Your search keyword '"WATRIGANT, RÉMI"' showing total 123 results

1. Identifying hard native instances for the maximum independent set problem on neutral atoms quantum processors

Author

Cazals, Pierre, François, Aymeric, Henriet, Loïc, Leclerc, Lucas, Marin, Malory, Naghmouchi, Yassine, Coelho, Wesley da Silva, Sikora, Florian, Vitale, Vittorio, Watrigant, Rémi, Garzillo, Monique Witt, and Dalyac, Constantin

Subjects

Quantum Physics

Abstract

The Maximum Independent Set (MIS) problem is a fundamental combinatorial optimization task that can be naturally mapped onto the Ising Hamiltonian of neutral atom quantum processors. Given its connection to NP-hard problems and real-world applications, there has been significant experimental interest in exploring quantum advantage for MIS. Pioneering experiments on King's Lattice graphs suggested a quadratic speed-up over simulated annealing, but recent benchmarks using state-of-the-art methods found no clear advantage, likely due to the structured nature of the tested instances. In this work, we generate hard instances of unit-disk graphs by leveraging complexity theory results and varying key hardness parameters such as density and treewidth. For a fixed graph size, we show that increasing these parameters can lead to prohibitive classical runtime increases of several orders of magnitude. We then compare classical and quantum approaches on small instances and find that, at this scale, quantum solutions are slower than classical ones for finding exact solutions. Based on extended classical benchmarks at larger problem sizes, we estimate that scaling up to a thousand atoms with a 1 kHz repetition rate is a necessary step toward demonstrating a computational advantage with quantum methods., Comment: 11 pages, 5 figures

Published

2025

2. A structural description of Zykov and Blanche Descartes graphs

Author

Marin, Malory, Thomassé, Stéphan, Trotignon, Nicolas, and Watrigant, Rémi

Subjects

Mathematics - Combinatorics, Computer Science - Computational Complexity, Computer Science - Discrete Mathematics

Abstract

In 1949, Zykov proposed the first explicit construction of triangle-free graphs with arbitrarily large chromatic number. We define a Zykov graph as any induced subgraph of a graph created using Zykov's construction. We give a structural characterization of Zykov graphs based on a specific type of stable set, that we call splitting stable set. It implies that recognizing this class is NP-complete, while being FPT in the treewidth of the input graph. We provide similar results for the Blanche Descartes construction.

Published

2024

3. Channel allocation revisited through 1-extendability of graphs

Author

Busson, Anthony, Marin, Malory, and Watrigant, Rémi

Subjects

Computer Science - Data Structures and Algorithms, Computer Science - Computational Complexity, Computer Science - Discrete Mathematics

Abstract

We revisit the classical problem of channel allocation for Wi-Fi access points (AP). Using mechanisms such as the CSMA/CA protocol, Wi-Fi access points which are in conflict within a same channel are still able to communicate to terminals. In graph theoretical terms, it means that it is not mandatory for the channel allocation to correspond to a proper coloring of the conflict graph. However, recent studies suggest that the structure -- rather than the number -- of conflicts plays a crucial role in the performance of each AP. More precisely, the graph induced by each channel must satisfy the so-called $1$-extendability property, which requires each vertex to be contained in an independent set of maximum cardinality. In this paper we introduce the 1-extendable chromatic number, which is the minimum size of a partition of the vertex set of a graph such that each part induces a 1-extendable graph. We study this parameter and the related optimization problem through different perspectives: algorithms and complexity, structure, and extremal properties. We first show how to compute this number using modular decompositions of graphs, and analyze the running time with respect to the modular width of the input graph. We also focus on the special case of cographs, and prove that the 1-extendable chromatic number can be computed in quasi-polynomial time in this class. Concerning extremal results, we show that the 1-extendable chromatic number of a graph with $n$ vertices is at most $2\sqrt{n}$, whereas the classical chromatic number can be as large as $n$. We are also able to construct graphs whose 1-extendable chromatic number is at least logarithmic in the number of vertices., Comment: Extended abstract in ALGOWIN 2024

Published

2024

4. Beyond Recognizing Well-Covered Graphs

Author

Feghali, Carl, Marin, Malory, Watrigant, Rémi, Goos, Gerhard, Series Editor, Hartmanis, Juris, Founding Editor, Bertino, Elisa, Editorial Board Member, Gao, Wen, Editorial Board Member, Steffen, Bernhard, Editorial Board Member, Yung, Moti, Editorial Board Member, Kráľ, Daniel, editor, and Milanič, Martin, editor

Published

2025

5. Channel Allocation Revisited Through 1-Extendability of Graphs

Author

Busson, Anthony, Marin, Malory, Watrigant, Rémi, Goos, Gerhard, Series Editor, Hartmanis, Juris, Founding Editor, Bertino, Elisa, Editorial Board Member, Gao, Wen, Editorial Board Member, Steffen, Bernhard, Editorial Board Member, Yung, Moti, Editorial Board Member, Bramas, Quentin, editor, Casteigts, Arnaud, editor, and Meeks, Kitty, editor

Published

2025

6. Beyond recognizing well-covered graphs

Author

Feghali, Carl, Marin, Malory, and Watrigant, Rémi

Subjects

Mathematics - Combinatorics, Computer Science - Discrete Mathematics

Abstract

We prove a number of results related to the computational complexity of recognizing well-covered graphs. Let $k$ and $s$ be positive integers and let $G$ be a graph. Then $G$ is said - $\mathbf{W_k}$ if for any $k$ pairwise disjoint independent vertex sets $A_1, \dots, A_k$ in $G$, there exist $k$ pairwise disjoint maximum independent sets $S_1, \dots,S_k$ in $G$ such that $A_i \subseteq S_i$ for $i \in [k]$. - $\mathbf{E_s}$ if every independent set in $G$ of size at most $s$ is contained in a maximum independent set in $G$. Chv\'atal and Slater (1993) and Sankaranarayana and Stewart (1992) famously showed that recognizing $\mathbf{W_1}$ graphs or, equivalently, well-covered graphs is coNP-complete. We extend this result by showing that recognizing $\mathbf{W_{k+1}}$ graphs in either $\mathbf{W_k}$ or $\mathbf{E_s}$ graphs is coNP-complete. This answers a question of Levit and Tankus (2023) and strengthens a theorem of Feghali and Marin (2024). We also show that recognizing $\mathbf{E_{s+1}}$ graphs is $\Theta_2^p$-complete even in $\mathbf{E_s}$ graphs, where $\Theta_2^p = \text{P}^{\text{NP}[\log]}$ is the class of problems solvable in polynomial time using a logarithmic number of calls to a SAT oracle. This strengthens a theorem of Berg\'e, Busson, Feghali and Watrigant (2023). We also obtain the complete picture of the complexity of recognizing chordal $\mathbf{W_k}$ and $\mathbf{E_s}$ graphs which, in particular, simplifies and generalizes a result of Dettlaff, Henning and Topp (2023)., Comment: Preliminary version

