1,788 research outputs found
Energy Saving Techniques for Phase Change Memory (PCM)
In recent years, the energy consumption of computing systems has increased
and a large fraction of this energy is consumed in main memory. Towards this,
researchers have proposed use of non-volatile memory, such as phase change
memory (PCM), which has low read latency and power; and nearly zero leakage
power. However, the write latency and power of PCM are very high and this,
along with limited write endurance of PCM present significant challenges in
enabling wide-spread adoption of PCM. To address this, several
architecture-level techniques have been proposed. In this report, we review
several techniques to manage power consumption of PCM. We also classify these
techniques based on their characteristics to provide insights into them. The
aim of this work is encourage researchers to propose even better techniques for
improving energy efficiency of PCM based main memory.Comment: Survey, phase change RAM (PCRAM
Exploring the Performance Benefit of Hybrid Memory System on HPC Environments
Hardware accelerators have become a de-facto standard to achieve high
performance on current supercomputers and there are indications that this trend
will increase in the future. Modern accelerators feature high-bandwidth memory
next to the computing cores. For example, the Intel Knights Landing (KNL)
processor is equipped with 16 GB of high-bandwidth memory (HBM) that works
together with conventional DRAM memory. Theoretically, HBM can provide 5x
higher bandwidth than conventional DRAM. However, many factors impact the
effective performance achieved by applications, including the application
memory access pattern, the problem size, the threading level and the actual
memory configuration. In this paper, we analyze the Intel KNL system and
quantify the impact of the most important factors on the application
performance by using a set of applications that are representative of
scientific and data-analytics workloads. Our results show that applications
with regular memory access benefit from MCDRAM, achieving up to 3x performance
when compared to the performance obtained using only DRAM. On the contrary,
applications with random memory access pattern are latency-bound and may suffer
from performance degradation when using only MCDRAM. For those applications,
the use of additional hardware threads may help hide latency and achieve higher
aggregated bandwidth when using HBM
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