TY - GEN
T1 - Proving hard-core predicates using list decoding
AU - Akavia, A.
AU - Goldwasser, S.
AU - Safra, S.
N1 - Publisher Copyright:
© 2003 IEEE.
PY - 2003
Y1 - 2003
N2 - We introduce a unifying framework for proving that predicate P is hard-core for a one-way function f, and apply it to a broad family of functions and predicates, reproving old results in an entirely different way as well as showing new hard-core predicates for well known one-way function candidates. Our framework extends the list-coding method of Goldreich and Levin for showing hard-core predicates. Namely, a predicate will correspond to some error correcting code, predicting a predicate will correspond to access to a corrupted codeword, and the task of inverting one-way functions will correspond to the task of list decoding a corrupted codeword. A characteristic of the error correcting codes which emerge and are addressed by our framework is that codewords can be approximated by a small number of heavy coefficients in their Fourier representation. Moreover, as long as corrupted words are close enough to legal codewords, they will share a heavy Fourier coefficient. We list decodes, by devising a learning algorithm applied to corrupted codewords for learning heavy Fourier coefficients. For codes defined over {0, 1}n domain, a learning algorithm by Kushilevitz and Mansour already exists. For codes defined over ZN, which are the codes which emerge for predicates based on number theoretic one-way functions such as the RSA and Exponentiation modulo primes, we develop a new learning algorithm. This latter algorithm may be of independent interest outside the realm of hard-core predicates.
AB - We introduce a unifying framework for proving that predicate P is hard-core for a one-way function f, and apply it to a broad family of functions and predicates, reproving old results in an entirely different way as well as showing new hard-core predicates for well known one-way function candidates. Our framework extends the list-coding method of Goldreich and Levin for showing hard-core predicates. Namely, a predicate will correspond to some error correcting code, predicting a predicate will correspond to access to a corrupted codeword, and the task of inverting one-way functions will correspond to the task of list decoding a corrupted codeword. A characteristic of the error correcting codes which emerge and are addressed by our framework is that codewords can be approximated by a small number of heavy coefficients in their Fourier representation. Moreover, as long as corrupted words are close enough to legal codewords, they will share a heavy Fourier coefficient. We list decodes, by devising a learning algorithm applied to corrupted codewords for learning heavy Fourier coefficients. For codes defined over {0, 1}n domain, a learning algorithm by Kushilevitz and Mansour already exists. For codes defined over ZN, which are the codes which emerge for predicates based on number theoretic one-way functions such as the RSA and Exponentiation modulo primes, we develop a new learning algorithm. This latter algorithm may be of independent interest outside the realm of hard-core predicates.
KW - Computer science
KW - Decoding
UR - http://www.scopus.com/inward/record.url?scp=33746330387&partnerID=8YFLogxK
U2 - 10.1109/SFCS.2003.1238189
DO - 10.1109/SFCS.2003.1238189
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AN - SCOPUS:33746330387
T3 - Proceedings - Annual IEEE Symposium on Foundations of Computer Science, FOCS
SP - 146
EP - 157
BT - Proceedings - 44th Annual IEEE Symposium on Foundations of Computer Science, FOCS 2003
PB - IEEE Computer Society
T2 - 44th Annual IEEE Symposium on Foundations of Computer Science, FOCS 2003
Y2 - 11 October 2003 through 14 October 2003
ER -