TY - GEN
T1 - On Time-Space Tradeoffs for Bounded-Length Collisions in Merkle-Damgård Hashing
AU - Ghoshal, Ashrujit
AU - Komargodski, Ilan
N1 - Publisher Copyright: © 2022, International Association for Cryptologic Research.
PY - 2022
Y1 - 2022
N2 - We study the power of preprocessing adversaries in finding bounded-length collisions in the widely used Merkle-Damgård (MD) hashing in the random oracle model. Specifically, we consider adversaries with arbitrary S-bit advice about the random oracle and can make at most T queries to it. Our goal is to characterize the advantage of such adversaries in finding a B-block collision in an MD hash function constructed using the random oracle with range size N as the compression function (given a random salt). The answer to this question is completely understood for very large values of B (essentially Ω(T) ) as well as for B= 1, 2. For B≈ T, Coretti et al. (EUROCRYPT ’18) gave matching upper and lower bounds of Θ~ (ST2/ N). Akshima et al. (CRYPTO ’20) observed that the attack of Coretti et al. could be adapted to work for any value of B> 1, giving an attack with advantage Ω~ (STB/ N+ T2/ N). Unfortunately, they could only prove that this attack is optimal for B= 2. Their proof involves a compression argument with exhaustive case analysis and, as they claim, a naive attempt to generalize their bound to larger values of B (even for B= 3 ) would lead to an explosion in the number of cases needed to be analyzed, making it unmanageable. With the lack of a more general upper bound, they formulated the STB conjecture, stating that the best-possible advantage is O~ (STB/ N+ T2/ N) for any B> 1. In this work, we confirm the STB conjecture in many new parameter settings. For instance, in one result, we show that the conjecture holds for all constant values of B. Further, using combinatorial properties of graphs, we are able to confirm the conjecture even for super constant values of B, as long as some restriction is made on S. For instance, we confirm the conjecture for all B⩽ T1 / 4 as long as S⩽ T1 / 8. Technically, we develop structural characterizations for bounded-length collisions in MD hashing that allow us to give a compression argument in which the number of cases needed to be handled does not explode.
AB - We study the power of preprocessing adversaries in finding bounded-length collisions in the widely used Merkle-Damgård (MD) hashing in the random oracle model. Specifically, we consider adversaries with arbitrary S-bit advice about the random oracle and can make at most T queries to it. Our goal is to characterize the advantage of such adversaries in finding a B-block collision in an MD hash function constructed using the random oracle with range size N as the compression function (given a random salt). The answer to this question is completely understood for very large values of B (essentially Ω(T) ) as well as for B= 1, 2. For B≈ T, Coretti et al. (EUROCRYPT ’18) gave matching upper and lower bounds of Θ~ (ST2/ N). Akshima et al. (CRYPTO ’20) observed that the attack of Coretti et al. could be adapted to work for any value of B> 1, giving an attack with advantage Ω~ (STB/ N+ T2/ N). Unfortunately, they could only prove that this attack is optimal for B= 2. Their proof involves a compression argument with exhaustive case analysis and, as they claim, a naive attempt to generalize their bound to larger values of B (even for B= 3 ) would lead to an explosion in the number of cases needed to be analyzed, making it unmanageable. With the lack of a more general upper bound, they formulated the STB conjecture, stating that the best-possible advantage is O~ (STB/ N+ T2/ N) for any B> 1. In this work, we confirm the STB conjecture in many new parameter settings. For instance, in one result, we show that the conjecture holds for all constant values of B. Further, using combinatorial properties of graphs, we are able to confirm the conjecture even for super constant values of B, as long as some restriction is made on S. For instance, we confirm the conjecture for all B⩽ T1 / 4 as long as S⩽ T1 / 8. Technically, we develop structural characterizations for bounded-length collisions in MD hashing that allow us to give a compression argument in which the number of cases needed to be handled does not explode.
UR - http://www.scopus.com/inward/record.url?scp=85141693814&partnerID=8YFLogxK
U2 - 10.1007/978-3-031-15982-4_6
DO - 10.1007/978-3-031-15982-4_6
M3 - منشور من مؤتمر
SN - 9783031159817
T3 - Lecture Notes in Computer Science
SP - 161
EP - 191
BT - Advances in Cryptology – CRYPTO 2022 - 42nd Annual International Cryptology Conference, CRYPTO 2022, Proceedings
A2 - Dodis, Yevgeniy
A2 - Shrimpton, Thomas
PB - Springer Science and Business Media Deutschland GmbH
T2 - 42nd Annual International Cryptology Conference, CRYPTO 2022
Y2 - 15 August 2022 through 18 August 2022
ER -