Homomorphism Indistinguishability, Multiplicity Automata Equivalence, and Polynomial Identity Testing

Abstract

Two graphs G and H are homomorphism indistinguishable over a graph class F if they admit the same number of homomorphisms from every graph F ∈ F. Many graph isomorphism relaxations such as (quantum) isomorphism and cospectrality can be characterised as homomorphism indistinguishability over specific graph classes. Thereby, the problems HomInd(F) of deciding homomorphism indistinguishability over F subsume diverse graph isomorphism relaxations whose complexities range from logspace to undecidable. Establishing the first general result on the complexity of HomInd(F), Seppelt (MFCS 2024) showed that HomInd(F) is in randomised polynomial time for every graph class F of bounded treewidth that can be defined in counting monadic second-order logic CMSO2. We show that this algorithm is conditionally optimal, i.e. it cannot be derandomised unless polynomial identity testing is in PTIME. For CMSO2-definable graph classes F of bounded pathwidth, we improve the previous complexity upper bound for HomInd(F) from PTIME to C=L and show that this is tight. Secondarily, we establish a connection between homomorphism indistinguishability and multiplicity automata equivalence which allows us to pinpoint the complexity of the latter problem as C=L-complete.

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