powerpc620微处理器的多处理器设计验证

Proceedings of ICCD '95 International Conference on Computer Design. VLSI in Computers and Processors Pub Date : 1995-10-02 DOI:10.1109/ICCD.1995.528809

C. Montemayor, M. Sullivan, Jen-Tien Yen, P. Wilson, R. Evers

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引用次数: 10

摘要

由于620总线协议的复杂性，PowerPC 620微处理器的多处理器设计验证具有挑战性。高并发总线和2级(LS)缓存接口，以及广泛的系统可配置性。为了验证这一功能，使用了随机和确定性方法的组合。随机测试程序生成器(RTPG)和新开发的随机并发程序生成器(SCPG)工具进行随机验证。在确定性方面，用C编写测试用例来验证特定的场景。在创建SCPG时，我们处理设计的复杂性和频繁的设计变更，方法是将关注的领域抽象为简单的语言，编写工具来生成测试，并在标准验证环境中执行这些测试。这些测试的附加价值在于，它们在处理器之间实现了真正的数据共享，具有自检功能，类似于商业多处理器代码。

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Multiprocessor design verification for the PowerPC 620 microprocessor

Multiprocessor design verification for the PowerPC 620 microprocessor was challenging due to the 620 Bus protocol complexity. The highly concurrent bus and level 2 (LS) cache interfaces, and the extensive system configurability. In order to verify this functionality, a combination of random and deterministic approaches were used. The Random Test Program Generator (RTPG) and the newly developed Stochastic Concurrent Program Generator (SCPG) tools were used for random verification. In the deterministic front, testcases in C were written to verify specific scenarios. In creating SCPG, we dealt with the design complexity and frequent design changes by abstracting areas of concern as simple languages, writing tools to generate tests, and executing these in the standard verification environment. The added value of these tests is that they exercise true data sharing among processors, are self-checking and resemble commercial multiprocessor code.

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

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