Published

2024

7. 1-Extendability of Independent Sets

Author

Bergé, Pierre, Busson, Anthony, Feghali, Carl, and Watrigant, Rémi

Published

2024

8. Approximating Highly Inapproximable Problems on Graphs of Bounded Twin-Width

Author

Bergé, Pierre, Bonnet, Édouard, Déprés, Hugues, and Watrigant, Rémi

Subjects

Computer Science - Data Structures and Algorithms, Computer Science - Computational Complexity, Computer Science - Discrete Mathematics, Mathematics - Combinatorics, 68W25, F.2.2

Abstract

For any $\varepsilon > 0$, we give a polynomial-time $n^\varepsilon$-approximation algorithm for Max Independent Set in graphs of bounded twin-width given with an $O(1)$-sequence. This result is derived from the following time-approximation trade-off: We establish an $O(1)^{2^q-1}$-approximation algorithm running in time $\exp(O_q(n^{2^{-q}}))$, for every integer $q \geqslant 0$. Guided by the same framework, we obtain similar approximation algorithms for Min Coloring and Max Induced Matching. In general graphs, all these problems are known to be highly inapproximable: for any $\varepsilon > 0$, a polynomial-time $n^{1-\varepsilon}$-approximation for any of them would imply that P$=$NP [Hastad, FOCS '96; Zuckerman, ToC '07; Chalermsook et al., SODA '13]. We generalize the algorithms for Max Independent Set and Max Induced Matching to the independent (induced) packing of any fixed connected graph $H$. In contrast, we show that such approximation guarantees on graphs of bounded twin-width given with an $O(1)$-sequence are very unlikely for Min Independent Dominating Set, and somewhat unlikely for Longest Path and Longest Induced Path. Regarding the existence of better approximation algorithms, there is a (very) light evidence that the obtained approximation factor of $n^\varepsilon$ for Max Independent Set may be best possible. This is the first in-depth study of the approximability of problems in graphs of bounded twin-width. Prior to this paper, essentially the only such result was a~polynomial-time $O(1)$-approximation algorithm for Min Dominating Set [Bonnet et al., ICALP '21]., Comment: 32 pages, 3 figures, 1 table

Published

2022

9. 1-Extendability of independent sets

Author

Bergé, Pierre, Busson, Anthony, Feghali, Carl, and Watrigant, Rémi

Subjects

Computer Science - Computational Complexity, Computer Science - Data Structures and Algorithms

Abstract

In the 70s, Berge introduced 1-extendable graphs (also called B-graphs), which are graphs where every vertex belongs to a maximum independent set. Motivated by an application in the design of wireless networks, we study the computational complexity of 1-extendability, the problem of deciding whether a graph is 1-extendable. We show that, in general, 1-extendability cannot be solved in $2^{o(n)}$ time assuming the Exponential Time Hypothesis, where $n$ is the number of vertices of the input graph, and that it remains NP-hard in subcubic planar graphs and in unit disk graphs (which is a natural model for wireless networks). Although 1-extendability seems to be very close to the problem of finding an independent set of maximum size (a.k.a. Maximum Independent Set), we show that, interestingly, there exist 1-extendable graphs for which Maximum Independent Set is NP-hard. Finally, we investigate a parameterized version of 1-extendability., Comment: Extended abstract in IWOCA 2022

Published

2022

10. Twin-width and polynomial kernels

Author

Bonnet, Édouard, Kim, Eun Jung, Reinald, Amadeus, Thomassé, Stéphan, and Watrigant, Rémi

Subjects

Computer Science - Data Structures and Algorithms, Computer Science - Computational Complexity, Computer Science - Discrete Mathematics, Mathematics - Combinatorics, 05C85, F.2.2

Abstract

We study the existence of polynomial kernels, for parameterized problems without a polynomial kernel on general graphs, when restricted to graphs of bounded twin-width. Our main result is that a polynomial kernel for $k$-Dominating Set on graphs of twin-width at most 4 would contradict a standard complexity-theoretic assumption. The reduction is quite involved, especially to get the twin-width upper bound down to 4, and can be tweaked to work for Connected $k$-Dominating Set and Total $k$-Dominating Set (albeit with a worse upper bound on the twin-width). The $k$-Independent Set problem admits the same lower bound by a much simpler argument, previously observed [ICALP '21], which extends to $k$-Independent Dominating Set, $k$-Path, $k$-Induced Path, $k$-Induced Matching, etc. On the positive side, we obtain a simple quadratic vertex kernel for Connected $k$-Vertex Cover and Capacitated $k$-Vertex Cover on graphs of bounded twin-width. Interestingly the kernel applies to graphs of Vapnik-Chervonenkis density 1, and does not require a witness sequence. We also present a more intricate $O(k^{1.5})$ vertex kernel for Connected $k$-Vertex Cover. Finally we show that deciding if a graph has twin-width at most 1 can be done in polynomial time, and observe that most optimization/decision graph problems can be solved in polynomial time on graphs of twin-width at most 1., Comment: 32 pages, 11 figures

Published

2021

11. Twin-width II: small classes

Author

Bonnet, Édouard, Geniet, Colin, Kim, Eun Jung, Thomassé, Stéphan, and Watrigant, Rémi

Subjects

Twin-width, small classes, expanders, clique subdivisions, sparsity

Abstract

The recently introduced twin-width of a graph $G$ is the minimum integer $d$ such that $G$ has a $d$-contraction sequence, that is, a sequence of $\left| V(G) \right|-1$ iterated vertex identifications for which the overall maximum number of red edges incident to a single vertex is at most $d$, where a red edge appears between two sets of identified vertices if they are not homogeneous in $G$ (not fully adjacent nor fully non-adjacent). We show that if a graph admits a $d$-contraction sequence, then it also has a linear-arity tree of $f(d)$-contractions, for some function $f$. Informally if we accept to worsen the twin-width bound, we can choose the next contraction from a set of $\Theta(\left| V(G) \right|)$ pairwise disjoint pairs of vertices. This has two main consequences. First it permits to show that every bounded twin-width class is small, i.e., has at most $n!c^n$ graphs labeled by $[n]$, for some constant $c$. This unifies and extends the same result for bounded treewidth graphs [Beineke and Pippert, JCT '69], proper subclasses of permutations graphs [Marcus and Tardos, JCTA '04], and proper minor-free classes [Norine et al., JCTB '06]. It implies in turn that bounded-degree graphs, interval graphs, and unit disk graphs have unbounded twin-width. The second consequence is an $O(\log n)$-adjacency labeling scheme for bounded twin-width graphs, confirming several cases of the implicit graph conjecture. We then explore the small conjecture that, conversely, every small hereditary class has bounded twin-width. The conjecture passes many tests. Inspired by sorting networks of logarithmic depth, we show that $\log_{\Theta(\log \log d)}n$-subdivisions of $K_n$ (a small class when $d$ is constant) have twin-width at most $d$. We obtain a rather sharp converse with a surprisingly direct proof: the $\log_{d+1}n$-subdivision of $K_n$ has twin-width at least $d$. Secondly graphs with bounded stack or queue number (also small classes) have bounded twin-width. These sparse classes are surprisingly rich since they contain certain (small) classes of expanders. Thirdly we show that cubic expanders obtained by iterated random 2-lifts from $K_4$ [Bilu and Linial, Combinatorica '06] also have bounded twin-width. These graphs are related to so-called separable permutations and also form a small class. We suggest a promising connection between the small conjecture and group theory. Finally we define a robust notion of sparse twin-width. We show that for a hereditary class $\mathcal C$ of bounded twin-width the five following conditions are equivalent: every graph in $\mathcal C$ (1) has no $K_{t,t}$ subgraph for some fixed $t$, (2) has an adjacency matrix without a $d$-by-$d$ division with a 1 entry in each of the $d^2$ cells for some fixed $d$, (3) has at most linearly many edges, (4) the subgraph closure of $\mathcal C$ has bounded twin-width, and (5) $\mathcal C$ has bounded expansion. We discuss how sparse classes with similar behavior with respect to clique subdivisions compare to bounded sparse twin-width.Mathematics Subject Classifications: 68R10, 05C30, 05C48Keywords: Twin-width, small classes, expanders, clique subdivisions, sparsity

