NAND flash memories are becoming the predominant technology in the implementation of mass storage systems for both embedded and high-performance applications. However, when considering data and code storage in non-volatile memories (NVMs), such as NAND flash memories, reliability and performance become a serious concern for systems’ designer. Designing NAND flash based systems based on worst-case scenarios leads to waste of resources in terms of performance, power consumption, and storage capacity. This is clearly in contrast with the request for run-time reconfigurability, adaptivity, and resource optimization in nowadays computing systems. There is a clear trend toward supporting differentiated access modes in flash memory controllers, each one setting a differentiated trade-off point in the performance-reliability optimization space. This is supported by the possibility of tuning the NAND flash memory performance, reliability and power consumption acting on several tuning knobs such as the flash programming algorithm and the flash error correcting code. However, to successfully exploit these degrees of freedom, it is mandatory to clearly understand the effect the combined tuning of these parameters have on the full NVM sub-system. This paper performs a comprehensive quantitative analysis of the benefits provided by the run-time reconfigurability of an MLC NAND flash controller through the combined effect of an adaptable memory programming circuitry coupled with run-time adaptation of the ECC correction capability. The full nonvolatile memory (NVM) sub-system is taken into account, starting from the characterization of the low level circuitry to the effect of the adaptation on a wide set of realistic benchmarks in order to provide the readers a clear figure of the benefit this combined adaptation would provide at the system level
Solid State Drives (SSDs) are gaining particular momentum in various frameworks such as multimedia, large data centers and cloud environments. Unfortunately, efficient CAD tools for SSD design space exploration able to assess the optimization of the device microarchitecture w.r.t. the target performance are still missing. This paper tries to close this gap by proposing SSDExplorer, a tool for fine-grained and fast design space exploration of SSD devices. SSDExplorer provides unprecedented insights into the architecture behavior and subcomponent interaction efficiency, while avoiding the need for the actual implementation of an FTL or of key hardware components. This is achieved by the introduction of suitable abstractions of the different components. This is confirmed by the thorough validation of SSDExplorer against a commercial SSD device
FPGAs achieve smaller geometries and their reliability is becoming a severe issue. Non-functional properties, as Negative Bias Temperature Instability, affect the device functionality. In this work a novel methodology to address this issue is described, exploiting FPGAs flexibility. Dynamic Partial Reconfiguration is used to minimize aging impact on FPGAs' configuration memory.
Solid State Drives (SSDs) are gaining particular momentum in various frameworks such as multimedia, large data centers and cloud environments. Unfortunately, efficient CAD tools for SSD design space exploration able to assess the optimization of the device microarchitecture w.r.t. the target performance are still missing. This paper tries to close this gap by proposing SSDExplorer, a tool for fine-grained and fast design space exploration of SSD devices. SSDExplorer provides unprecedented insights into the architecture behavior and subcomponent interaction efficiency, while avoiding the need for the actual implementation of an FTL or of key hardware components. This is achieved by the introduction of suitable abstractions of the different components. This is confirmed by the thorough validation of SSDExplorer against a commercial SSD device.
With the advent of solid-state storage systems, NAND flash memories are becoming a key storage technology. However, they suffer from serious reliability and endurance issues during the operating lifetime that can be handled by the use of appropriate error correction codes (ECCs) in order to reconstruct the information when needed. Adaptable ECCs may provide the flexibility to avoid worst-case reliability design, thus leading to improved performance. However, a way to control such adaptable ECCs' strength is required. This article proposes FLARES, an algorithm able to adapt the ECC correction capability of each page of a flash based on a flash RBER prediction model and on a measurement of the number of errors detected in a given time window. FLARES has been fully implemented within the YAFFS 2 filesystem under the Linux operating system. This allowed us to perform an extensive set of simulations on a set of standard benchmarks that highlighted the benefit of FLARES on the overall storage subsystem performances.
NAND Flash memories are gaining popularity in the development of electronic embedded systems for both consumer and mission-critical applications. NAND Flashes crucially influence computing systems development and performances. EF 3 S, a framework to easily assess NAND Flash based memory systems performances (reliability, throughput, power), is presented. The framework is based on a simulation engine and a running environment which enable developers to assess any application impact. Experimental results show functionality of the framework, analysing several performance-reliability tradeoffs of an illustrative system.
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