Counting Small Induced Subgraphs with Hereditary Properties

Abstract: We study the computational complexity of the problem #IndSub(Φ) of counting k-vertex induced subgraphs of a graph G that satisfy a graph property Φ. Our main result establishes an exhaustive and explicit classification for all hereditary properties, including tight conditional lower bounds under the Exponential Time Hypothesis (ETH):• If a hereditary property Φ is true for all graphs, or if it is true only for finitely many graphs, then #IndSub(Φ) is solvable in polynomial time.• Otherwise, #IndSub(Φ) is #W[1]… Show more

“…In addition to confirming Conjecture 1 for hereditary properties, we also establish a tight conditional lower bound under the Exponential Time Hypothesis; it turns out that a hereditary property is meagre if and only if either Φ is true for all graphs, or it is true only for finitely many graphs (an easy proof of this fact can be found in the full version [15]). Observe that our conditional lower bound under ETH rules out any significant improvement over the brute-force algorithm for #IndSub(Φ), which iterates over every 𝑘-vertex subset of 𝑉 (𝐺) and counts those that induce a subgraph satisfying Φ.…”

“…For example, the property Φ of having an even number of vertices is meagre, and it is easy to see that #IndSub(Φ) is trivial to solve: On input 𝐺 and 𝑘, output 0 if 𝑘 is odd, and output |𝑉 (𝐺) | 𝑘 if 𝑘 is even. It is well-known that an analogue of the previous algorithm exists for every meagre property; this is made formal in the full version [15]. Conversely, as stated in [30], we conjecture that all non-meagre properties yield hardness:…”

Counting Small Induced Subgraphs with Hereditary Properties

“…In addition to confirming Conjecture 1 for hereditary properties, we also establish a tight conditional lower bound under the Exponential Time Hypothesis; it turns out that a hereditary property is meagre if and only if either Φ is true for all graphs, or it is true only for finitely many graphs (an easy proof of this fact can be found in the full version [15]). Observe that our conditional lower bound under ETH rules out any significant improvement over the brute-force algorithm for #IndSub(Φ), which iterates over every 𝑘-vertex subset of 𝑉 (𝐺) and counts those that induce a subgraph satisfying Φ.…”

“…For example, the property Φ of having an even number of vertices is meagre, and it is easy to see that #IndSub(Φ) is trivial to solve: On input 𝐺 and 𝑘, output 0 if 𝑘 is odd, and output |𝑉 (𝐺) | 𝑘 if 𝑘 is even. It is well-known that an analogue of the previous algorithm exists for every meagre property; this is made formal in the full version [15]. Conversely, as stated in [30], we conjecture that all non-meagre properties yield hardness:…”

Counting Small Induced Subgraphs with Hereditary Properties

“…In addition to confirming Conjecture 1 for hereditary properties, we also establish a tight conditional lower bound under the Exponential Time Hypothesis; it turns out that a hereditary property is meagre if and only if either Φ is true for all graphs, or it is true only for finitely many graphs (an easy proof of this fact can be found in the full version [15]). Theorem 2.…”

“…In the course of establishing Theorem 2, we prove a much stronger technical intractability theorem which is stated in the full version [15]. We have not yet explored the full extent of its applicability and we believe that it will be useful in future work (see Section 5).…”

“…In[19], #IndSub(Φ) is called #InducedUnlabelledSubgraphWithProperty(Φ) 2. The class #W[1] can be considered as a parameterised counting equivalent of NP; a formal definition is stated in the full version[15].…”

Counting small induced subgraphs with hereditary properties