Monotone Bounded-Depth Complexity of Homomorphism Polynomials

Bhargav C. S.; Radu-Cristian  Curticapean; Shiteng Chen; Prateek  Dwivedi

doi:10.4230/LIPICS.MFCS.2025.19

Monotone Bounded-Depth Complexity of Homomorphism Polynomials

Bhargav C. S.
, Radu-Cristian Curticapean
, Shiteng Chen
, Prateek Dwivedi

Publikation: Konference artikel i Proceeding eller bog/rapport kapitel › Konferencebidrag i proceedings › Forskning › peer review

Abstract

For every fixed graph H, it is known that homomorphism counts from H and colorful H-subgraph counts can be determined in O(n^{t+1}) time on n-vertex input graphs G, where t is the treewidth of H. On the other hand, a running time of n^{o(t / log t)} would refute the exponential-time hypothesis. Komarath, Pandey, and Rahul (Algorithmica, 2023) studied algebraic variants of these counting problems, i.e., homomorphism and subgraph polynomials for fixed graphs H. These polynomials are weighted sums over the objects counted above, where each object is weighted by the product of variables corresponding to edges contained in the object. As shown by Komarath et al., the monotone circuit complexity of the homomorphism polynomial for H is Θ(n^{tw(H)+1}).
In this paper, we characterize the power of monotone bounded-depth circuits for homomorphism and colorful subgraph polynomials. This leads us to discover a natural hierarchy of graph parameters tw_Δ(H), for fixed Δ ∈ ℕ, which capture the width of tree-decompositions for H when the underlying tree is required to have depth at most Δ. We prove that monotone circuits of product-depth Δ computing the homomorphism polynomial for H require size Θ(n^{tw_Δ(H^{†})+1}), where H^{†} is the graph obtained from H by removing all degree-1 vertices. This allows us to derive an optimal depth hierarchy theorem for monotone bounded-depth circuits through graph-theoretic arguments.

Originalsprog	Engelsk
Titel	Proceedings of the 50th International Symposium on Mathematical Foundations of Computer Science
Antal sider	18
Vol/bind	345
Udgivelsessted	Dagstuhl, Germany
Forlag	Schloss Dagstuhl - Leibniz-Zentrum fuer Informatik GmbH
Publikationsdato	20 aug. 2025
Sider	19:1--19:18
Artikelnummer	19
ISBN (Trykt)	9783959773881
ISBN (Elektronisk)	978-3-95977-388-1
DOI	https://doi.org/10.4230/LIPICS.MFCS.2025.19
Status	Udgivet - 20 aug. 2025
Begivenhed	50th International Symposium on Mathematical Foundations of Computer Science - Warsaw, Polen Varighed: 25 aug. 2025 → 29 aug. 2025

Konference

Konference	50th International Symposium on Mathematical Foundations of Computer Science
Land/Område	Polen
By	Warsaw
Periode	25/08/2025 → 29/08/2025

Adgang til dokumentet

10.4230/LIPICS.MFCS.2025.19Licens: CC BY

CountHom: Counting (with) homomorphisms
Curticapean, R.-C. (PI) & Seppelt, T. F. (Samarbejdspartner)
European Commission
01/04/2023 → 31/03/2028
Projekter: Projekt › Forskning

Citationsformater

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title = "Monotone Bounded-Depth Complexity of Homomorphism Polynomials",

abstract = "For every fixed graph H, it is known that homomorphism counts from H and colorful H-subgraph counts can be determined in O(n\textasciicircum{}\{t+1\}) time on n-vertex input graphs G, where t is the treewidth of H. On the other hand, a running time of n\textasciicircum{}\{o(t / log t)\} would refute the exponential-time hypothesis. Komarath, Pandey, and Rahul (Algorithmica, 2023) studied algebraic variants of these counting problems, i.e., homomorphism and subgraph polynomials for fixed graphs H. These polynomials are weighted sums over the objects counted above, where each object is weighted by the product of variables corresponding to edges contained in the object. As shown by Komarath et al., the monotone circuit complexity of the homomorphism polynomial for H is Θ(n\textasciicircum{}\{tw(H)+1\}). In this paper, we characterize the power of monotone bounded-depth circuits for homomorphism and colorful subgraph polynomials. This leads us to discover a natural hierarchy of graph parameters tw\_Δ(H), for fixed Δ ∈ ℕ, which capture the width of tree-decompositions for H when the underlying tree is required to have depth at most Δ. We prove that monotone circuits of product-depth Δ computing the homomorphism polynomial for H require size Θ(n\textasciicircum{}\{tw\_Δ(H\textasciicircum{}\{†\})+1\}), where H\textasciicircum{}\{†\} is the graph obtained from H by removing all degree-1 vertices. This allows us to derive an optimal depth hierarchy theorem for monotone bounded-depth circuits through graph-theoretic arguments.",

keywords = "Monotone circuit complexity, Pathwidth, Algebraic Complexity, Homomorphisms, Boundeddepth circuits, Treewidth",

author = "\{C. S.\}, Bhargav and Radu-Cristian Curticapean and Shiteng Chen and Prateek Dwivedi",

year = "2025",

month = aug,

day = "20",

doi = "10.4230/LIPICS.MFCS.2025.19",

language = "English",

isbn = "9783959773881",

volume = "345",

pages = "19:1----19:18",

booktitle = "Proceedings of the 50th International Symposium on Mathematical Foundations of Computer Science",

publisher = "Schloss Dagstuhl - Leibniz-Zentrum fuer Informatik GmbH",

note = "50th International Symposium on Mathematical Foundations of Computer Science, MFCS 2025 ; Conference date: 25-08-2025 Through 29-08-2025",

