Towards P from Extended Frege lower bounds

Abstract

We prove that if conditions I-II (below) hold and there is a sequence of Boolean functions fn hard to approximate by p-size circuits such that p-size circuit lower bounds for fn do not have p-size proofs in Extended Frege system EF, then P NP. I. S12 proves that a concrete function in E is hard to approximate by subexponential-size circuits. II. [Learning from ∃ OWF.] S12 proves that a p-time reduction transforms circuits breaking one-way functions to p-size circuits learning p-size circuits over the uniform distribution, with membership queries. Here, S12 is Buss's theory of bounded arithmetic formalizing p-time reasoning. Further, we show that any of the following assumptions implies that P NP, if EF is not p-bounded: 1. [Feasible anticheckers.] S12 proves that a p-time function generates anticheckers for SAT. 2. [Witnessing NP⊂eq P/poly.] S12 proves that a p-time function witnesses an error of each p-size circuit which fails to solve SAT. 3. [OWF from NP⊂eq P/poly \& hardness of E.] Condition I holds and S12 proves that a p-time reduction transforms circuits breaking one-way functions to p-size circuits computing SAT. The results generalize to stronger theories and proof systems.

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