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Title:
An Algorithmic Framework for the Generalized Birthday Problem
Authors: Itai Dinur
Abstract:The generalized birthday problem (GBP) was introduced by Wagner in 2002 and has shown to have many applications in cryptanalysis. In its typical variant, we are given access to a function H:\{0,1\}^{\ell} \rightarrow \{0,1\}^n (whose specification depends on the underlying problem) and an integer K>0. The goal is to find K distinct inputs to H (denoted by \{x_i\}_{i=1}^{K}) such that \sum_{i=1}^{K}H(x_i) = 0. Wagner’s K-tree algorithm solves the problem in time and memory complexities of about N^{1/(\lfloor \log K \rfloor + 1)} (where N= 2^n). Two important open problems raised by Wagner were (1) devise efficient time-memory tradeoffs for GBP, and (2) reduce the complexity of the K-tree algorithm for K which is not a power of 2. In this paper, we make progress in both directions. First, we improve the best know GBP time-memory tradeoff curve (published by independently by Nikolić and Sasaki and also by Biryukov and Khovratovich) for all K \geq 8 from T^2M^{\lfloor \log K \rfloor -1} = N to T^{\lceil (\log K)/2 \rceil + 1 }M^{\lfloor (\log K)/2 \rfloor} = N, applicable for a large range of parameters. For example, for K = 8 we improve the best previous tradeoff from T^2M^2 = N to T^3M = N and for K = 32 the improvement is from T^2M^4 = N to T^4M^2 = N. Next, we consider values of K which are not powers of 2 and show that in many cases even more efficient time-memory tradeoff curves can be obtained. Most interestingly, for K \in \{6,7,14,15\} we present algorithms with the same time complexities as the K-tree algorithm, but with significantly reduced memory complexities. In particular, for K=6 the K-tree algorithm achieves T=M=N^{1/3}, whereas we obtain T=N^{1/3} and M=N^{1/6}. For K=14, Wagner’s algorithm achieves T=M=N^{1/4}, while we obtain T=N^{1/4} and M=N^{1/8}. This gives the first significant improvement over the K-tree algorithm for small K. Finally, we optimize our techniques for several concrete GBP instances and show how to solve some of them with improved time and memory complexities compared to the state-of-the-art. Our results are obtained using a framework that combines several algorithmic techniques such as variants of the Schroeppel-Shamir algorithm for solving knapsack problems (devised in works by Howgrave-Graham and Joux and by Becker, Coron and Joux) and dissection algorithms (published by Dinur, Dunkelman, Keller and Shamir). It then builds on these techniques to develop new GBP algorithms.
ePrint: https://eprint.iacr.org/2018/575
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