We propose a new approach to the Directed Feedback Vertex Set Problem (DFVSP), where the input is a directed graph and the solution is a minimum set of vertices whose removal makes the graph acyclic. Our approach, implemented in the solver DAGer, is based on two novel contributions: Firstly, we add a wide range of data reductions that are partially inspired by reductions for the similar vertex cover problem. For this, we give a theoretical basis for lifting reductions from vertex cover to DFVSP but also incorporate novel ideas into strictly more general and new DFVSP reductions. Secondly, we propose dynamically encoding DFVSP in propositional logic using cycle propagation for improved performance. Cycle propagation builds on the idea that already a limited number of the constraints in a propositional encoding is usually sufficient for finding an optimal solution. Our algorithm, therefore, starts with a small number of constraints and cycle propagation adds additional constraints when necessary. We propose an efficient integration of cycle propagation into the workflow of MaxSAT solvers, further improving the performance of our algorithm. Our extensive experimental evaluation shows that DAGer significantly outperforms the state-of-the-art solvers and that our data reductions alone directly solve many of the instances.
翻译:我们提出一种新的方法来解决直接反馈热点设置问题(DFVSP ), 输入是一个定向图表, 解决方案是一组最起码的脊椎, 其去除使图形环状。 我们在解答器 DAGer 中实施的方法基于两种新的贡献: 首先, 我们增加一系列因类似顶顶层覆盖问题减少而部分引发的数据减少。 为此, 我们给从顶部覆盖到DFVSP 的减少量提供一个理论基础, 并将新的想法纳入严格来说更一般的和新的DFVSP 削减量。 其次, 我们提议用循环传播来将DFVSP 动态地编码为代言逻辑, 以便改进性能。 循环传播基于这样一种想法,即一种模式编码中已经有限的限制通常足以找到最佳的解决方案。 因此, 我们的算法从少量限制和周期传播开始, 必要时会增加额外的限制。 我们提议将循环传播有效纳入MaxSAT 解算器的工作流程, 进一步改进我们的算法的性能。 我们的广泛实验性评估显示, DAGer 独自大大超越了我们许多解算器的状态。