<p>The <Emphasis Type="BoldItalic">H</Emphasis>-<span>Coloring</span> problem is a well-known generalization of the classical <Emphasis FontCategory="SansSerif">NP</Emphasis>-complete problem <Emphasis Type="BoldItalic">k</Emphasis>-<span>Coloring</span> where the task is to determine whether an input graph admits a homomorphism to the template graph <Emphasis Type="BoldItalic">H</Emphasis>. This problem has been the subject of intense theoretical research and in this article we study the complexity of <Emphasis Type="BoldItalic">H</Emphasis>-<span>Coloring</span> with respect to the parameters <i>clique-width</i> and the more recent <i>component twin-width</i>, which describe desirable computational properties of graphs. We give two surprising linear bounds between these parameters, thus improving the previously known exponential and double exponential bounds. Our constructive proof naturally extends to related parameters and as a showcase we prove that <i>total twin-width</i> and <i>linear clique-width</i> can be related via a tight quadratic bound. These bounds naturally lead to algorithmic applications. The linear bounds between component twin-width and clique-width entail natural approximations of component twin-width, by making use of the results known for clique-width. As for computational aspects of graph coloring, we target the richer problem of counting the number of homomorphisms to <Emphasis Type="BoldItalic">H</Emphasis> (#<Emphasis Type="BoldItalic">H</Emphasis>-<span>Coloring</span>). The first algorithm that we propose uses a contraction sequence of the input graph <Emphasis Type="BoldItalic">G</Emphasis> parameterized by the component twin-width of <Emphasis Type="BoldItalic">G</Emphasis>. This leads to a positive <Emphasis FontCategory="SansSerif">FPT</Emphasis> result for the counting version. The second uses a contraction sequence of the template graph <Emphasis Type="BoldItalic">H</Emphasis> and here we instead measure the complexity with respect to the number of vertices in the input graph. Using our linear bounds we show that our algorithms are <i>always</i> at least as fast as the previously best #<Emphasis Type="BoldItalic">H</Emphasis>-Coloring algorithms (based on clique-width) and for several interesting classes of graphs (e.g., cographs, cycles of length <InlineEquation ID="IEq1"> <EquationSource Format="TEX">\(\varvec{\ge 7}\)</EquationSource> <EquationSource Format="MATHML"><math> <mrow> <mo mathvariant="bold">≥</mo> <mn mathvariant="bold">7</mn> </mrow> </math></EquationSource> </InlineEquation>, or distance-hereditary graphs) are in fact strictly faster.</p>

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Improved Bounds for Twin-Width Parameter Variants with Algorithmic Applications to Counting Graph Colorings

  • Ambroise Baril,
  • Miguel Couceiro,
  • Victor Lagerkvist

摘要

The H-Coloring problem is a well-known generalization of the classical NP-complete problem k-Coloring where the task is to determine whether an input graph admits a homomorphism to the template graph H. This problem has been the subject of intense theoretical research and in this article we study the complexity of H-Coloring with respect to the parameters clique-width and the more recent component twin-width, which describe desirable computational properties of graphs. We give two surprising linear bounds between these parameters, thus improving the previously known exponential and double exponential bounds. Our constructive proof naturally extends to related parameters and as a showcase we prove that total twin-width and linear clique-width can be related via a tight quadratic bound. These bounds naturally lead to algorithmic applications. The linear bounds between component twin-width and clique-width entail natural approximations of component twin-width, by making use of the results known for clique-width. As for computational aspects of graph coloring, we target the richer problem of counting the number of homomorphisms to H (#H-Coloring). The first algorithm that we propose uses a contraction sequence of the input graph G parameterized by the component twin-width of G. This leads to a positive FPT result for the counting version. The second uses a contraction sequence of the template graph H and here we instead measure the complexity with respect to the number of vertices in the input graph. Using our linear bounds we show that our algorithms are always at least as fast as the previously best #H-Coloring algorithms (based on clique-width) and for several interesting classes of graphs (e.g., cographs, cycles of length \(\varvec{\ge 7}\) 7 , or distance-hereditary graphs) are in fact strictly faster.