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引用次数: 124

摘要

编写精确的数值软件是困难的,因为有许多不可避免的不确定性来源,包括有限的数值精度实现。我们提出了一个编程模型,其中用户用实值实现和规范语言编写程序,其中显式包含不同类型的不确定性。然后,我们提出了一种编译算法,该算法生成有限精度的实现,保证满足相对于实数的所需精度。我们的编译对不同的候选精度执行许多验证步骤。它生成验证条件,以统一的方式处理所有不确定源,并将有限精度舍入误差的推理编码为实数推理。这些验证条件可以作为验证数值程序精度和正确性的标准格式。由于它们的非线性性质,对这些验证条件的精确推理仍然很困难,并且不能单独使用最先进的SMT求解器来处理。因此,我们提出了一个新的过程,结合了精确的SMT求解实数与近似和声音仿射和区间算法。我们证明这种方法克服了SMT求解器的可扩展性限制,同时提供了比仿射和区间算法更高的精度。我们的实现在几个数值模型上给出了有希望的结果,包括动力系统、超越函数和控制器实现。
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Sound compilation of reals
Writing accurate numerical software is hard because of many sources of unavoidable uncertainties, including finite numerical precision of implementations. We present a programming model where the user writes a program in a real-valued implementation and specification language that explicitly includes different types of uncertainties. We then present a compilation algorithm that generates a finite-precision implementation that is guaranteed to meet the desired precision with respect to real numbers. Our compilation performs a number of verification steps for different candidate precisions. It generates verification conditions that treat all sources of uncertainties in a unified way and encode reasoning about finite-precision roundoff errors into reasoning about real numbers. Such verification conditions can be used as a standardized format for verifying the precision and the correctness of numerical programs. Due to their non-linear nature, precise reasoning about these verification conditions remains difficult and cannot be handled using state-of-the art SMT solvers alone. We therefore propose a new procedure that combines exact SMT solving over reals with approximate and sound affine and interval arithmetic. We show that this approach overcomes scalability limitations of SMT solvers while providing improved precision over affine and interval arithmetic. Our implementation gives promising results on several numerical models, including dynamical systems, transcendental functions, and controller implementations.
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Session details: Verified systems Session details: Semantic models 2 Session details: Program analysis 3 Session details: Program analysis 1 Session details: Type system design
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