Finding Hash Collisions with Quantum Computers by Using Differential Trails with Smaller Probability than Birthday Bound

Abstract: In this paper we spot light on dedicated quantum collision attacks on concrete hash functions, which has not received much attention so far. In the classical setting, the generic complexity to find collisions of an n -bit hash function is , thus classical collision attacks based on differential cryptanalysis such as rebound attacks build differential trails with probability higher than . By the same analogy, generic quantum algorithms such as the BHT algorithm fin… Show more

“…This attack is more efficient than a generic one for 18 rounds classically, and up to 20 quantumly. As a side note, these results provide a new example where quantum attacks reach more rounds than classical ones, much like in [21].…”

“…We consider 8 rounds of Gimli, e.g. rounds 21 to 14 included, and name Gimli (21,14) this reduced-round permutation. We omit the last swap, because it has no incidence (it only swaps values).…”

“…Putting both Steps Together. With these solutions, we built two collisions on 8round Gimli (21,14). We start from 1 , 0, 0, 0, then after one round, we inject the values 21 , 21 , 21 , 21 and ′21 , 21 , 21 , 21 respectively in the rate; then we obtain two states that differ only on the -coordinate of the third column (not the first, due to a big swap), and we inject two different blocks to cancel out this difference, obtaining the same state.…”

“…Different choices are possible, which are detailed e.g. in [21]. In short, the overall cost of quantum collision search depends on the cost that is assigned to quantum hardware.…”

“…Quantum collision attacks reaching more rounds than classical ones. In [21], Hosoyamada and Sasaki initiated the study of dedicated quantum attacks on hash functions. They remarked that quantum collision search does not benefit from a square-root speedup (it goes from roughly 2 /2 to 2 /3 with the BHT algorithm, and the gain is even smaller in more constrained models of quantum hardware), while some collision-finding procedures may have a better speedup, say, quadratic.…”

New Results on Gimli: Full-Permutation Distinguishers and Improved Collisions

“…This attack is more efficient than a generic one for 18 rounds classically, and up to 20 quantumly. As a side note, these results provide a new example where quantum attacks reach more rounds than classical ones, much like in [21].…”

“…We consider 8 rounds of Gimli, e.g. rounds 21 to 14 included, and name Gimli (21,14) this reduced-round permutation. We omit the last swap, because it has no incidence (it only swaps values).…”

“…Putting both Steps Together. With these solutions, we built two collisions on 8round Gimli (21,14). We start from 1 , 0, 0, 0, then after one round, we inject the values 21 , 21 , 21 , 21 and ′21 , 21 , 21 , 21 respectively in the rate; then we obtain two states that differ only on the -coordinate of the third column (not the first, due to a big swap), and we inject two different blocks to cancel out this difference, obtaining the same state.…”

“…Different choices are possible, which are detailed e.g. in [21]. In short, the overall cost of quantum collision search depends on the cost that is assigned to quantum hardware.…”

“…Quantum collision attacks reaching more rounds than classical ones. In [21], Hosoyamada and Sasaki initiated the study of dedicated quantum attacks on hash functions. They remarked that quantum collision search does not benefit from a square-root speedup (it goes from roughly 2 /2 to 2 /3 with the BHT algorithm, and the gain is even smaller in more constrained models of quantum hardware), while some collision-finding procedures may have a better speedup, say, quadratic.…”

New Results on Gimli: Full-Permutation Distinguishers and Improved Collisions

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