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Main Authors: Bouvier, Maxence, Amaudruz, Ryan, Arnold, Felix, Andri, Renzo, Cavigelli, Lukas
Format: Preprint
Published: 2025
Subjects:
Online Access:https://arxiv.org/abs/2507.18989
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author Bouvier, Maxence
Amaudruz, Ryan
Arnold, Felix
Andri, Renzo
Cavigelli, Lukas
author_facet Bouvier, Maxence
Amaudruz, Ryan
Arnold, Felix
Andri, Renzo
Cavigelli, Lukas
contents As AI workloads proliferate, optimizing arithmetic units is becoming increasingly important for reducing the footprint of digital systems. Conventional design flows, which often rely on manual or heuristic-based optimization, are limited in their ability to thoroughly explore the vast design space. In this paper, we introduce GENIAL, a machine learning-based framework for the automatic generation and optimization of arithmetic units, with a focus on multipliers. At the core of GENIAL is a Transformer-based surrogate model trained in two stages, involving self-supervised pretraining followed by supervised finetuning, to robustly forecast key hardware metrics such as power and area from abstracted design representations. By inverting the surrogate model, GENIAL efficiently searches for new operand encodings that directly minimize power consumption in arithmetic units for specific input data distributions. Extensive experiments on large datasets demonstrate that GENIAL is consistently more sample efficient than other methods, and converges faster towards optimized designs. This enables deployment of a high-effort logic synthesis optimization flow in the loop, improving the accuracy of the surrogate model. Notably, GENIAL automatically discovers encodings that achieve up to 18% switching activity savings within multipliers on representative AI workloads compared with the conventional two's complement. We also demonstrate the versatility of our approach by achieving significant improvements on Finite State Machines, highlighting GENIAL's applicability for a wide spectrum of logic functions. Together, these advances mark a significant step toward automated Quality-of-Results-optimized combinational circuit generation for digital systems.
format Preprint
id arxiv_https___arxiv_org_abs_2507_18989
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle GENIAL: Generative Design Space Exploration via Network Inversion for Low Power Algorithmic Logic Units
Bouvier, Maxence
Amaudruz, Ryan
Arnold, Felix
Andri, Renzo
Cavigelli, Lukas
Machine Learning
Artificial Intelligence
Hardware Architecture
As AI workloads proliferate, optimizing arithmetic units is becoming increasingly important for reducing the footprint of digital systems. Conventional design flows, which often rely on manual or heuristic-based optimization, are limited in their ability to thoroughly explore the vast design space. In this paper, we introduce GENIAL, a machine learning-based framework for the automatic generation and optimization of arithmetic units, with a focus on multipliers. At the core of GENIAL is a Transformer-based surrogate model trained in two stages, involving self-supervised pretraining followed by supervised finetuning, to robustly forecast key hardware metrics such as power and area from abstracted design representations. By inverting the surrogate model, GENIAL efficiently searches for new operand encodings that directly minimize power consumption in arithmetic units for specific input data distributions. Extensive experiments on large datasets demonstrate that GENIAL is consistently more sample efficient than other methods, and converges faster towards optimized designs. This enables deployment of a high-effort logic synthesis optimization flow in the loop, improving the accuracy of the surrogate model. Notably, GENIAL automatically discovers encodings that achieve up to 18% switching activity savings within multipliers on representative AI workloads compared with the conventional two's complement. We also demonstrate the versatility of our approach by achieving significant improvements on Finite State Machines, highlighting GENIAL's applicability for a wide spectrum of logic functions. Together, these advances mark a significant step toward automated Quality-of-Results-optimized combinational circuit generation for digital systems.
title GENIAL: Generative Design Space Exploration via Network Inversion for Low Power Algorithmic Logic Units
topic Machine Learning
Artificial Intelligence
Hardware Architecture
url https://arxiv.org/abs/2507.18989