Minghao Liu, David M. Cerna, Filipe Gouveia, Andrew Cropper
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Scalable Knowledge Refactoring using Constrained Optimisation
Knowledge refactoring compresses a logic program by introducing new rules.
Current approaches struggle to scale to large programs. To overcome this
limitation, we introduce a constrained optimisation refactoring approach. Our
first key idea is to encode the problem with decision variables based on
literals rather than rules. Our second key idea is to focus on linear invented
rules. Our empirical results on multiple domains show that our approach can
refactor programs quicker and with more compression than the previous
state-of-the-art approach, sometimes by 60%.
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