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Lower Bounds Against Sparse Symmetric Functions of ACC Circuits: Expanding the Reach of #SAT Algorithms

Authors Nikhil Vyas , R. Ryan Williams

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LIPIcs.STACS.2020.59.pdf
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Nikhil Vyas
  • MIT, Cambridge, MA, USA
R. Ryan Williams
  • MIT, Cambridge, MA, USA

Funding

Supported by NSF CCF-1741615 and NSF CCF-1909429.

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Nikhil Vyas and R. Ryan Williams. Lower Bounds Against Sparse Symmetric Functions of ACC Circuits: Expanding the Reach of #SAT Algorithms. In 37th International Symposium on Theoretical Aspects of Computer Science (STACS 2020). Leibniz International Proceedings in Informatics (LIPIcs), Volume 154, pp. 59:1-59:17, Schloss Dagstuhl – Leibniz-Zentrum für Informatik (2020)
https://doi.org/10.4230/LIPIcs.STACS.2020.59

Abstract

We continue the program of proving circuit lower bounds via circuit satisfiability algorithms. So far, this program has yielded several concrete results, proving that functions in Quasi-NP = NTIME[n^{(log n)^O(1)}] and NEXP do not have small circuits (in the worst case and/or on average) from various circuit classes C, by showing that C admits non-trivial satisfiability and/or #SAT algorithms which beat exhaustive search by a minor amount. In this paper, we present a new strong lower bound consequence of non-trivial #SAT algorithm for a circuit class {C}. Say a symmetric Boolean function f(x₁,…,x_n) is sparse if it outputs 1 on O(1) values of ∑_i x_i. We show that for every sparse f, and for all "typical" C, faster #SAT algorithms for C circuits actually imply lower bounds against the circuit class f ∘ C, which may be stronger than C itself. In particular: - #SAT algorithms for n^k-size C-circuits running in 2ⁿ/n^k time (for all k) imply NEXP does not have f ∘ C-circuits of polynomial size. - #SAT algorithms for 2^{n^ε}-size C-circuits running in 2^{n-n^ε} time (for some ε > 0) imply Quasi-NP does not have f ∘ C-circuits of polynomial size. Applying #SAT algorithms from the literature, one immediate corollary of our results is that Quasi-NP does not have EMAJ ∘ ACC⁰ ∘ THR circuits of polynomial size, where EMAJ is the "exact majority" function, improving previous lower bounds against ACC⁰ [Williams JACM'14] and ACC⁰ ∘ THR [Williams STOC'14], [Murray-Williams STOC'18]. This is the first nontrivial lower bound against such a circuit class.

Subject Classification

ACM Subject Classification
  • Theory of computation → Circuit complexity
Keywords
  • #SAT
  • satisfiability
  • circuit complexity
  • exact majority
  • ACC

