| [176792] |
| Title: Predicting Worst-Case Execution Times During Multi-Criterial Function Inlining. <em>In Proceedings of the 7th International Conference on Machine Learning, Optimization, and Data Science (LOD)</em> |
| Written by: Kateryna Muts and Heiko Falk |
| in: October (2021). |
| Volume: Number: |
| on pages: |
| Chapter: |
| Editor: |
| Publisher: |
| Series: |
| Address: |
| Edition: |
| ISBN: 10.1007/978-3-030-95467-3_21 |
| how published: 21-75 MF21a LOD |
| Organization: |
| School: |
| Institution: |
| Type: |
| DOI: |
| URL: |
| ARXIVID: |
| PMID: |
Note: kmuts, hfalk, multiopt, ESD, WCC
Abstract: In the domain of hard real-time systems, the Worst-Case Execution Time (WCET) is one of the most important design criteria. Safely and accurately estimating the WCET during a static WCET analysis is computationally demanding because of the involved data flow, control flow, and microarchitecture analyses. This becomes critical in the field of multi-criterial compiler optimizations that trade the WCET with other design objectives. Evolutionary algorithms are typically exploited to solve a multi-objective optimization problem, but they require an extensive evaluation of the objectives to explore the search space of the problem. This paper proposes a method that utilizes machine learning to build a surrogate model in order to quickly predict the WCET instead of costly estimating it using static WCET analysis. We build a prediction model that is independent of the source code and assembly code features, so a compiler can utilize it to perform any compiler-based optimization. We demonstrate the effectiveness of our model on multi-criterial function inlining, where we aim to explore trade-offs between the WCET, code size, and energy consumption at compile time.