Published

2022

12. Twin-width III: Max Independent Set, Min Dominating Set, and Coloring

Author

Bonnet, Édouard, Geniet, Colin, Kim, Eun Jung, Thomassé, Stéphan, and Watrigant, Rémi

Subjects

Computer Science - Data Structures and Algorithms, Computer Science - Computational Complexity, Computer Science - Discrete Mathematics, Mathematics - Combinatorics, 05C85, F.2.2

Abstract

We recently introduced the graph invariant twin-width, and showed that first-order model checking can be solved in time $f(d,k)n$ for $n$-vertex graphs given with a witness that the twin-width is at most $d$, called $d$-contraction sequence or $d$-sequence, and formulas of size $k$ [Bonnet et al., FOCS '20]. The inevitable price to pay for such a general result is that $f$ is a tower of exponentials of height roughly $k$. In this paper, we show that algorithms based on twin-width need not be impractical. We present $2^{O(k)}n$-time algorithms for $k$-Independent Set, $r$-Scattered Set, $k$-Clique, and $k$-Dominating Set when an $O(1)$-sequence is provided. We further show how to solve weighted $k$-Independent Set, Subgraph Isomorphism, and Induced Subgraph Isomorphism, in time $2^{O(k \log k)}n$. These algorithms are based on a dynamic programming scheme following the sequence of contractions forward. We then show a second algorithmic use of the contraction sequence, by starting at its end and rewinding it. As an example, we establish that bounded twin-width classes are $\chi$-bounded. This significantly extends the $\chi$-boundedness of bounded rank-width classes, and does so with a very concise proof. The third algorithmic use of twin-width builds on the second one. Playing the contraction sequence backward, we show that bounded twin-width graphs can be edge-partitioned into a linear number of bicliques, such that both sides of the bicliques are on consecutive vertices, in a fixed vertex ordering. Given that biclique edge-partition, we show how to solve the unweighted Single-Source Shortest Paths and hence All-Pairs Shortest Paths in sublinear time $O(n \log n)$ and time $O(n^2 \log n)$, respectively. Finally we show that Min Dominating Set and related problems have constant integrality gaps on bounded twin-width classes, thereby getting constant approximations on these classes., Comment: 38 pages, 6 figures. This version contains more results, notably the approximation for Min Dominating Set, and the title has been edited accordingly

Published

2020

13. Twin-width II: small classes

Author

Bonnet, Édouard, Geniet, Colin, Kim, Eun Jung, Thomassé, Stéphan, and Watrigant, Rémi

Subjects

Computer Science - Discrete Mathematics, Computer Science - Data Structures and Algorithms, Computer Science - Logic in Computer Science, Mathematics - Combinatorics, 68R10, 05C30, 05C48, G.2.2

Abstract

The twin-width of a graph $G$ is the minimum integer $d$ such that $G$ has a $d$-contraction sequence, that is, a sequence of $|V(G)|-1$ iterated vertex identifications for which the overall maximum number of red edges incident to a single vertex is at most $d$, where a red edge appears between two sets of identified vertices if they are not homogeneous in $G$. We show that if a graph admits a $d$-contraction sequence, then it also has a linear-arity tree of $f(d)$-contractions, for some function $f$. First this permits to show that every bounded twin-width class is small, i.e., has at most $n!c^n$ graphs labeled by $[n]$, for some constant $c$. This unifies and extends the same result for bounded treewidth graphs [Beineke and Pippert, JCT '69], proper subclasses of permutations graphs [Marcus and Tardos, JCTA '04], and proper minor-free classes [Norine et al., JCTB '06]. The second consequence is an $O(\log n)$-adjacency labeling scheme for bounded twin-width graphs, confirming several cases of the implicit graph conjecture. We then explore the "small conjecture" that, conversely, every small hereditary class has bounded twin-width. Inspired by sorting networks of logarithmic depth, we show that $\log_{\Theta(\log \log d)}n$-subdivisions of $K_n$ (a small class when $d$ is constant) have twin-width at most $d$. We obtain a rather sharp converse with a surprisingly direct proof: the $\log_{d+1}n$-subdivision of $K_n$ has twin-width at least $d$. Secondly graphs with bounded stack or queue number (also small classes) have bounded twin-width. Thirdly we show that cubic expanders obtained by iterated random 2-lifts from $K_4$~[Bilu and Linial, Combinatorica '06] have bounded twin-width, too. We suggest a promising connection between the small conjecture and group theory. Finally we define a robust notion of sparse twin-width and discuss how it compares with other sparse classes., Comment: 37 pages, 9 figures

Published

2020

14. Twin-width I: tractable FO model checking

Author

Bonnet, Édouard, Kim, Eun Jung, Thomassé, Stéphan, and Watrigant, Rémi

Subjects

Computer Science - Data Structures and Algorithms, Computer Science - Discrete Mathematics, Computer Science - Logic in Computer Science, 68Q25, F.2.2

Abstract

Inspired by a width invariant defined on permutations by Guillemot and Marx [SODA '14], we introduce the notion of twin-width on graphs and on matrices. Proper minor-closed classes, bounded rank-width graphs, map graphs, $K_t$-free unit $d$-dimensional ball graphs, posets with antichains of bounded size, and proper subclasses of dimension-2 posets all have bounded twin-width. On all these classes (except map graphs without geometric embedding) we show how to compute in polynomial time a sequence of $d$-contractions, witness that the twin-width is at most $d$. We show that FO model checking, that is deciding if a given first-order formula $\phi$ evaluates to true for a given binary structure $G$ on a domain $D$, is FPT in $|\phi|$ on classes of bounded twin-width, provided the witness is given. More precisely, being given a $d$-contraction sequence for $G$, our algorithm runs in time $f(d,|\phi|) \cdot |D|$ where $f$ is a computable but non-elementary function. We also prove that bounded twin-width is preserved by FO interpretations and transductions (allowing operations such as squaring or complementing a graph). This unifies and significantly extends the knowledge on fixed-parameter tractability of FO model checking on non-monotone classes, such as the FPT algorithm on bounded-width posets by Gajarsk\'y et al. [FOCS '15]., Comment: 49 pages, 9 figures

