PolyARBerNN: A Neural Network Guided Solver and Optimizer for Bounded Polynomial Inequalities

IF 2.8 3区 计算机科学 Q2 COMPUTER SCIENCE, HARDWARE & ARCHITECTURE ACM Transactions on Embedded Computing Systems Pub Date : 2024-01-24 DOI:10.1145/3632970
Wael Fatnassi, Yasser Shoukry
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Abstract

Constraints solvers play a significant role in the analysis, synthesis, and formal verification of complex cyber-physical systems. In this paper, we study the problem of designing a scalable constraints solver for an important class of constraints named polynomial constraint inequalities (also known as nonlinear real arithmetic theory). In this paper, we introduce a solver named PolyARBerNN that uses convex polynomials as abstractions for highly nonlinears polynomials. Such abstractions were previously shown to be powerful to prune the search space and restrict the usage of sound and complete solvers to small search spaces. Compared with the previous efforts on using convex abstractions, PolyARBerNN provides three main contributions namely (i) a neural network guided abstraction refinement procedure that helps selecting the right abstraction out of a set of pre-defined abstractions, (ii) a Bernstein polynomial-based search space pruning mechanism that can be used to compute tight estimates of the polynomial maximum and minimum values which can be used as an additional abstraction of the polynomials, and (iii) an optimizer that transforms polynomial objective functions into polynomial constraints (on the gradient of the objective function) whose solutions are guaranteed to be close to the global optima. These enhancements together allowed the PolyARBerNN solver to solve complex instances and scales more favorably compared to the state-of-art nonlinear real arithmetic solvers while maintaining the soundness and completeness of the resulting solver. In particular, our test benches show that PolyARBerNN achieved 100X speedup compared with Z3 8.9, Yices 2.6, and PVS (a solver that uses Bernstein expansion to solve multivariate polynomial constraints) on a variety of standard test benches. Finally, we implemented an optimizer called PolyAROpt that uses PolyARBerNN to solve constrained polynomial optimization problems. Numerical results show that PolyAROpt is able to solve high-dimensional and high order polynomial optimization problems with higher speed compared to the built-in optimizer in the Z3 8.9 solver.

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PolyARBerNN:神经网络引导的有界多项式不等式求解器和优化器
约束求解器在复杂网络物理系统的分析、综合和形式验证中发挥着重要作用。在本文中,我们研究了为一类重要的约束条件设计可扩展的约束条件求解器的问题,这类约束条件被命名为多项式约束不等式(也称为非线性实算术理论)。在本文中,我们介绍了一种名为 PolyARBerNN 的求解器,它使用凸多项式作为高度非线性多项式的抽象。以前的研究表明,这种抽象具有强大的剪裁搜索空间的能力,并能将完善的求解器限制在较小的搜索空间内。与以往使用凸抽象的方法相比,PolyARBerNN 有三个主要贡献:(i) 神经网络引导的抽象完善程序,有助于从一组预定义的抽象中选择正确的抽象、(ii) 基于伯恩斯坦多项式的搜索空间剪枝机制,可用于计算多项式最大值和最小值的严格估计值,这些估计值可用作多项式的额外抽象;以及 (iii) 优化器,可将多项式目标函数转化为多项式约束(目标函数梯度),其解决方案保证接近全局最优。这些改进使得 PolyARBerNN 求解器能够求解复杂的实例,与最先进的非线性实算术求解器相比,其规模更大,同时保持了求解器的合理性和完整性。特别是,我们的测试平台显示,在各种标准测试平台上,PolyARBerNN 与 Z3 8.9、Yices 2.6 和 PVS(一种使用伯恩斯坦展开求解多元多项式约束的求解器)相比,速度提高了 100 倍。最后,我们实施了一个名为 PolyAROpt 的优化器,它使用 PolyARBerNN 解决多项式约束优化问题。数值结果表明,与 Z3 8.9 求解器中的内置优化器相比,PolyAROpt 能够以更快的速度解决高维和高阶多项式优化问题。
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来源期刊
ACM Transactions on Embedded Computing Systems
ACM Transactions on Embedded Computing Systems 工程技术-计算机:软件工程
CiteScore
3.70
自引率
0.00%
发文量
138
审稿时长
6 months
期刊介绍: The design of embedded computing systems, both the software and hardware, increasingly relies on sophisticated algorithms, analytical models, and methodologies. ACM Transactions on Embedded Computing Systems (TECS) aims to present the leading work relating to the analysis, design, behavior, and experience with embedded computing systems.
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