Your search keyword '"Bathen, Luis"' showing total 4 results

1. ViPZonE: Hardware Power Variability-Aware Virtual Memory Management for Energy Savings.

Author

Gottscho, Mark, Bathen, Luis A.D., Dutt, Nikil, Nicolau, Alex, and Gupta, Puneet

Subjects

*VIRTUAL storage (Computer science), *COMPUTER memory management, *ENERGY conservation, *COMPUTER software, *COMPUTER input-output equipment, *LINUX operating systems, *KERNEL operating systems

Abstract

Hardware variability is predicted to increase dramatically over the coming years as a consequence of continued technology scaling. In this paper, we apply the Underdesigned and Opportunistic Computing (UnO) paradigm by exposing system-level powervariability to software to improve energy efficiency. We present ViPZonE, a memory management solution in conjunction withapplication annotations that opportunistically performs memory allocations to reduce DRAM energy. ViPZonE’s components consist of a physical address space with DIMM-aware zones, a modified page allocation routine, and a new virtual memory system call for dynamic allocations from userspace. We implemented ViPZonE in the Linux kernel with GLIBC API support, running on a real x86-64 testbed with significant access power variation in its DDR3 DIMMs. We demonstrate that on our testbed, ViPZonE can save up to27.80 percent memory energy, with no more than 4.80 percent performance degradation across a set of PARSEC benchmarks tested with respect to the baseline Linux software. Furthermore, through a hypothetical “what-if” extension, we predict that in futurenon-volatile memory systems which consume almost no idle power, ViPZonE could yield even greater benefits, demonstrating theability to exploit memory hardware variability through opportunistic software. [ABSTRACT FROM PUBLISHER]

Published

2015

2. A Reliability-Aware Address Mapping Strategy for NAND Flash Memory Storage Systems.

Author

Wang, Yi, Huang, Min, Shao, Zili, Chan, Henry C. B., Bathen, Luis Angel D., and Dutt, Nikil D.

Subjects

ERROR-correcting codes, ERROR detection (Information theory), COMPUTER memory management, DISTRIBUTED shared memory, METADATA, FLASH memory, COMPUTER reliability

Abstract

The increasing density of NAND flash memory leads to a dramatic increase in the bit error rate of flash, which greatly reduces the ability of error correcting codes (ECC) to handle multibit errors. NAND flash memory is normally used to store the file system metadata and page mapping information. Thus, a broken physical page containing metadata may cause an unintended and severe change in functionality of the entire flash. This paper presents Meta-Cure, a novel hardware and file system interface that transparently protects metadata in the presence of multibit faults. Meta-Cure exploits built-in ECC and replication in order to protect pages containing critical data, such as file system metadata. Redundant pairs are formed at run time and distributed to different physical pages to protect against failures. Meta-Cure requires no changes to the file system, on-chip hierarchy, or hardware implementation of flash memory chip. We evaluate Meta-Cure under a real-embedded platform using a variety of I/O traces. The evaluation platform adopts dual ARM Cortex A9 processor cores with 64 Gb NAND flash memory. We have evaluated the effectiveness of Meta-Cure on the new technology file system file system. Experimental results show that the proposed technique can reduce uncorrectable page errors by 70.38% with less than 7.86% time overhead in comparison with conventional error correction techniques. [ABSTRACT FROM AUTHOR]

Published

2014

3. HaVOC: A Hybrid Memory-aware Virtualization Layer for On-Chip Distributed Scratch Pad and Non-Volatile Memories.

Author

Bathen, Luis Angel and Dutt, Nikil

Subjects

NONVOLATILE random-access memory, HAVOC (Information retrieval system), COMPUTER memory management, MULTIPROCESSORS, ELECTRONIC data processing

Abstract

Hybrid on-chip memories that combine Non-Volatile Memories (NVMs) with SRAMs promise to mitigate the increasing leakage power of traditional on-chip SRAMs. We present HaVOC: a run-time memory manager that virtualizes the hybrid on-chip memory space and supports efficient sharing of distributed ScratchPad Memories (SPMs) and NVMs. HaVOC allows programmers and the compiler to partition the application's address space and generate data/instruction block layouts considering virtualized hybrid address spaces. We define a data volatility metric used by our hybrid memoryaware compilation flow to generate memory allocation policies that are enforced at run-time by a filter-inspired dynamic memory algorithm. Our experimental results with a set of embedded benchmarks executing simultaneously on a Chip-Multiprocessor with hybrid NVM/SPMs show that HaVOC is able to reduce execution time and energy by 60.8% and 74.7% respectively with respect to traditional multitasking based SPM allocation policies. [ABSTRACT FROM AUTHOR]

Published

2012

4. Virtualizing on-chip distributed ScratchPad memories for low power and trusted application execution.

Author

Bathen, Luis, Shin, Dongyun, Lim, Sung-Soo, and Dutt, Nikil

Subjects

COMPUTER software management, VIRTUAL storage (Computer science), COMPUTER memory management, MULTIPROCESSORS, ENERGY consumption

Abstract

Emerging multicore platforms are increasingly deploying distributed scratchpad memories to achieve lower energy and area together with higher predictability; but this requires transparent and efficient software management of these critical resources. In this paper, we introduce the concept of ScratchPad Memory virtualization, a hardware/software run-time layer (called SPMVisor) that virtualizes the scratchpad memory space in order to facilitate the use of distributed SPMs in an efficient, transparent and secure manner. We introduce the notion of virtual scratchpad memories (vSPMs), which can be dynamically created and managed as regular SPMs. The SPMVisor exploits policy-driven allocation strategies based on application privilege levels and data level prioritization metrics (e.g., utilization) to efficiently manage the on-chip memory real-estate. Our experimental results on Mediabench/CHStone benchmarks running on various Chip-Multiprocessor configurations and software stacks (RTOS, virtualization, secure execution) showed that SPMVisor enhances performance by 71 % on average and reduces power consumption by 79 % on average with respect to traditional context switching schemes. We showed the benefits of using vSPMs in a various environments (a RTOS multi-tasking environment, a virtualization environment, and a trusted execution environment). Furthermore, we explored the effects of mapping instructions and data onto vSPMs, and showed that sharing on-chip space reduces both execution time and energy by an average 16 % and 12 % respectively. We then compared our priority-driven memory allocation scheme with traditional dynamic allocation and showed an average 54 % execution time reduction and 65 % energy savings. Finally, to further validate the SPMVisor's benefits, we modified the initial bus-based architecture to include a mesh-based CMP with up to 4×4 nodes. We were able to observe that SPMVisor's priority-driven allocator was able to reduce execution time by an average 17 % with respect to competing allocation policies, while saving an average 65 % across various architectural configurations. We were also able to observe that SPMVisor reduces execution time by an average 12.6 % with respect to competing allocation policies, while saving an average 63.5 % in total energy for various architectural configuration running 1024 jobs. [ABSTRACT FROM AUTHOR]

Published

2013