Published

2020

15. An algorithmic weakening of the Erd\H{o}s-Hajnal conjecture

Author

Bonnet, Édouard, Thomassé, Stéphan, Tran, Xuan Thang, and Watrigant, Rémi

Subjects

Computer Science - Data Structures and Algorithms, Computer Science - Computational Complexity, Computer Science - Discrete Mathematics, 68Q25, 68Q17, 68R10, F.2.2

Abstract

We study the approximability of the Maximum Independent Set (MIS) problem in $H$-free graphs (that is, graphs which do not admit $H$ as an induced subgraph). As one motivation we investigate the following conjecture: for every fixed graph $H$, there exists a constant $\delta > 0$ such that MIS can be $n^{1 - \delta}$-approximated in $H$-free graphs, where $n$ denotes the number of vertices of the input graph. We first prove that a constructive version of the celebrated Erd\H{o}s-Hajnal conjecture implies ours. We then prove that the set of graphs $H$ satisfying our conjecture is closed under the so-called graph substitution. This, together with the known polynomial-time algorithms for MIS in $H$-free graphs (e.g. $P_6$-free and fork-free graphs), implies that our conjecture holds for many graphs $H$ for which the Erd\H{o}s-Hajnal conjecture is still open. We then focus on improving the constant $\delta$ for some graph classes: we prove that the classical Local Search algorithm provides an $OPT^{1-\frac{1}{t}}$-approximation in $K_{t,t}$-free graphs (hence a $\sqrt{OPT}$-approximation in $C_4$-free graphs), and, while there is a simple $\sqrt{n}$-approximation in triangle-free graphs, it cannot be improved to $n^{\frac{1}{4}-\varepsilon}$ for any $\varepsilon > 0$ unless $NP \subseteq BPP$. More generally, we show that there is a constant $c$ such that MIS in graphs of girth $\gamma$ cannot be $n^{\frac{c}{\gamma}}$-approximated. Up to a constant factor in the exponent, this matches the ratio of a known approximation algorithm by Monien and Speckenmeyer, and by Murphy. To the best of our knowledge, this is the first strong (i.e., $\Omega(n^\delta)$ for some $\delta > 0$) inapproximability result for Maximum Independent Set in a proper hereditary class.

Published

2020

16. When Maximum Stable Set can be solved in FPT time

Author

Bonnet, Édouard, Bousquet, Nicolas, Thomassé, Stéphan, and Watrigant, Rémi

Subjects

Computer Science - Data Structures and Algorithms, Computer Science - Computational Complexity, Computer Science - Discrete Mathematics, F.2.2

Abstract

Maximum Independent Set (MIS for short) is in general graphs the paradigmatic $W[1]$-hard problem. In stark contrast, polynomial-time algorithms are known when the inputs are restricted to structured graph classes such as, for instance, perfect graphs (which includes bipartite graphs, chordal graphs, co-graphs, etc.) or claw-free graphs. In this paper, we introduce some variants of co-graphs with parameterized noise, that is, graphs that can be made into disjoint unions or complete sums by the removal of a certain number of vertices and the addition/deletion of a certain number of edges per incident vertex, both controlled by the parameter. We give a series of FPT Turing-reductions on these classes and use them to make some progress on the parameterized complexity of MIS in $H$-free graphs. We show that for every fixed $t \geqslant 1$, MIS is FPT in $P(1,t,t,t)$-free graphs, where $P(1,t,t,t)$ is the graph obtained by substituting all the vertices of a four-vertex path but one end of the path by cliques of size $t$. We also provide randomized FPT algorithms in dart-free graphs and in cricket-free graphs. This settles the FPT/W[1]-hard dichotomy for five-vertex graphs $H$.

Published

2019

17. Constraint Generation Algorithm for the Minimum Connectivity Inference Problem

Author

Bonnet, Édouard, Fălămaş, Diana-Elena, and Watrigant, Rémi

Subjects

Computer Science - Data Structures and Algorithms, 68W40, F.2.2

Abstract

Given a hypergraph $H$, the Minimum Connectivity Inference problem asks for a graph on the same vertex set as $H$ with the minimum number of edges such that the subgraph induced by every hyperedge of $H$ is connected. This problem has received a lot of attention these recent years, both from a theoretical and practical perspective, leading to several implemented approximation, greedy and heuristic algorithms. Concerning exact algorithms, only Mixed Integer Linear Programming (MILP) formulations have been experimented, all representing connectivity constraints by the means of graph flows. In this work, we investigate the efficiency of a constraint generation algorithm, where we iteratively add cut constraints to a simple ILP until a feasible (and optimal) solution is found. It turns out that our method is faster than the previous best flow-based MILP algorithm on random generated instances, which suggests that a constraint generation approach might be also useful for other optimization problems dealing with connectivity constraints. At last, we present the results of an enumeration algorithm for the problem., Comment: 16 pages, 4 tables, 1 figure

Published

2019

18. Twin-width and Polynomial Kernels

Author

Bonnet, Édouard, Kim, Eun Jung, Reinald, Amadeus, Thomassé, Stéphan, and Watrigant, Rémi

Published

2022

19. Parameterized Complexity of Independent Set in H-Free Graphs

Author

Bonnet, Édouard, Bousquet, Nicolas, Charbit, Pierre, Thomassé, Stéphan, and Watrigant, Rémi

Subjects

Computer Science - Data Structures and Algorithms, Computer Science - Computational Complexity

Abstract

In this paper, we investigate the complexity of Maximum Independent Set (MIS) in the class of $H$-free graphs, that is, graphs excluding a fixed graph as an induced subgraph. Given that the problem remains $NP$-hard for most graphs $H$, we study its fixed-parameter tractability and make progress towards a dichotomy between $FPT$ and $W[1]$-hard cases. We first show that MIS remains $W[1]$-hard in graphs forbidding simultaneously $K_{1, 4}$, any finite set of cycles of length at least $4$, and any finite set of trees with at least two branching vertices. In particular, this answers an open question of Dabrowski et al. concerning $C_4$-free graphs. Then we extend the polynomial algorithm of Alekseev when $H$ is a disjoint union of edges to an $FPT$ algorithm when $H$ is a disjoint union of cliques. We also provide a framework for solving several other cases, which is a generalization of the concept of \emph{iterative expansion} accompanied by the extraction of a particular structure using Ramsey's theorem. Iterative expansion is a maximization version of the so-called \emph{iterative compression}. We believe that our framework can be of independent interest for solving other similar graph problems. Finally, we present positive and negative results on the existence of polynomial (Turing) kernels for several graphs $H$., Comment: An extended abstract appeared in the proceedings of IPEC 2018

