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BitE : Accelerating Learned Query Optimization in a Mixed-Workload Environment

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arxiv 2306.00845 v2 pith:2PXWLT3O submitted 2023-06-01 cs.DB cs.LG

BitE : Accelerating Learned Query Optimization in a Mixed-Workload Environment

classification cs.DB cs.LG
keywords querylearnedmodelqueriesworkloadsbitedatasetslearning
verification ladder T0 review T1 audit T2 compute T3 formal T4 reserved
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Although the many efforts to apply deep reinforcement learning to query optimization in recent years, there remains room for improvement as query optimizers are complex entities that require hand-designed tuning of workloads and datasets. Recent research present learned query optimizations results mostly in bulks of single workloads which focus on picking up the unique traits of the specific workload. This proves to be problematic in scenarios where the different characteristics of multiple workloads and datasets are to be mixed and learned together. Henceforth, in this paper, we propose BitE, a novel ensemble learning model using database statistics and metadata to tune a learned query optimizer for enhancing performance. On the way, we introduce multiple revisions to solve several challenges: we extend the search space for the optimal Abstract SQL Plan(represented as a JSON object called ASP) by expanding hintsets, we steer the model away from the default plans that may be biased by configuring the experience with all unique plans of queries, and we deviate from the traditional loss functions and choose an alternative method to cope with underestimation and overestimation of reward. Our model achieves 19.6% more improved queries and 15.8% less regressed queries compared to the existing traditional methods whilst using a comparable level of resources.

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