Finding Four-Node Subgraphs in Triangle Time

Williams, Virginia Vassilevska; Wang, Joshua R.; Williams, Ryan; Yu, Huacheng

doi:10.1137/1.9781611973730.111

Cited by 39 publications

(45 citation statements)

References 14 publications

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“…It is unlikely that the problem can be solved in o(n α )-time by Theorem 6 (recall that the two problems of triangle detection and matrix multiplication are assumed to be equivalent [43,42]). Finally, we proved in Theorem 9 that for every graph G with bounded clique-number ω, the clique minimal separator decomposition of G can be computed in O(T (G) + ω 2 n)-time where T (G) here denotes the time needed to compute a minimal triangulation of G. We conjecture that in fact, it can be computed in O(ω O(1) (n + m))-time.…”

Section: Resultsmentioning

confidence: 99%

“…Altogether, this is hint that ourÕ(n α )-time clique minimal separator decomposition algorithm is optimal up to polylogarithmic factors -assuming the computational equivalence between triangle detection and matrix multiplication [43,42].…”

Section: Introductionmentioning

confidence: 87%

“…This combined with standard complexity assumptions -such as the Strong Exponential-Time Hypothesis [31] -allows one to prove conditional time complexity lower bounds for many problems in P, and unsuspected relationships between these problems. In our case we will assume, like in [42], the computational equivalence between Triangle Detection and Matrix Multiplication. This equivalence has been proved in [43] for combinatorial algorithms (i.e., not using algebraic methods).…”

Section: Introductionmentioning

confidence: 99%

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Revisiting Decomposition by Clique Separators

Coudert¹,

Ducoffe²

2018

SIAM J. Discrete Math.

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We study the complexity of decomposing a graph by means of clique separators. This common algorithmic tool, first introduced by Tarjan, allows to cut a graph into smaller pieces, and so, it can be applied to preprocess the graph in the computation of optimization problems. However, the best-known algorithms for computing a decomposition have respective O(nm)-time and O(n (3+α)/2 ) = o(n 2.69 )-time complexity, with α < 2.3729 being the exponent for matrix multiplication. Such running times are prohibitive for large graphs. Here we prove that for every graph G, a decomposition can be computed in O(T (G) + min{n α , ω 2 n})-time with T (G) and ω being respectively the time needed to compute a minimal triangulation of G and the clique-number of G. In particular, it implies that every graph can be decomposed by clique separators in O(n α log n)-time. Based on prior work from Kratsch et al., we prove in addition that decomposing a graph by clique-separators is as least as hard as triangle detection. Therefore, the existence of any o(n α )-time algorithm for this problem would be a significant breakthrough in the field of algorithmic. Finally, our main result implies that planar graphs, bounded-treewidth graphs and bounded-degree graphs can be decomposed by clique separators in linear or quasi-linear time.

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Section: Resultsmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 87%

Section: Introductionmentioning

confidence: 99%

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Revisiting Decomposition by Clique Separators

Coudert¹,

Ducoffe²

2018

SIAM J. Discrete Math.

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“…In a subsequent paper, after the submission of this work, Vassilevska Williams et al [21] presented several improved upper bounds on the detection of induced subgraphs on four vertices and even some induced subgraphs on five vertices (e.g., the chair and 4-pan). By using a polynomial testing framework similar to that in this paper, they have shown in particular that any induced subgraph on four vertices, with the exception of K 4 and the independent set on four vertices, can be detected by a randomized algorithm in O(n ω ) time.…”

Section: Final Remarkmentioning

confidence: 99%

“…By using a polynomial testing framework similar to that in this paper, they have shown in particular that any induced subgraph on four vertices, with the exception of K 4 and the independent set on four vertices, can be detected by a randomized algorithm in O(n ω ) time. The improved upper time bounds presented in [21] are noncombinatorial as they rely on fast matrix multiplication.…”

Section: Final Remarkmentioning

confidence: 99%

Detecting and Counting Small Pattern Graphs

Floderus¹,

Kowaluk²,

Lingas³

et al. 2015

SIAM J. Discrete Math.

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We study the induced subgraph isomorphism problem and the general subgraph isomorphism problem for small pattern graphs. We present a new general method for detecting induced subgraphs of a host graph isomorphic to a fixed pattern graph by reduction to polynomial testing for nonidentity with zero over a field of finite characteristic. It yields new upper time bounds for several pattern graphs on five vertices and provides an alternative combinatorial method for the majority of pattern graphs on four and three vertices. Since our method avoids the large overhead of fast matrix multiplication, it can be of practical interest even for larger pattern graphs. Next, we derive new upper time bounds on counting the number of isomorphisms between a fixed pattern graph with an independent set of size s and a subgraph of the host graph. We also consider a weighted version of the counting problem, when one counts the number of isomorphisms between the pattern graph and lightest subgraphs, providing a slightly slower combinatorial algorithm.

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Bisimplicial separators

Milanič,

Penev,

Pivač

et al. 2024

Journal of Graph Theory

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A minimal separator of a graph is a set such that there exist vertices with the property that separates from in , but no proper subset of does. For an integer , we say that a minimal separator is ‐simplicial if it can be covered by cliques and denote by the class of all graphs in which each minimal separator is ‐simplicial. We show that for each , the class is closed under induced minors, and we use this to show that the Maximum Weight Stable Set problem can be solved in polynomial time for . We also give a complete list of minimal forbidden induced minors for . Next, we show that, for , every nonnull graph in has a ‐simplicial vertex, that is, a vertex whose neighborhood is a union of cliques; we deduce that the Maximum Weight Clique problem can be solved in polynomial time for graphs in . Further, we show that, for , it is NP‐hard to recognize graphs in ; the time complexity of recognizing graphs in is unknown. We also show that the Maximum Clique problem is NP‐hard for graphs in . Finally, we prove a decomposition theorem for diamond‐free graphs in (where the diamond is the graph obtained from by deleting one edge), and we use this theorem to obtain polynomial‐time algorithms for the Vertex Coloring and recognition problems for diamond‐free graphs in , and improved running times for the Maximum Weight Clique and Maximum Weight Stable Set problems for this class of graphs.

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Finding Four-Node Subgraphs in Triangle Time

Cited by 39 publications

References 14 publications

Revisiting Decomposition by Clique Separators

Revisiting Decomposition by Clique Separators

Detecting and Counting Small Pattern Graphs

Bisimplicial separators

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