ILP-Based energy minimization techniques for banked memories

Author:

Ozturk Ozcan1,Kandemir Mahmut2

Affiliation:

1. Bilkent University, Ankara, Turkey

2. The Pennsylvania State University, University Park, PA

Abstract

Main memories can consume a significant portion of overall energy in many data-intensive embedded applications. One way of reducing this energy consumption is banking, that is, dividing available memory space into multiple banks and placing unused (idle) memory banks into low-power operating modes. Prior work investigated code-restructuring- and data-layout-reorganization-based approaches for increasing the energy benefits that could be obtained from a banked memory architecture. This article explores different techniques that can potentially coexist within the same optimization framework for maximizing benefits of low-power operating modes. These techniques include employing nonuniform bank sizes, data migration, data compression, and data replication. By using these techniques, we try to increase the chances for utilizing low-power operating modes in a more effective manner, and achieve further energy savings over what could be achieved by exploiting low-power modes alone. Specifically, nonuniform banking tries to match bank sizes with application-data access patterns. The goal of data migration is to cluster data with similar access patterns in the same set of banks. Data compression reduces the size of the data used by an application, and thus helps reduce the number of memory banks occupied by data. Finally, data replication increases bank idleness by duplicating select read-only data blocks across banks. We formulate each of these techniques as an ILP (integer linear programming) problem, and solve them using a commercial solver. Our experimental analysis using several benchmarks indicates that all the techniques presented in this framework are successful in reducing memory energy consumption. Based on our experience with these techniques, we recommend to compiler writers for banked memories to consider data compression, replication, and migration.

Funder

National Science Foundation

Publisher

Association for Computing Machinery (ACM)

Subject

Electrical and Electronic Engineering,Computer Graphics and Computer-Aided Design,Computer Science Applications

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1. High-Performance Predictable NVM-Based Instruction Memory for Real-Time Embedded Systems;IEEE Transactions on Emerging Topics in Computing;2021-01-01

2. Disperse Access Considered Energy Inefficiency in Intel Optane DC Persistent Memory Servers;2020 IEEE 40th International Conference on Distributed Computing Systems (ICDCS);2020-11

3. On the Restore Time Variations of Future DRAM Memory;ACM Transactions on Design Automation of Electronic Systems;2017-03-15

4. A Survey Of Architectural Approaches for Data Compression in Cache and Main Memory Systems;IEEE Transactions on Parallel and Distributed Systems;2016-05-01

5. Optimum design of a banked memory with power management for wireless sensor networks;Wireless Networks;2014-07-15

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