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Design Smells in Deep Learning Programs: An Empirical Study

Software Engineering 2021-07-09 v2 Machine Learning

Abstract

Nowadays, we are witnessing an increasing adoption of Deep Learning (DL) based software systems in many industries. Designing a DL program requires constructing a deep neural network (DNN) and then training it on a dataset. This process requires that developers make multiple architectural (e.g., type, size, number, and order of layers) and configuration (e.g., optimizer, regularization methods, and activation functions) choices that affect the quality of the DL models, and consequently software quality. An under-specified or poorly-designed DL model may train successfully but is likely to perform poorly when deployed in production. Design smells in DL programs are poor design and-or configuration decisions taken during the development of DL components, that are likely to have a negative impact on the performance (i.e., prediction accuracy) and then quality of DL based software systems. In this paper, we present a catalogue of 8 design smells for a popular DL architecture, namely deep Feedforward Neural Networks which is widely employed in industrial applications. The design smells were identified through a review of the existing literature on DL design and a manual inspection of 659 DL programs with performance issues and design inefficiencies. The smells are specified by describing their context, consequences, and recommended refactorings. To provide empirical evidence on the relevance and perceived impact of the proposed design smells, we conducted a survey with 81 DL developers. In general, the developers perceived the proposed design smells as reflective of design or implementation problems, with agreement levels varying between 47\% and 68\%.

Keywords

Cite

@article{arxiv.2107.02279,
  title  = {Design Smells in Deep Learning Programs: An Empirical Study},
  author = {Amin Nikanjam and Foutse Khomh},
  journal= {arXiv preprint arXiv:2107.02279},
  year   = {2021}
}

Comments

Accepted for publication by ICSME 2021

R2 v1 2026-06-24T03:54:48.623Z