Complexity

In his recent presentation discussing verification of the Power7 processor, John Ludden of IBM opened with a quote from an IBM exec more than a decade ago. “it’s not rocket science”- a perception held by some members of the management and design communities at that time.

However, designs have become a whole lot more complex over time. The Power7 processor at 45nm has 1.2B transistors on a 567 sq. mm die, supporting 8 cores with 4 threads each, an on-chip eDRAM, 3 levels of caches and 2 DDR memory controllers. Yet as verification complexity multiplies in this multi-threaded design, it’s very helpful to have some of the more advanced tools and methodology at your disposal.

Tools and Methodology

Fortunately for Ludden and the Power7 team, IBM has invested in verification technology for years (in spite the quote from the exec). The company continues to develop and rely on in-house tools for many of the advanced verification technologies for processor-specific testing. These include the test-bench, multi-thread test generators, hardware accelerators, formal and semi-formal tools, micro-architecture checkers (API based), cache coherency checkers and coverage tools. Exercisers
originally developed for post-silicon validation were used to exploit the hardware acceleration platform. Forty-five thousand coverage points were organized to assist with big picture and were used to re-direct the test generator and exercisers for accelerators.

To support corner case testing for events that occur rarely, especially in multi-threaded scenarios, software irritator threads were used. These irritators are capable of creating the worst possible contentions. Through their application, twenty-three high quality bugs were revealed hiding in the corners.

A methodical application of these tools and technology clearly captured and advanced the industry best practices.

Designing for Verification

Designing for Verification was an important element in managing the overall risk to verification time line. IBM minimized the risks by maintaining a tight interaction between the specification and verification teams during the design phase and allowing the verification team to maintain architectural changes. “Chicken switches” were placed in silicon that allowed verification team to back-off an area considered risky or possible of otherwise compromising the verification effort. These switches provide workarounds, with some small impact on performance but no functional change, for accessing difficult to verify micro architectural features. Hardware irritators were also used to enable stress testing of corner cases in both pre-silicon and post-silicon testing.

Conclusion

The Power7 draws many architectural features from the Power5 and 6 designs, although it is a much more complex and powerful processor with a much shorter verification cycle. Ludden and the Power7 team accomplished this remarkable feat with a lot of foresight in planning, metrics collection and careful execution. Tight interlocking between metrics collected and verification plan was key part of tracking mechanism and functional closure. This project should serve as an example of how to plan for and manage risks in a complex verification project.

Kudos to John and the IBM team. His full presentation can be downloaded here.

10th International Workshop on Microprocessor Test and Verification (MTV 2009)
December 7-8, 2009, Hyatt Regency On Town Lake, Austin, Texas, USA.

Website: http://mtv.ece.ucsb.edu/MTV/

This is the 10th edition of the MTV Workshop, a testament to its success in providing an ideal environment for cross- examination of test and verification experiences and innovative solutions. MTV has been held in Austin for the last 8 years, so please plan on participating in order to make this another successful forum.

Purpose

The purpose of this workshop is to bring researchers and practitioners from the fields of verification and test together to exchange innovative ideas and to develop new methodologies to solve the difficult challenges facing us today in various processor and SOC design environments. In the past few years, some work has been done on exploiting techniques from test to solve problems in verification and vice versa.

Topics

AREAS OF INTEREST include, but not limited to:

• Validation of microprocessors and SOCs
• Test/Verification of multimedia processors
• Performance testing
• High-level test generation for functional verification
• Emulation techniques
• Silicon debugging
• Formal techniques and their applications
• Verification coverage
• Test Generation at the transistor level
• Equivalence checking of custom circuits
• ESL Methodology
• Virtual Platforms
• Software verification
• Circuit level verification
• Switch-level circuit modeling
• Timing validation techniques
• Path analysis for verification or test
• Design error models
• Design error diagnosis
• Design for Testability or Verifiability
• Optimizing SAT procedures with applications to testing and formal verification

Important dates

Submission: Sept 1, 2009
Notification: Oct 1, 2009
Final version due: Nov 1, 2009