English

Parameterized Complexity of Streaming Diameter and Connectivity Problems

Data Structures and Algorithms 2024-07-19 v2 Computational Complexity Discrete Mathematics

Abstract

We initiate the investigation of the parameterized complexity of Diameter and Connectivity in the streaming paradigm. On the positive end, we show that knowing a vertex cover of size kk allows for algorithms in the Adjacency List (AL) streaming model whose number of passes is constant and memory is O(logn)O(\log n) for any fixed kk. Underlying these algorithms is a method to execute a breadth-first search in O(k)O(k) passes and O(klogn)O(k \log n) bits of memory. On the negative end, we show that many other parameters lead to lower bounds in the AL model, where Ω(n/p)\Omega(n/p) bits of memory is needed for any pp-pass algorithm even for constant parameter values. In particular, this holds for graphs with a known modulator (deletion set) of constant size to a graph that has no induced subgraph isomorphic to a fixed graph HH, for most HH. For some cases, we can also show one-pass, Ω(nlogn)\Omega(n \log n) bits of memory lower bounds. We also prove a much stronger Ω(n2/p)\Omega(n^2/p) lower bound for Diameter on bipartite graphs. Finally, using the insights we developed into streaming parameterized graph exploration algorithms, we show a new streaming kernelization algorithm for computing a vertex cover of size kk. This yields a kernel of 2k2k vertices (with O(k2)O(k^2) edges) produced as a stream in poly(k)\text{poly}(k) passes and only O(klogn)O(k \log n) bits of memory.

Keywords

Cite

@article{arxiv.2207.04872,
  title  = {Parameterized Complexity of Streaming Diameter and Connectivity Problems},
  author = {Jelle J. Oostveen and Erik Jan van Leeuwen},
  journal= {arXiv preprint arXiv:2207.04872},
  year   = {2024}
}
R2 v1 2026-06-25T00:48:47.723Z