English

SwiftPruner: Reinforced Evolutionary Pruning for Efficient Ad Relevance

Information Retrieval 2022-09-02 v1 Artificial Intelligence Computation and Language

Abstract

Ad relevance modeling plays a critical role in online advertising systems including Microsoft Bing. To leverage powerful transformers like BERT in this low-latency setting, many existing approaches perform ad-side computations offline. While efficient, these approaches are unable to serve cold start ads, resulting in poor relevance predictions for such ads. This work aims to design a new, low-latency BERT via structured pruning to empower real-time online inference for cold start ads relevance on a CPU platform. Our challenge is that previous methods typically prune all layers of the transformer to a high, uniform sparsity, thereby producing models which cannot achieve satisfactory inference speed with an acceptable accuracy. In this paper, we propose SwiftPruner - an efficient framework that leverages evolution-based search to automatically find the best-performing layer-wise sparse BERT model under the desired latency constraint. Different from existing evolution algorithms that conduct random mutations, we propose a reinforced mutator with a latency-aware multi-objective reward to conduct better mutations for efficiently searching the large space of layer-wise sparse models. Extensive experiments demonstrate that our method consistently achieves higher ROC AUC and lower latency than the uniform sparse baseline and state-of-the-art search methods. Remarkably, under our latency requirement of 1900us on CPU, SwiftPruner achieves a 0.86% higher AUC than the state-of-the-art uniform sparse baseline for BERT-Mini on a large scale real-world dataset. Online A/B testing shows that our model also achieves a significant 11.7% cut in the ratio of defective cold start ads with satisfactory real-time serving latency.

Keywords

Cite

@article{arxiv.2209.00625,
  title  = {SwiftPruner: Reinforced Evolutionary Pruning for Efficient Ad Relevance},
  author = {Li Lyna Zhang and Youkow Homma and Yujing Wang and Min Wu and Mao Yang and Ruofei Zhang and Ting Cao and Wei Shen},
  journal= {arXiv preprint arXiv:2209.00625},
  year   = {2022}
}

Comments

CIKM 2022 (Applied Research Track)

R2 v1 2026-06-28T00:35:17.702Z