1,681 research outputs found
A Cache Management Strategy to Replace Wear Leveling Techniques for Embedded Flash Memory
Prices of NAND flash memories are falling drastically due to market growth
and fabrication process mastering while research efforts from a technological
point of view in terms of endurance and density are very active. NAND flash
memories are becoming the most important storage media in mobile computing and
tend to be less confined to this area. The major constraint of such a
technology is the limited number of possible erase operations per block which
tend to quickly provoke memory wear out. To cope with this issue,
state-of-the-art solutions implement wear leveling policies to level the wear
out of the memory and so increase its lifetime. These policies are integrated
into the Flash Translation Layer (FTL) and greatly contribute in decreasing the
write performance. In this paper, we propose to reduce the flash memory wear
out problem and improve its performance by absorbing the erase operations
throughout a dual cache system replacing FTL wear leveling and garbage
collection services. We justify this idea by proposing a first performance
evaluation of an exclusively cache based system for embedded flash memories.
Unlike wear leveling schemes, the proposed cache solution reduces the total
number of erase operations reported on the media by absorbing them in the cache
for workloads expressing a minimal global sequential rate.Comment: Ce papier a obtenu le "Best Paper Award" dans le "Computer System
track" nombre de page: 8; International Symposium on Performance Evaluation
of Computer & Telecommunication Systems, La Haye : Netherlands (2011
Flash memory management with cooperation, adaptation and assistance
Ph.DDOCTOR OF PHILOSOPH
Bridging the Gap between Application and Solid-State-Drives
Data storage is one of the important and often critical parts of the computing system in terms of performance, cost, reliability, and energy. Numerous new memory technologies, such as NAND flash, phase change memory (PCM), magnetic RAM (STT-RAM) and Memristor, have emerged recently. Many of them have already entered the production system. Traditional storage optimization and caching algorithms are far from optimal because storage I/Os do not show simple locality. To provide optimal storage we need accurate predictions of I/O behavior. However, the workloads are increasingly dynamic and diverse, making the long and short time I/O prediction challenge. Because of the evolution of the storage technologies and the increasing diversity of workloads, the storage software is becoming more and more complex. For example, Flash Translation Layer (FTL) is added for NAND-flash based Solid State Disks (NAND-SSDs). However, it introduces overhead such as address translation delay and garbage collection costs. There are many recent studies aim to address the overhead. Unfortunately, there is no one-size-fits-all solution due to the variety of workloads. Despite rapidly evolving in storage technologies, the increasing heterogeneity and diversity in machines and workloads coupled with the continued data explosion exacerbate the gap between computing and storage speeds. In this dissertation, we improve the data storage performance from both top-down and bottom-up approach. First, we will investigate exposing the storage level parallelism so that applications can avoid I/O contentions and workloads skew when scheduling the jobs. Second, we will study how architecture aware task scheduling can improve the performance of the application when PCM based NVRAM are equipped. Third, we will develop an I/O correlation aware flash translation layer for NAND-flash based Solid State Disks. Fourth, we will build a DRAM-based correlation aware FTL emulator and study the performance in various filesystems
Dependability Assessment of NAND Flash-memory for Mission-critical Applications
It is a matter of fact that NAND flash memory devices are well established in consumer market. However, it is not true that the same architectures adopted in the consumer market are suitable for mission critical applications like space. In fact, USB flash drives, digital cameras, MP3 players are usually adopted to store "less significant" data which are not changing frequently (e.g., MP3s, pictures, etc.). Therefore, in spite of NAND flash's drawbacks, a modest complexity is usually needed in the logic of commercial flash drives. On the other hand, mission critical applications have different reliability requirements from commercial scenarios. Moreover, they are usually playing in a hostile environment (e.g., the space) which contributes to worsen all the issues. We aim at providing practical valuable guidelines, comparisons and tradeoffs among the huge number of dimensions of fault tolerant methodologies for NAND flash applied to critical environments. We hope that such guidelines will be useful for our ongoing research and for all the interested reader
- …