Published

2018

20. Overlaying a hypergraph with a graph with bounded maximum degree

Author

Havet, Frédéric, Mazauric, Dorian, Nguyen, Viet-Ha, and Watrigant, Rémi

Published

2022

21. Complexity Dichotomies for the Minimum F-Overlay Problem

Author

Cohen, Nathann, Havet, Frédéric, Mazauric, Dorian, Sau, Ignasi, and Watrigant, Rémi

Subjects

Computer Science - Data Structures and Algorithms, Computer Science - Computational Complexity

Abstract

For a (possibly infinite) fixed family of graphs F, we say that a graph G overlays F on a hypergraph H if V(H) is equal to V(G) and the subgraph of G induced by every hyperedge of H contains some member of F as a spanning subgraph.While it is easy to see that the complete graph on |V(H)| overlays F on a hypergraph H whenever the problem admits a solution, the Minimum F-Overlay problem asks for such a graph with the minimum number of edges.This problem allows to generalize some natural problems which may arise in practice. For instance, if the family F contains all connected graphs, then Minimum F-Overlay corresponds to the Minimum Connectivity Inference problem (also known as Subset Interconnection Design problem) introduced for the low-resolution reconstruction of macro-molecular assembly in structural biology, or for the design of networks.Our main contribution is a strong dichotomy result regarding the polynomial vs. NP-hard status with respect to the considered family F. Roughly speaking, we show that the easy cases one can think of (e.g. when edgeless graphs of the right sizes are in F, or if F contains only cliques) are the only families giving rise to a polynomial problem: all others are NP-complete.We then investigate the parameterized complexity of the problem and give similar sufficient conditions on F that give rise to W[1]-hard, W[2]-hard or FPT problems when the parameter is the size of the solution.This yields an FPT/W[1]-hard dichotomy for a relaxed problem, where every hyperedge of H must contain some member of F as a (non necessarily spanning) subgraph.

Published

2017

22. The Authorization Policy Existence Problem

Author

Bergé, Pierre, Crampton, Jason, Gutin, Gregory, and Watrigant, Rémi

Subjects

Computer Science - Cryptography and Security, Computer Science - Data Structures and Algorithms

Abstract

Constraints such as separation-of-duty are widely used to specify requirements that supplement basic authorization policies. However, the existence of constraints (and authorization policies) may mean that a user is unable to fulfill her/his organizational duties because access to resources has been denied. In short, there is a tension between the need to protect resources (using policies and constraints) and the availability of resources. Recent work on workflow satisfiability and resiliency in access control asks whether this tension compromises the ability of an organization to achieve its objectives. In this paper, we develop a new method of specifying constraints which subsumes much related work and allows a wider range of constraints to be specified. The use of such constraints leads naturally to a range of questions related to "policy existence", where a positive answer means that an organization's objectives can be realized. We analyze the complexity of these policy existence questions and, for particular sub-classes of constraints defined by our language, develop fixed-parameter tractable algorithms to solve them.

Published

2016

23. Parameterized Resiliency Problems via Integer Linear Programming

Author

Crampton, Jason, Gutin, Gregory, Koutecký, Martin, and Watrigant, Rémi

Subjects

Computer Science - Data Structures and Algorithms, Computer Science - Computational Complexity

Abstract

We introduce an extension of decision problems called resiliency problems. In resiliency problems, the goal is to decide whether an instance remains positive after any (appropriately defined) perturbation has been applied to it. To tackle these kinds of problems, some of which might be of practical interest, we introduce a notion of resiliency for Integer Linear Programs (ILP) and show how to use a result of Eisenbrand and Shmonin (Math. Oper. Res., 2008) on Parametric Linear Programming to prove that ILP Resiliency is fixed-parameter tractable (FPT) under a certain parameterization. To demonstrate the utility of our result, we consider natural resiliency versions of several concrete problems, and prove that they are FPT under natural parameterizations. Our first results concern a four-variate problem which generalizes the Disjoint Set Cover problem and which is of interest in access control. We obtain a complete parameterized complexity classification for every possible combination of the parameters. Then, we introduce and study a resiliency version of the Closest String problem, for which we extend an FPT result of Gramm et al. (Algorithmica, 2003). We also consider problems in the fields of scheduling and social choice. We believe that many other problems can be tackled by our framework., Comment: This paper is based on two papers published in conference proceedings of AAIM 2016 and CIAC 2017

Published

2016

24. A Multivariate Approach for Checking Resiliency in Access Control

Author

Crampton, Jason, Gutin, Gregory, and Watrigant, Rémi

Subjects

Computer Science - Data Structures and Algorithms, Computer Science - Cryptography and Security

Abstract

In recent years, several combinatorial problems were introduced in the area of access control. Typically, such problems deal with an authorization policy, seen as a relation $UR \subseteq U \times R$, where $(u, r) \in UR$ means that user $u$ is authorized to access resource $r$. Li, Tripunitara and Wang (2009) introduced the Resiliency Checking Problem (RCP), in which we are given an authorization policy, a subset of resources $P \subseteq R$, as well as integers $s \ge 0$, $d \ge 1$ and $t \geq 1$. It asks whether upon removal of any set of at most $s$ users, there still exist $d$ pairwise disjoint sets of at most $t$ users such that each set has collectively access to all resources in $P$. This problem possesses several parameters which appear to take small values in practice. We thus analyze the parameterized complexity of RCP with respect to these parameters, by considering all possible combinations of $|P|, s, d, t$. In all but one case, we are able to settle whether the problem is in FPT, XP, W[2]-hard, para-NP-hard or para-coNP-hard. We also consider the restricted case where $s=0$ for which we determine the complexity for all possible combinations of the parameters.