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C. S., B, Curticapean, R-C, Chen, S & Dwivedi, P 2025, Monotone Bounded-Depth Complexity of Homomorphism Polynomials. i Proceedings of the 50th International Symposium on Mathematical Foundations of Computer Science. bind 345, 19, Schloss Dagstuhl - Leibniz-Zentrum fuer Informatik GmbH, Dagstuhl, Germany, s. 19:1--19:18, 50th International Symposium on Mathematical Foundations of Computer Science, Warsaw, Polen, 25/08/2025. https://doi.org/10.4230/LIPICS.MFCS.2025.19

Monotone Bounded-Depth Complexity of Homomorphism Polynomials. / C. S., Bhargav; Curticapean, Radu-Cristian ; Chen, Shiteng et al.
Proceedings of the 50th International Symposium on Mathematical Foundations of Computer Science. Bind 345 Dagstuhl, Germany: Schloss Dagstuhl - Leibniz-Zentrum fuer Informatik GmbH, 2025. s. 19:1--19:18 19.

Publikation: Konference artikel i Proceeding eller bog/rapport kapitel › Konferencebidrag i proceedings › Forskning › peer review

TY - GEN

T1 - Monotone Bounded-Depth Complexity of Homomorphism Polynomials

AU - C. S., Bhargav

AU - Curticapean, Radu-Cristian

AU - Chen, Shiteng

AU - Dwivedi, Prateek

PY - 2025/8/20

Y1 - 2025/8/20

N2 - For every fixed graph H, it is known that homomorphism counts from H and colorful H-subgraph counts can be determined in O(n^{t+1}) time on n-vertex input graphs G, where t is the treewidth of H. On the other hand, a running time of n^{o(t / log t)} would refute the exponential-time hypothesis. Komarath, Pandey, and Rahul (Algorithmica, 2023) studied algebraic variants of these counting problems, i.e., homomorphism and subgraph polynomials for fixed graphs H. These polynomials are weighted sums over the objects counted above, where each object is weighted by the product of variables corresponding to edges contained in the object. As shown by Komarath et al., the monotone circuit complexity of the homomorphism polynomial for H is Θ(n^{tw(H)+1}). In this paper, we characterize the power of monotone bounded-depth circuits for homomorphism and colorful subgraph polynomials. This leads us to discover a natural hierarchy of graph parameters tw_Δ(H), for fixed Δ ∈ ℕ, which capture the width of tree-decompositions for H when the underlying tree is required to have depth at most Δ. We prove that monotone circuits of product-depth Δ computing the homomorphism polynomial for H require size Θ(n^{tw_Δ(H^{†})+1}), where H^{†} is the graph obtained from H by removing all degree-1 vertices. This allows us to derive an optimal depth hierarchy theorem for monotone bounded-depth circuits through graph-theoretic arguments.

AB - For every fixed graph H, it is known that homomorphism counts from H and colorful H-subgraph counts can be determined in O(n^{t+1}) time on n-vertex input graphs G, where t is the treewidth of H. On the other hand, a running time of n^{o(t / log t)} would refute the exponential-time hypothesis. Komarath, Pandey, and Rahul (Algorithmica, 2023) studied algebraic variants of these counting problems, i.e., homomorphism and subgraph polynomials for fixed graphs H. These polynomials are weighted sums over the objects counted above, where each object is weighted by the product of variables corresponding to edges contained in the object. As shown by Komarath et al., the monotone circuit complexity of the homomorphism polynomial for H is Θ(n^{tw(H)+1}). In this paper, we characterize the power of monotone bounded-depth circuits for homomorphism and colorful subgraph polynomials. This leads us to discover a natural hierarchy of graph parameters tw_Δ(H), for fixed Δ ∈ ℕ, which capture the width of tree-decompositions for H when the underlying tree is required to have depth at most Δ. We prove that monotone circuits of product-depth Δ computing the homomorphism polynomial for H require size Θ(n^{tw_Δ(H^{†})+1}), where H^{†} is the graph obtained from H by removing all degree-1 vertices. This allows us to derive an optimal depth hierarchy theorem for monotone bounded-depth circuits through graph-theoretic arguments.

KW - Monotone circuit complexity

KW - Pathwidth

KW - Algebraic Complexity

KW - Homomorphisms

KW - Boundeddepth circuits

KW - Treewidth

U2 - 10.4230/LIPICS.MFCS.2025.19

DO - 10.4230/LIPICS.MFCS.2025.19

M3 - Article in proceedings

SN - 9783959773881

VL - 345

SP - 19:1--19:18

BT - Proceedings of the 50th International Symposium on Mathematical Foundations of Computer Science

PB - Schloss Dagstuhl - Leibniz-Zentrum fuer Informatik GmbH

CY - Dagstuhl, Germany

T2 - 50th International Symposium on Mathematical Foundations of Computer Science

Y2 - 25 August 2025 through 29 August 2025

ER -

Monotone Bounded-Depth Complexity of Homomorphism Polynomials

Abstract

Konference

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Fingeraftryk

Projekter

CountHom: Counting (with) homomorphisms

Citationsformater