On Hardness Assumptions Needed for "Extreme High-End'' PRGs and Fast Derandomization
Abstract
The hardness vs.~randomness paradigm aims to explicitly construct pseudorandom generators G:\0,1\r → \0,1\m that fool circuits of size m, assuming the existence of explicit hard functions. A ``high-end PRG'' with seed length r=O( m) (implying BPP=P) was achieved in a seminal work of Impagliazzo and Wigderson (STOC 1997), assuming the high-end hardness assumption: there exist constants 0<β < 1< B, and functions computable in time 2B · n that cannot be computed by circuits of size 2β · n. Recently, motivated by fast derandomization of randomized algorithms, Doron et al.~(FOCS 2020) and Chen and Tell (STOC 2021), construct ``extreme high-end PRGs'' with seed length r=(1+o(1))· m, under qualitatively stronger assumptions. We study whether extreme high-end PRGs can be constructed from the following scaled version of the assumption which we call ``the extreme high-end hardness assumption'', and in which β=1-o(1) and B=1+o(1). We give a partial negative answer, showing that certain approaches cannot yield a black-box proof. (A longer abstract with more details appears in the PDF file)
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