Published

2016

25. The Bi-Objective Workflow Satisfiability Problem and Workflow Resiliency

Author

Crampton, Jason, Gutin, Gregory, Karapetyan, Daniel, and Watrigant, Rémi

Subjects

Computer Science - Cryptography and Security, Computer Science - Data Structures and Algorithms

Abstract

A computerized workflow management system may enforce a security policy, specified in terms of authorized actions and constraints, thereby restricting which users can perform particular steps in a workflow. The existence of a security policy may mean it is impossible to find a valid plan (an assignment of steps to authorized users such that all constraints are satisfied). Work in the literature focuses on the workflow satisfiability problem, a \emph{decision} problem that outputs a valid plan if the instance is satisfiable (and a negative result otherwise). In this paper, we introduce the \textsc{Bi-Objective Workflow Satisfiability Problem} (\BOWSP), which enables us to solve \emph{optimization} problems related to workflows and security policies. In particular, we are able to compute a "least bad" plan when some components of the security policy may be violated. In general, \BOWSP is intractable from both the classical and parameterized complexity point of view. We prove there exists an fixed-parameter tractable (FPT) algorithm to compute a Pareto front for \BOWSP if we restrict our attention to user-independent constraints. We also present a second algorithm to compute a Pareto front which uses mixed integer programming (MIP). We compare the performance of both our algorithms on synthetic instances, and show that the FPT algorithm outperforms the MIP-based one by several orders of magnitude on most of the instances. Finally, we study the important question of workflow resiliency and prove new results establishing that known decision problems are fixed-parameter tractable when restricted to user-independent constraints. We then propose a new way of modeling the availability of users and demonstrate that many questions related to resiliency in the context of this new model may be reduced to instances of \BOWSP., Comment: to appear in the Journal of Computer Security

Published

2015

26. Multidimensional Binary Vector Assignment problem: standard, structural and above guarantee parameterizations

Author

Bougeret, Marin, Duvillié, Guillerme, Giroudeau, Rodolphe, and Watrigant, Rémi

Subjects

Computer Science - Data Structures and Algorithms

Abstract

In this article we focus on the parameterized complexity of the Multidimensional Binary Vector Assignment problem (called \BVA). An input of this problem is defined by $m$ disjoint sets $V^1, V^2, \dots, V^m$, each composed of $n$ binary vectors of size $p$. An output is a set of $n$ disjoint $m$-tuples of vectors, where each $m$-tuple is obtained by picking one vector from each set $V^i$. To each $m$-tuple we associate a $p$ dimensional vector by applying the bit-wise AND operation on the $m$ vectors of the tuple. The objective is to minimize the total number of zeros in these $n$ vectors. mBVA can be seen as a variant of multidimensional matching where hyperedges are implicitly locally encoded via labels attached to vertices, but was originally introduced in the context of integrated circuit manufacturing. We provide for this problem FPT algorithms and negative results ($ETH$-based results, $W$[2]-hardness and a kernel lower bound) according to several parameters: the standard parameter $k$ i.e. the total number of zeros), as well as two parameters above some guaranteed values., Comment: 16 pages, 6 figures

Published

2015

27. 1-Extendability of Independent Sets

Author

Bergé, Pierre, primary, Busson, Anthony, additional, Feghali, Carl, additional, and Watrigant, Rémi, additional

Published

2022

28. Overlaying a Hypergraph with a Graph with Bounded Maximum Degree

Author

Havet, Frédéric, Mazauric, Dorian, Nguyen, Viet-Ha, Watrigant, Rémi, Goos, Gerhard, Founding Editor, Hartmanis, Juris, Founding Editor, Bertino, Elisa, Editorial Board Member, Gao, Wen, Editorial Board Member, Steffen, Bernhard, Editorial Board Member, Woeginger, Gerhard, Editorial Board Member, Yung, Moti, Editorial Board Member, Changat, Manoj, editor, and Das, Sandip, editor

Published

2020

29. TWIN-WIDTH III: MAX INDEPENDENT SET, MIN DOMINATING SET, AND COLORING.

Author

BONNET, ÉDOUARD, GENIET, COLIN, EUN JUNG KIM, THOMASSÉ, STÉPHAN, and WATRIGANT, RÉMI

Subjects

DOMINATING set, INDEPENDENT sets, ISOMORPHISM (Mathematics), GRAPH coloring, DYNAMIC programming, APPROXIMATION algorithms, POLYNOMIAL time algorithms

Abstract

We recently introduced the notion of twin-width, a novel graph invariant, and showed that first-order model checking can be solved in time f(d, k)n for n-vertex graphs given with a witness that the twin-width is at most d, called d-contraction sequence or d-sequence, and formulas of size k [Bonnet et al., JACM '22]. The inevitable price to pay for such a general result is that f is a tower of exponentials of height roughly k. In this paper, we show that algorithms based on twin-width need not be impractical. We present 2O(k)n-time algorithms for k-independent set, r-scattered set, k-clique, and k-dominating set when an O(1)-sequence of the graph is given in input. We further show how to solve the weighted version of k-independent set, subgraph isomorphism, and induced subgraph isomorphism in the slightly worse running time 2O(k log k)n. Up to logarithmic factors in the exponent, all these running times are optimal unless the exponential time hypothesis fails. Like our first-order model checking algorithm, these new algorithms are based on a dynamic programming scheme following the sequence of contractions forward. We then show a second algorithmic use of the contraction sequence by starting at its end and rewinding it. As an example of such a reverse scheme, we present a polynomial-time algorithm that properly colors the vertices of a graph with relatively few colors, thereby establishing that bounded twin-width classes are x-bounded. This significantly extends the x-boundedness of bounded rank-width classes and does so with a very concise proof. It readily yields a constant approximation for max independent set on Kt-free graphs of bounded twin-width and a 2O(OPT)-approximation for min coloring on bounded twin-width graphs. We further observe that a constant approximation for max independent set on bounded twin-width graphs (but arbitrarily large clique number) would actually imply a polynomial-time approximation scheme. The third algorithmic use of twin-width builds on the second one. Playing the contraction sequence backward, we show that bounded twin-width graphs can be edge-partitioned into a linear number of bicliques such that both sides of the bicliques are on consecutive vertices in a fixed vertex ordering. This property is trivially shared with graphs of bounded average degree. Given that biclique edge-partition, we show how to solve the unweighted single-source shortest paths, and hence all-pairs shortest paths, in time O(n log n) and time O(n² log n), respectively. In sharp contrast, even diameter does not admit a truly subquadratic algorithm on bounded twin-width graphs unless the strong exponential time hypothesis fails. The fourth algorithmic use of twin-width builds on the so-called versatile tree of contractions [Bonnet et al., Comb. Theory '22], a branching and more robust witness of low twin-width. We present constant-approximation algorithms for min dominating set and related problems on bounded twin-width graphs by showing that the integrality gap is constant. This is done by going down the versatile tree and stopping according to a problem-dependent criterion. At the reached node, a greedy approach yields the desired approximation. [ABSTRACT FROM AUTHOR]

Published

2024

30. Parameterized Complexity of Independent Set in H-Free Graphs

Author

Bonnet, Édouard, Bousquet, Nicolas, Charbit, Pierre, Thomassé, Stéphan, and Watrigant, Rémi

Published

2020

31. Parameterized resiliency problems

Author

Crampton, Jason, Gutin, Gregory, Koutecký, Martin, and Watrigant, Rémi

Published

2019

32. Twin-width II: small classes

Author

Bonnet, Édouard, primary, Geniet, Colin, additional, Kim, Eun Jung, additional, Thomassé, Stéphan, additional, and Watrigant, Rémi, additional

