture with no reliability mechanism.

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Section: Related Workmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Probabilistic WCET Estimation in Presence of Hardware for Mitigating the Impact of Permanent Faults

Hardy¹,

Puaut²,

Sazeides³

2016

Proceedings of the 2016 Design, Automation &Amp; Test in Europe Conference &Amp; Exhibition (DATE)

Self Cite

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show abstract

“…The study presented in [12] addresses this issue for non real-time applications. They assume the same fault model as in our method, but concentrate on average-case performance, whereas our focus here is on real-time applications and worst-case performance.…”

Section: Related Workmentioning

confidence: 99%

“…We are going to enter in a new era: functionally correct chips with variable performance from the time they are shipped. A recent study [12] has analyzed the effect of fine grain disabling resulting from permanent faults on average performance. It reveals that caches, which take most of die real-estate in current processors and contain numerous SRAM cells, will be a non-negligible source of performance degradation in the near future.…”

Section: Introductionmentioning

confidence: 99%

Static probabilistic worst case execution time estimation for architectures with faulty instruction caches

Hardy

Puaut²

2014

Real-Time Syst

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Semiconductor technology evolution suggests that permanent failure rates will increase dramatically with scaling, in particular for SRAM cells. While well known approaches such as error correcting codes exist to recover from failures and provide fault-free chips, they will not be affordable anymore in the future due to their non-scalable cost. Consequently, other approaches like fine grain disabling and reconfiguration of hardware elements (e.g. individual functional units or cache blocks) will become economically necessary. This fine-grain disabling will lead to degraded performance compared to a fault-free execution. To the best of our knowledge, all static worst-case execution time (WCET) estimation methods assume fault-free architectures. Their result is not safe anymore when using fine grain disabling of hardware components, which degrades performance. In this paper we provide the first method that statically calculates a probabilistic WCET bound in the presence of permanent faults in instruction caches. The proposed method, from a given program, cache configuration and probability of cell failure, derives a probabilistic WCET bound. The proposed method, because it relies on static analysis, is guaranteed to identify the longest program path, its probabilistic nature only stemming from the presence of faults. The method is computationally tractable because it does not require an exhaustive enumeration of the possible locations of faulty cache blocks. Experimental results show that it provides WCET estimates very close to, but never below, the method that derives probabilistic WCETs by enumerating all possible locations of faulty cache blocks. The proposed method not only allows to quantify the impact of permanent faults on WCET estimates, but also can be used in architectural exploration frameworks to select the most appropriate fault management mechanisms.

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“…One challenge for analyzing fault mitigation techniques is the large set of required simulations. Running all workloads and simulated models combinations for a single fault map can lead to wrong results, as other authors have described [32,33]. For example, if all the faults affect to the most/least frequently accessed cache sets, the observed speed-up would be much lower/higher than in reality.…”

mentioning

confidence: 98%

A fault-tolerant last level cache for CMPs operating at ultra-low voltage

Ferrerón

Alastruey-Benedé

Gracia

et al. 2019

Journal of Parallel and Distributed Computing

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The Performance Vulnerability of Architectural and Non-architectural Arrays to Permanent Faults

Cited by 20 publications

References 35 publications

Probabilistic WCET Estimation in Presence of Hardware for Mitigating the Impact of Permanent Faults

Probabilistic WCET Estimation in Presence of Hardware for Mitigating the Impact of Permanent Faults

Static probabilistic worst case execution time estimation for architectures with faulty instruction caches

A fault-tolerant last level cache for CMPs operating at ultra-low voltage

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