Drew Penney scite author profile

Machine learning applied to architecture design presents a promising opportunity with broad applications. Recent deep reinforcement learning (DRL) techniques, in particular, enable efficient exploration in vast design spaces where conventional design strategies may be inadequate. This paper proposes a novel deep reinforcement framework, taking routerless networks-on-chip (NoC) as an evaluation case study. The new framework successfully resolves problems with prior design approaches being either unreliable due to random searches or inflexible due to severe design space restrictions. The framework learns (near-)optimal loop placement for routerless NoCs with various design constraints. A deep neural network is developed using parallel threads that efficiently explore the immense routerless NoC design space with a Monte Carlo search tree. Experimental results show that, compared with conventional mesh, the proposed deep reinforcement learning (DRL) routerless design achieves a 3.25x increase in throughput, 1.6x reduction in packet latency, and 5x reduction in power. Compared with the state-of-the-art routerless NoC, DRL achieves a 1.47x increase in throughput, 1.18x reduction in packet latency, and 1.14x reduction in average hop count albeit with slightly more power overhead.

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A Survey of Machine Learning Applied to Computer Architecture Design

Penney¹,

Chen

2019

Preprint

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Machine learning has enabled significant benefits in diverse fields, but, with a few exceptions, has had limited impact on computer architecture. Recent work, however, has explored broader applicability for design, optimization, and simulation. Notably, machine learning based strategies often surpass prior state-of-the-art analytical, heuristic, and human-expert approaches. This paper reviews machine learning applied system-wide to simulation and run-time optimization, and in many individual components, including memory systems, branch predictors, networks-on-chip, and GPUs. The paper further analyzes current practice to highlight useful design strategies and identify areas for future work, based on optimized implementation strategies, opportune extensions to existing work, and ambitious long term possibilities. Taken together, these strategies and techniques present a promising future for increasingly automated architectural design.

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AI for Computer Architecture: Principles, Practice, and Prospects

Chen

Penney

Jiménez

2020

Synthesis Lectures on Computer Architecture

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Drew Penney

A Deep Reinforcement Learning Framework for Architectural Exploration: A Routerless NoC Case Study

Characterizing On-Chip Traffic Patterns in General-Purpose GPUs: A Deep Learning Approach

Optimizing Routerless Network-on-Chip Designs: An Innovative Learning-Based Framework

A Survey of Machine Learning Applied to Computer Architecture Design

AI for Computer Architecture: Principles, Practice, and Prospects

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