An Accelerator for Resolution Proof Checking based on FPGA and Hybrid Memory Cube Technology

Abstract

Modern Boolean satisfiability solvers can emit proofs of unsatisfiability. There is substantial interest in being able to verify such proofs and also in using them for further computations. In this paper, we present an FPGA accelerator for checking resolution proofs, a popular proof format. Our accelerator exploits parallelism at the low level by implementing the basic resolution step in hardware, and at the high level by instantiating a number of parallel modules for proof checking. Since proof checking involves highly irregular memory accesses, we employ Hybrid Memory Cube technology for accelerator memory. The results show that while the accelerator is scalable and achieves speedups for all benchmark proofs, performance improvements are currently limited by the overhead of transitioning the proof into the accelerator memory.

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    http://fmv.jku.at/tracecheck/

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    www.micron.com/products/advanced-solutions/advanced-computing-solutions

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    www.satcompetition.org

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Acknowledgements

This work was partially supported by the German Research Foundation (DFG) within the Collaborative Research Centre “On-The-Fly Computing” (SFB 901).

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Correspondence to Tim Hansmeier.

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Hansmeier, T., Platzner, M., Pantho, M.J.H. et al. An Accelerator for Resolution Proof Checking based on FPGA and Hybrid Memory Cube Technology. J Sign Process Syst 91, 1259–1272 (2019). https://doi.org/10.1007/s11265-018-1435-y

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Keywords

  • Resolution proof checking
  • Accelerator
  • FPGA
  • Hybrid Memory Cube