用高阶逻辑扩展VLSI设计

Proceedings of ICCD '95 International Conference on Computer Design. VLSI in Computers and Processors Pub Date : 1995-10-02 DOI:10.1109/ICCD.1995.528795

Anand Chavan, Shiu-Kai Chin, Shahid Ikram, J. Kim, Juin-Yeu Zu

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引用次数: 4

摘要

用高阶逻辑扩展VLSI CAD集成了形式验证和综合验证。这样做的好处是:1)将指令集描述与实现相关联，2)在比原理图级别更高的抽象级别上进行设计，3)通过证明进行验证，4)重用已验证的参数化设计，5)自动将高阶逻辑中的设计编译为参数化单元生成器和布局，以及6)通过仿真验证电气和功能属性。这种集成通过将Cambridge高阶逻辑(HOL)定理证明器与Mentor Graphics GDT设计环境相连接来演示。我们通过为n位Am2910微程序定序器创建参数化宏单元生成器来说明其应用，该定序器的设计已根据其指令集架构规范进行了正式验证。

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Extending VLSI design with higher-order logic

Extending VLSI CAD with higher-order logic integrates formal verification with synthesis. The benefits of doing so are: 1) relating instruction-set descriptions to implementations, 2) designing at a higher level of abstraction than at the level of schematics, 3) verifying by proof 4) reusing verified parameterized designs, 5) automatically compiling designs in higher-order logic to parameterized cell generators and layouts, and 6) validating electrical and functional properties by simulation. Such an integration is demonstrated by linking the Cambridge Higher-Order Logic (HOL) theorem-prover with the Mentor Graphics GDT design environment. We illustrate its applications by creating a parameterized macro-cell generator for an n-bit Am2910 microprogram sequencer whose design is formally verified with respect to its instruction-set architecture specification.

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Proceedings of ICCD '95 International Conference on Computer Design. VLSI in Computers and Processors

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