In this paper, we discuss the maximum flow problem in the two-party communication model, where two parties, each holding a subset of edges on a common vertex set, aim to compute the maximum flow of the union graph with minimal communication. We show that this can be solved with $\tilde{O}(n^{1.5})$ bits of communication, improving upon the trivial $\tilde{O}(n^2)$ bound. To achieve this, we derive two additional, more general results: 1. We present a randomized algorithm for linear programs with two-sided constraints that requires $\tilde{O}(n^{1.5}k)$ bits of communication when each constraint has at most $k$ non-zeros. This result improves upon the prior work by [Ghadiri, Lee, Padmanabhan, Swartworth, Woodruff, Ye, STOC'24], which achieves a complexity of $\tilde{O}(n^2)$ bits for LPs with one-sided constraints. Upon more precise analysis, their algorithm can reach a bit complexity of $\tilde{O}(n^{1.5} + nk)$ for one-sided constraint LPs. Nevertheless, for sparse matrices, our approach matches this complexity while extending the scope to two-sided constraints. 2. Leveraging this result, we demonstrate that the minimum cost flow problem, as a special case of solving linear programs with two-sided constraints and as a general case of maximum flow problem, can also be solved with a communication complexity of $\tilde{O}(n^{1.5})$ bits. These results are achieved by adapting an interior-point method (IPM)-based algorithm for solving LPs with two-sided constraints in the sequential setting by [van den Brand, Lee, Liu, Saranurak, Sidford, Song, Wang, STOC'21] to the two-party communication model. This adaptation utilizes techniques developed by [Ghadiri, Lee, Padmanabhan, Swartworth, Woodruff, Ye, STOC'24] for distributed convex optimization.
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