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Transaction Based Modeling and Verification of Hardware Protocols

Transaction Based Modeling and Verification of Hardware Protocols. Xiaofang Chen, Steven M. German and Ganesh Gopalakrishnan. Supported in part by SRC Contract TJ1318 Also supported thru an IBM Summer Internship . Hardware Protocols. Abstraction level. Specification.

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Transaction Based Modeling and Verification of Hardware Protocols

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  1. Transaction Based Modeling and Verification of Hardware Protocols • Xiaofang Chen, Steven M. German and Ganesh Gopalakrishnan Supported in part by SRC Contract TJ1318 Also supported thru an IBM Summer Internship

  2. Hardware Protocols Abstraction level Specification Cycle accurate RTL level Model size

  3. Problem Addressed • Specifications • Usually verifiable • But do they correctly represent the implementations? • RTL implementations • Real designs usually too complex to be verified • Even if verifiable, does the impl meet the spec? • Our goal • Develop a practical approach to check refinement

  4. Outline • Our approach of refinement check • Compositional refinement check • Experimental results and related work

  5. Differences in Modeling: Specs vs. Impls Multiple steps in low-level One step in high-level home remote home remote router buf represents an atomic guarded/command.

  6. Differences in Execution: Specs vs. Impls Interleaving in HL Concurrency in LL

  7. Our Approach of Refinement • Modeling • Specification: Murphi • Implementation: Hardware Murphi • Use transactions in Impl to relate to Spec • Verification • Muv: Hardware Murphi  synthesizable VHDL • Tool: IBM SixthSense

  8. Hardware Murphi • Murphi extension by German and Janssen • Concurrent guarded/commands with shared variables • On each cycle • Multiple transitions execute concurrently • Exclusive write to a variable • Shared reads to variables • Write immediately visible within the same transition • Write visible to other transitions on the next cycle • Support transactions, signals, etc

  9. What Are Transactions? • Group a multi-step execution in implementations Spec Impl

  10. Tool: Muv • Initially developed by German and Janssen • Hardware Murphi  synthesizable VHDL • Other usages: • Write verification drivers/checkers • Prototype VHDL implementations • Cycle-accurate modeling

  11. Our Definition of Refinement Category 1: interface vars … l0 l1 l2 Impl: … … … hn2 hn0 hn1 Spec:

  12. Our Definition of Refinement Category 2: transactional vars … l0 l1 l2 Impl: … … … hn2 hn0 hn1 Spec:

  13. Our Definition of Refinement Category 3: non-observable vars … l0 l1 l2 Impl: … … … hn2 hn0 hn1 Spec:

  14. Our Refinement Check Guard for Spec transition must hold Spec transition Spec(I) Spec(I’) Observable vars changed by either must match Multi-step Impl transaction I I’ I is a reachable Impl state

  15. An Example of Refinement Check Transaction Rule-1 guard1 action1; Rule-2 guard2 action2; Rule-3 guard3 action3; End; assert spec_guard; spec_action; assert impl_var1 = spec_var1; assert impl_var2 = spec_var2; …

  16. Additional Checks Needed for Refinement • Write-write conflicts • Serializability check

  17. Workflow of Our Refinement Check Murphi Spec model Muv Property check Product model in Hardware Murphi Product model in VHDL Hardware Murphi Impl model Check implementation meets specification

  18. Driving Benchmark Dir Cache Mem Local Buf Home Buf Remote Buf Router Dir Cache Mem Local Buf Home Buf Remote Buf S. German and G. Janssen, IBM Research Tech Report 2006

  19. Bugs Found with Refinement Check • Benchmark satisfies cache coherence already • Bugs still found • Bug 1: router unit loses messages • Bug 2: home unit replies twice for one request • Bug 3: cache unit gets updated twice from one reply • Refinement check is a convenient way of constructing checks

  20. Outline • Our approach of refinement check • Compositional refinement check • Experimental results and related work

  21. Model Checking Approaches • Monolithic • Product model + property check • Compositional • Divide and conquer Monolithic Product model in VHDL Compositional

  22. Compositional Refinement Check Guard for Spec transition must hold Spec transition Spec(I) Spec(I’) Observable vars changed by either must match Multi-step Impl transaction I I’ I is a reachable Impl state

  23. Basic Techniques of Our Compositional Approach • Abstraction • Removing details to make verification easier • A sound approach • Assume guarantee • A form of induction which introduces assumptions and justifies them

  24. Abstraction • Change variables to free input variables • Add all transitions that write to a variable to the submodel • If a read of a variable is self-sourced, this read is conservatively abstract

  25. Assume Guarantee Reasoning • Assume reads of an observable variable v • Spec_v = Impl_v • Guarantee this for all writes to v

  26. Additional Checks Needed for Abstraction & A/G • Write-write conflicts • Serializability check • Read-write dependencies between transactions • Currently performed on the monolithic model • Only involve the control logic

  27. Outline • Our approach of refinement check • Compositional refinement check • Experimental results and related work

  28. Experiment Results with SixthSense VerificationTime 1-day Monolithic approach Compositional approach 30 min Datapath 1-bit 10-bit * Configuration: Node = 2, Addr = 2

  29. Related Work • Bluespec • Arvind et al. • Aggregation of distributed actions • Park and Dill • Compositional verification • Many previous works: McMillan[97], C. B. Jones[83], etc.

  30. Conclusion • Developed a formal theory of refinement • Developed the monolithic refinement check • Developed a compositional approach • Obtained promising experimental results

  31. Future Work • Simulation-based check • VHDL design + Hardware Murphi test cases • Planned Work • Mechanize assertion generation of refinement in muv • More case studies, eg. pipelining

  32. Thanks • IBM SixthSense, RuleBase • Cadence IFV

  33. Questions?

  34. Project Summary • This paper • Basic refinement theory and implementation • Preliminary experiment results • More experiment results • A complete case study on a benchmark protocol • Bugs found • Verification time: over a day  30 min

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