Published

2021

33. Complexity Dichotomies for the Minimum -Overlay Problem

Author

Cohen, Nathann, Havet, Frédéric, Mazauric, Dorian, Sau, Ignasi, Watrigant, Rémi, Hutchison, David, Series Editor, Kanade, Takeo, Series Editor, Kittler, Josef, Series Editor, Kleinberg, Jon M., Series Editor, Mattern, Friedemann, Series Editor, Mitchell, John C., Series Editor, Naor, Moni, Series Editor, Pandu Rangan, C., Series Editor, Steffen, Bernhard, Series Editor, Terzopoulos, Demetri, Series Editor, Tygar, Doug, Series Editor, Weikum, Gerhard, Series Editor, Brankovic, Ljiljana, editor, Ryan, Joe, editor, and Smyth, William F., editor

Published

2018

34. Complexity dichotomies for the Minimum[formula omitted]-Overlay problem

Author

Cohen, Nathann, Havet, Frédéric, Mazauric, Dorian, Sau, Ignasi, and Watrigant, Rémi

Published

2018

35. Parameterized Resiliency Problems via Integer Linear Programming

Author

Crampton, Jason, Gutin, Gregory, Koutecký, Martin, Watrigant, Rémi, Hutchison, David, Series editor, Kanade, Takeo, Series editor, Kittler, Josef, Series editor, Kleinberg, Jon M., Series editor, Mattern, Friedemann, Series editor, Mitchell, John C., Series editor, Naor, Moni, Series editor, Pandu Rangan, C., Series editor, Steffen, Bernhard, Series editor, Terzopoulos, Demetri, Series editor, Tygar, Doug, Series editor, Weikum, Gerhard, Series editor, Fotakis, Dimitris, editor, Pagourtzis, Aris, editor, and Paschos, Vangelis Th., editor

Published

2017

36. Overlaying a Hypergraph with a Graph with Bounded Maximum Degree

Author

Havet, Frédéric, primary, Mazauric, Dorian, additional, Nguyen, Viet-Ha, additional, and Watrigant, Rémi, additional

Published

2020

37. Twin-width I: Tractable FO Model Checking.

Author

BONNET, ÉDOUARD, EUN JUNG KIM, THOMASSÉ, STÉPHAN, and WATRIGANT, RÉMI

Subjects

POLYNOMIAL time algorithms, PARTIALLY ordered sets, UNIT ball (Mathematics), CHARTS, diagrams, etc., GENETIC transduction

Abstract

Inspired by a width invariant defined on permutations by Guillemot and Marx [SODA'14], we introduce the notion of twin-width on graphs and on matrices. Proper minor-closed classes, bounded rank-width graphs, map graphs, Kt -free unit d-dimensional ball graphs, posets with antichains of bounded size, and proper subclasses of dimension-2 posets all have bounded twin-width. On all these classes (except map graphs without geometric embedding) we show how to compute in polynomial time a sequence of d-contractions, witness that the twin-width is at most d. We show that FO model checking, that is deciding if a given first-order formula ϕ evaluates to true for a given binary structure G on a domain D, is FPT in |ϕ| on classes of bounded twin-width, provided the witness is given. More precisely, being given a d-contraction sequence for G, our algorithm runs in time f (d, |ϕ|) · |D| where f is a computable but non-elementary function. We also prove that bounded twin-width is preserved under FO interpretations and transductions (allowing operations such as squaring or complementing a graph). This unifies and significantly extends the knowledge on fixed-parameter tractability of FO model checking on non-monotone classes, such as the FPT algorithm on bounded-width posets by Gajarský et al. [FOCS'15]. [ABSTRACT FROM AUTHOR]

Published

2022

38. 1-Extendability of Independent Sets

Author

Bergé, Pierre, primary, Busson, Anthony, additional, Feghali, Carl, additional, and Watrigant, Rémi, additional

Published

2023

39. Constraint Generation Algorithm for the Minimum Connectivity Inference Problem

Author

Bonnet, Édouard, primary, Fălămaş, Diana-Elena, additional, and Watrigant, Rémi, additional

Published

2019

40. Approximating Highly Inapproximable Problems on Graphs of Bounded Twin-Width

Author

Pierre Bergé and Édouard Bonnet and Hugues Déprés and Rémi Watrigant, Bergé, Pierre, Bonnet, Édouard, Déprés, Hugues, Watrigant, Rémi, Pierre Bergé and Édouard Bonnet and Hugues Déprés and Rémi Watrigant, Bergé, Pierre, Bonnet, Édouard, Déprés, Hugues, and Watrigant, Rémi

Published

2023

41. Approximating the Sparsest k-Subgraph in Chordal Graphs

Author

Watrigant, Rémi, Bougeret, Marin, Giroudeau, Rodolphe, Hutchison, David, editor, Kanade, Takeo, editor, Kittler, Josef, editor, Kleinberg, Jon M., editor, Kobsa, Alfred, editor, Mattern, Friedemann, editor, Mitchell, John C., editor, Naor, Moni, editor, Nierstrasz, Oscar, editor, Pandu Rangan, C., editor, Steffen, Bernhard, editor, Terzopoulos, Demetri, editor, Tygar, Doug, editor, Weikum, Gerhard, editor, Kaklamanis, Christos, editor, and Pruhs, Kirk, editor

Published

2014

42. Parameterized Complexity of the Sparsest k-Subgraph Problem in Chordal Graphs

Author

Bougeret, Marin, Bousquet, Nicolas, Giroudeau, Rodolphe, Watrigant, Rémi, Hutchison, David, editor, Kanade, Takeo, editor, Kittler, Josef, editor, Kleinberg, Jon M., editor, Mattern, Friedemann, editor, Mitchell, John C., editor, Naor, Moni, editor, Nierstrasz, Oscar, editor, Pandu Rangan, C., editor, Steffen, Bernhard, editor, Sudan, Madhu, editor, Terzopoulos, Demetri, editor, Tygar, Doug, editor, Vardi, Moshe Y., editor, Weikum, Gerhard, editor, Geffert, Viliam, editor, Preneel, Bart, editor, Rovan, Branislav, editor, Štuller, Július, editor, and Tjoa, A Min, editor

Published

2014

43. Approximating Highly Inapproximable Problems on Graphs of Bounded Twin-Width

Author

Bergé, Pierre, Bonnet, Édouard, Déprés, Hugues, and Watrigant, Rémi

Subjects

FOS: Computer and information sciences, Discrete Mathematics (cs.DM), Theory of computation → Design and analysis of algorithms, Computational Complexity (cs.CC), 68W25, Approximation algorithms, bounded twin-width, Computer Science - Computational Complexity, Theory of computation → Graph algorithms analysis, Computer Science - Data Structures and Algorithms, FOS: Mathematics, Mathematics - Combinatorics, Data Structures and Algorithms (cs.DS), Combinatorics (math.CO), F.2.2, Computer Science - Discrete Mathematics

