http://www.cs.rochester.edu/~kshen/papers/usenix2010-li.pdf

Abstract

Memory hardware reliability is an indispensable part of whole-system dependability. This paper presents the collection of realistic memory hardware error traces (including transient and non-transient errors) from production computer systems with more than 800 GB memory for around nine months. Detailed information on the error addresses allows us to identify patterns of single-bit, row, column, and whole-chip memory errors. Based on the collected traces, we explore the implications of different hardware ECC protection schemes so as to identify the most common error causes and approximate error rates exposed to the software level. Further, we investigate the software system susceptibility to major error causes, with the goal of validating, questioning, and augmenting results of prior studies. In particular, we find that the earlier result that most memory hardware errors do not lead to incorrect software execution may not be valid, due to the unrealistic model of exclusive transient errors. Our study is based on an effi- cient memory error injection approach that applies hardware watchpoints on hotspot memory regions.

 

1 Introduction

Memory hardware errors are an important threat to computer system reliability [37] as VLSI technologies continue to scale [6]. Past case studies [27,38] suggested that these errors are significant contributing factors to whole-system failures. Managing memory hardware errors is an important component in developing an overall system dependability strategy. Recent software system studies have attempted to examine the impact of memory hardware errors on computer system reliability [11, 26] and security [14]. Software system countermeasures to these errors have also been investigated [31]. Despite its importance, our collective understanding about the rate, pattern, impact, and scaling trends of

memory hardware errors is still somewhat fragmented and incomplete. The lack of knowledge on realistic errors has forced failure analysis researchers to use synthetic error models that have not been validated [11, 14, 24, 26, 31]. Without a good understanding, it is tempting for software developers in the field to attribute (often falsely) non-deterministic system failures or rare performance anomalies [36] to hardware errors. On the other hand, anecdotal evidence suggests that these errors are being encountered in the field. For example, we were able to follow a Rochester student’s failure report and identify a memory hardware error on a medical Systemon-Chip platform (Microchip PIC18F452). The faulty chip was used to monitor heart rate of neonates and it reported mysterious (and alarming) heart rate drops. Using an in-circuit debugger, we found the failure was caused by a memory bit (in the SRAM’s 23rd byte) stuck at ‘1’.

 

 

@w

In an effort to acquire valuable error statistics in realworld environments, we have monitored memory hardware errors in three groups of computers—specifically, a rack-mounted Internet server farm with more than 200 machines, about 20 university desktops, and 70 PlanetLab machines. We have collected error tracking results on over 800 GB memory for around nine months. Our error traces are available on the web [34]. As far as we know, they are the first (and so far only) publicly available memory hardware error traces with detailed error addresses and patterns.

 

One important discovery from our error traces is that non-transient errors are at least as significant a source of reliability concern as transient errors. In theory, permanent hardware errors, whose symptoms persist over

time, are easier to detect. Consequently they ought to present only a minimum threat to system reliability in an ideally-maintained environment. However, some nontransient errors are intermittent [10] (i.e., whose symptoms are unstable at times) and they are not necessarily easy to detect. Further, the system maintenance is hardly perfect, particularly for hardware errors that do not trigger obvious system failures. Given our discovery of nontransient errors in real-world production systems, a holistic dependability strategy needs to take into account their presence and error characteristics.

 

We conduct trace-driven studies to understand hardware error manifestations and their impact on the software system. First, we extrapolate the collected traces into general statistical error manifestation patterns. We then perform Monte Carlo simulations to learn the error rate and particularly error causes under different memory protection mechanisms (e.g., single-error-correcting ECC or stronger Chipkill ECC [12]). To achieve high confidence, we also study the sensitivity of our results to key parameters of our simulation model.

Further, we use a virtual machine-based error injection approach to study the error susceptibility of real software systems and applications. In particular, we discovered the previous conclusion that most memory hardware errors do not lead to incorrect software execution [11,26] is inappropriate for non-transient memory errors. We also validated the failure oblivious computing model [33] using our web server workload with injected non-transient errors.

 

2 Background

2.1 Terminology

In general, a fault is the cause of an error, and errors lead to service failures [23]. Precisely defining these terms (“fault”, “error”, and “failure”), however, can be “surprisingly difficult” [2], as it depends on the notion of the system and its boundaries. For instance, the consequence of reading from a defective memory cell (obtaining an erroneous result) can be considered as a failure of the memory subsystem, an error in the broader computer system, or it may not lead to any failure of the computer system at all if it is masked by subsequent processing. In our discussion, we use error to refer to the incidence of having incorrect memory content. The root cause of an error is the fault, which can be a particle impact, or defects in some part of the memory circuit. Note that an error does not manifest (i.e., it is a latent error) until the corrupt location is accessed.

An error may involve more than a single bit. Specifically, we count all incorrect bits due to the same root cause as part of one error. This is different from the con

cept of a multi-bit error in the ECC context, in which case the multiple incorrect bits must fall into a single ECC word. To avoid confusions we call these errors wordwise multi-bit instead.

 

Transient memory errors are those that do not persist and are correctable by software overwrites or hardware scrubbing. They are usually caused by temporary environmental factors such as particle strikes from radioactive decay and cosmic ray-induced neutrons. Nontransient errors, on the other hand, are often caused (at least partially) by inherent manufacturing defect, insuf- ficient burn-in, or device aging [6]. Once they manifest, they tend to cause more predictable errors as the deterioration is often irreversible. However, before transitioning into permanent errors, they may put the device into a marginal state causing apparently intermittent errors.