Random Permutations in Computational Complexity
Abstract
Classical results of Bennett and Gill (1981) show that with probability 1, PA ≠ NPA relative to a random oracle A, and with probability 1, Pπ ≠ NPπ coNPπ relative to a random permutation π. Whether PA = NPA coNPA holds relative to a random oracle A remains open. While the random oracle separation has been extended to specific individually random oracles--such as Martin-L\"of random or resource-bounded random oracles--no analogous result is known for individually random permutations. We introduce a new resource-bounded measure framework for analyzing individually random permutations. We define permutation martingales and permutation betting games that characterize measure-zero sets in the space of permutations, enabling formal definitions of resource-bounded random permutations. Our main result shows that Pπ ≠ NPπ coNPπ for every polynomial-time betting-game random permutation π. This is the first separation result relative to individually random permutations, rather than an almost-everywhere separation. We also strengthen a quantum separation of Bennett, Bernstein, Brassard, and Vazirani (1997) by showing that NPπ coNPπ ⊂eq BQPπ for every polynomial-space random permutation π. We investigate the relationship between random permutations and random oracles. We prove that random oracles are polynomial-time reducible from random permutations. The converse--whether every random permutation is reducible from a random oracle--remains open. We show that if NP coNP is not a measurable subset of EXP, then PA ≠ NPA coNPA holds with probability 1 relative to a random oracle A. Conversely, establishing this random oracle separation with time-bounded measure would imply BPP is a measure 0 subset of EXP.
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