Abstract

For any $\varepsilon > 0$, we give a polynomial-time $n^\varepsilon$-approximation algorithm for Max Independent Set in graphs of bounded twin-width given with an $O(1)$-sequence. This result is derived from the following time-approximation trade-off: We establish an $O(1)^{2^q-1}$-approximation algorithm running in time $\exp(O_q(n^{2^{-q}}))$, for every integer $q \geqslant 0$. Guided by the same framework, we obtain similar approximation algorithms for Min Coloring and Max Induced Matching. In general graphs, all these problems are known to be highly inapproximable: for any $\varepsilon > 0$, a polynomial-time $n^{1-\varepsilon}$-approximation for any of them would imply that P$=$NP [Hastad, FOCS '96; Zuckerman, ToC '07; Chalermsook et al., SODA '13]. We generalize the algorithms for Max Independent Set and Max Induced Matching to the independent (induced) packing of any fixed connected graph $H$. In contrast, we show that such approximation guarantees on graphs of bounded twin-width given with an $O(1)$-sequence are very unlikely for Min Independent Dominating Set, and somewhat unlikely for Longest Path and Longest Induced Path. Regarding the existence of better approximation algorithms, there is a (very) light evidence that the obtained approximation factor of $n^\varepsilon$ for Max Independent Set may be best possible. This is the first in-depth study of the approximability of problems in graphs of bounded twin-width. Prior to this paper, essentially the only such result was a~polynomial-time $O(1)$-approximation algorithm for Min Dominating Set [Bonnet et al., ICALP '21]., 32 pages, 3 figures, 1 table

Published

2023

44. On the sum-max graph partitioning problem

Author

Watrigant, Rémi, Bougeret, Marin, Giroudeau, Rodolphe, and König, Jean-Claude

Published

2014

45. Complexity Dichotomies for the Minimum $$\mathcal {F}$$-Overlay Problem

Author

Cohen, Nathann, primary, Havet, Frédéric, additional, Mazauric, Dorian, additional, Sau, Ignasi, additional, and Watrigant, Rémi, additional

Published

2018

46. Approximating the Sparsest k-Subgraph in Chordal Graphs

Author

Watrigant, Rémi, Bougeret, Marin, and Giroudeau, Rodolphe

Published

2016

47. A Multivariate Approach for Checking Resiliency in Access Control

Author

Crampton, Jason, primary, Gutin, Gregory, additional, and Watrigant, Rémi, additional

Published

2016

48. Twin-width III: Max Independent Set, Min Dominating Set, and Coloring

Author

Bonnet, Édouard, Geniet, Colin, Kim, Eun Jung, Thomassé, Stéphan, Watrigant, Rémi, École normale supérieure de Lyon (ENS de Lyon), Warsaw University of Technology [Warsaw], Laboratoire d'analyse et modélisation de systèmes pour l'aide à la décision (LAMSADE), Université Paris Dauphine-PSL, Université Paris sciences et lettres (PSL)-Université Paris sciences et lettres (PSL)-Centre National de la Recherche Scientifique (CNRS), and ANR-19-CE48-0013,DIGRAPHS,Digraphes(2019)

Subjects

FOS: Computer and information sciences, Discrete Mathematics (cs.DM), Parameterized Algorithms, Computational Complexity (cs.CC), Exact Algorithms, Max Independent Set, Min Dominating Set, Theory of computation → Fixed parameter tractability, Computer Science - Computational Complexity, Theory of computation → Graph algorithms analysis, Computer Science - Data Structures and Algorithms, FOS: Mathematics, Coloring, Mathematics - Combinatorics, Data Structures and Algorithms (cs.DS), 05C85, [INFO]Computer Science [cs], Combinatorics (math.CO), F.2.2, Approximation Algorithms, Twin-width, Computer Science - Discrete Mathematics, MathematicsofComputing_DISCRETEMATHEMATICS

Abstract

We recently introduced the notion of twin-width, a novel graph invariant, and showed that first-order model checking can be solved in time f(d,k)n for n-vertex graphs given with a witness that the twin-width is at most d, called d-contraction sequence or d-sequence, and formulas of size k [Bonnet et al., FOCS '20]. The inevitable price to pay for such a general result is that f is a tower of exponentials of height roughly k. In this paper, we show that algorithms based on twin-width need not be impractical. We present 2^{O(k)}n-time algorithms for k-Independent Set, r-Scattered Set, k-Clique, and k-Dominating Set when an O(1)-sequence of the graph is given in input. We further show how to solve the weighted version of k-Independent Set, Subgraph Isomorphism, and Induced Subgraph Isomorphism, in the slightly worse running time 2^{O(k log k)}n. Up to logarithmic factors in the exponent, all these running times are optimal, unless the Exponential Time Hypothesis fails. Like our FO model checking algorithm, these new algorithms are based on a dynamic programming scheme following the sequence of contractions forward. We then show a second algorithmic use of the contraction sequence, by starting at its end and rewinding it. As an example of such a reverse scheme, we present a polynomial-time algorithm that properly colors the vertices of a graph with relatively few colors, thereby establishing that bounded twin-width classes are χ-bounded. This significantly extends the χ-boundedness of bounded rank-width classes, and does so with a very concise proof. It readily yields a constant approximation for Max Independent Set on K_t-free graphs of bounded twin-width, and a 2^{O(OPT)}-approximation for Min Coloring on bounded twin-width graphs. We further observe that a constant approximation for Max Independent Set on bounded twin-width graphs (but arbitrarily large clique number) would actually imply a PTAS. The third algorithmic use of twin-width builds on the second one. Playing the contraction sequence backward, we show that bounded twin-width graphs can be edge-partitioned into a linear number of bicliques, such that both sides of the bicliques are on consecutive vertices, in a fixed vertex ordering. This property is trivially shared with graphs of bounded average degree. Given that biclique edge-partition, we show how to solve the unweighted Single-Source Shortest Paths and hence All-Pairs Shortest Paths in time O(n log n) and time O(n² log n), respectively. In sharp contrast, even Diameter does not admit a truly subquadratic algorithm on bounded twin-width graphs, unless the Strong Exponential Time Hypothesis fails. The fourth algorithmic use of twin-width builds on the so-called versatile tree of contractions [Bonnet et al., SODA '21], a branching and more robust witness of low twin-width. We present constant-approximation algorithms for Min Dominating Set and related problems, on bounded twin-width graphs, by showing that the integrality gap is constant. This is done by going down the versatile tree and stopping accordingly to a problem-dependent criterion. At the reached node, a greedy approach yields the desired approximation., LIPIcs, Vol. 198, 48th International Colloquium on Automata, Languages, and Programming (ICALP 2021), pages 35:1-35:20

Published

2021

49. Multidimensional Binary Vector Assignment Problem: Standard, Structural and Above Guarantee Parameterizations

Author

Bougeret, Marin, primary, Duvillié, Guillerme, additional, Giroudeau, Rodolphe, additional, and Watrigant, Rémi, additional

Published

2015

50. Twin-width I: Tractable FO Model Checking

Author

Bonnet, Édouard, primary, Kim, Eun Jung, additional, Thomassé, Stéphan, additional, and Watrigant, Rémi, additional

Published

2021