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References

  1. Josh Alman, Timothy M. Chan, and R. Ryan Williams. Polynomial representations of threshold functions and algorithmic applications. In FOCS, pages 467-476, 2016. Google Scholar
  2. Sanjeev Arora and Boaz Barak. Computational Complexity - A Modern Approach. Cambridge University Press, 2009. URL: http://www.cambridge.org/catalogue/catalogue.asp?isbn=9780521424264.
  3. Richard Beigel, Nick Reingold, and Daniel A. Spielman. PP is closed under intersection. J. Comput. Syst. Sci., 50(2):191-202, 1995. URL: https://doi.org/10.1006/jcss.1995.1017.
  4. Richard Beigel, Jun Tarui, and Seinosuke Toda. On probabilistic ACC circuits with an exact-threshold output gate. In Algorithms and Computation, Third International Symposium, ISAAC '92, Nagoya, Japan, December 16-18, 1992, Proceedings, pages 420-429, 1992. Google Scholar
  5. Lijie Chen. Non-deterministic quasi-polynomial time is average-case hard for ACC circuits. In 60th IEEE Annual Symposium on Foundations of Computer Science, FOCS 2019, Baltimore, Maryland, USA, November 9-12, 2019, pages 1281-1304, 2019. Google Scholar
  6. Lijie Chen and R. Ryan Williams. Stronger connections between circuit analysis and circuit lower bounds, via pcps of proximity. In 34th Computational Complexity Conference, CCC 2019, July 18-20, 2019, New Brunswick, NJ, USA., pages 19:1-19:43, 2019. Google Scholar
  7. Ruiwen Chen, Igor Carboni Oliveira, and Rahul Santhanam. An average-case lower bound against acc⁰. In LATIN 2018: Theoretical Informatics - 13th Latin American Symposium, Buenos Aires, Argentina, April 16-19, 2018, Proceedings, pages 317-330, 2018. Google Scholar
  8. Irit Dinur and Omer Reingold. Assignment testers: Towards a combinatorial proof of the PCP theorem. SIAM J. Comput., 36(4):975-1024, 2006. URL: https://doi.org/10.1137/S0097539705446962.
  9. Uriel Feige, Shafi Goldwasser, László Lovász, Shmuel Safra, and Mario Szegedy. Approximating clique is almost np-complete. In 32nd Annual Symposium on Foundations of Computer Science, San Juan, Puerto Rico, 1-4 October 1991, pages 2-12, 1991. Google Scholar
  10. Oded Goldreich. A sample of samplers: A computational perspective on sampling. In Studies in Complexity and Cryptography. Miscellanea on the Interplay between Randomness and Computation - In Collaboration with Lidor Avigad, Mihir Bellare, Zvika Brakerski, Shafi Goldwasser, Shai Halevi, Tali Kaufman, Leonid Levin, Noam Nisan, Dana Ron, Madhu Sudan, Luca Trevisan, Salil Vadhan, Avi Wigderson, David Zuckerman, pages 302-332. Springer, 2011. Google Scholar
  11. Frederic Green. A complex-number fourier technique for lower bounds on the mod-m degree. Computational Complexity, 9(1):16-38, 2000. URL: https://doi.org/10.1007/PL00001599.
  12. Kristoffer Arnsfelt Hansen. Computing symmetric boolean functions by circuits with few exact threshold gates. In Computing and Combinatorics, 13th Annual International Conference, COCOON 2007, Banff, Canada, July 16-19, 2007, Proceedings, pages 448-458, 2007. URL: https://doi.org/10.1007/978-3-540-73545-8_44.
  13. Kristoffer Arnsfelt Hansen. Depth reduction for circuits with a single layer of modular counting gates. In Computer Science - Theory and Applications, Fourth International Computer Science Symposium in Russia, CSR 2009, Novosibirsk, Russia, August 18-23, 2009. Proceedings, pages 117-128, 2009. URL: https://doi.org/10.1007/978-3-642-03351-3_13.
  14. Kristoffer Arnsfelt Hansen and Vladimir V. Podolskii. Exact threshold circuits. In Proceedings of the 25th Annual IEEE Conference on Computational Complexity, CCC 2010, Cambridge, Massachusetts, USA, June 9-12, 2010, pages 270-279, 2010. URL: https://doi.org/10.1109/CCC.2010.33.
  15. Valentine Kabanets and Russell Impagliazzo. Derandomizing polynomial identity tests means proving circuit lower bounds. Computational Complexity, 13(1-2):1-46, 2004. URL: https://doi.org/10.1007/s00037-004-0182-6.
  16. Cody Murray and R. Ryan Williams. Circuit lower bounds for nondeterministic quasi-polytime: an easy witness lemma for NP and NQP. In Proceedings of the 50th Annual ACM SIGACT Symposium on Theory of Computing, STOC 2018, Los Angeles, CA, USA, June 25-29, 2018, pages 890-901, 2018. Google Scholar
  17. Daniel A. Spielman. Linear-time encodable and decodable error-correcting codes. IEEE Trans. Information Theory, 42(6):1723-1731, 1996. URL: https://doi.org/10.1109/18.556668.
  18. Suguru Tamaki. A satisfiability algorithm for depth two circuits with a sub-quadratic number of symmetric and threshold gates. Electronic Colloquium on Computational Complexity (ECCC), 23:100, 2016. Google Scholar
  19. Nikhil Vyas and Ryan Williams. Lower bounds against sparse symmetric functions of acc circuits: Expanding the reach of #SAT algorithms, 2020. URL: https://drive.google.com/open?id=1NjlPk9FZPY3DHvxpbB7nWE3fz71E16mf.
  20. Klaus W. Wagner. The complexity of combinatorial problems with succinct input representation. Acta Inf., 23(3):325-356, 1986. URL: https://doi.org/10.1007/BF00289117.
  21. R. Ryan Williams. New algorithms and lower bounds for circuits with linear threshold gates. Theory of Computing, 14(1):1-25, 2018. Google Scholar
  22. R. Ryan Williams. New algorithms and lower bounds for circuits with linear threshold gates. Theory of Computing, 14(1):1-25, 2018. URL: https://doi.org/10.4086/toc.2018.v014a017.
  23. Richard Ryan Williams. Limits on representing boolean functions by linear combinations of simple functions: Thresholds, relus, and low-degree polynomials. In 33rd Computational Complexity Conference, CCC 2018, June 22-24, 2018, San Diego, CA, USA, pages 6:1-6:24, 2018. URL: https://doi.org/10.4230/LIPIcs.CCC.2018.6.
  24. Ryan Williams. Improving exhaustive search implies superpolynomial lower bounds. SIAM Journal on Computing, 42(3):1218-1244, 2013. Google Scholar
  25. Ryan Williams. Nonuniform ACC circuit lower bounds. J. ACM, 61(1):2:1-2:32, 2014. URL: https://doi.org/10.1145/2559903.
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