Graph Homomorphism Distortion: A Metric to Distinguish Them All and in the Latent Space Bind Them
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| Publication date | 04-11-2025 |
| Edition | v1 |
| Number of pages | 40 |
| Publisher | ArXiv |
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| Abstract |
For far too long, expressivity of graph neural networks has been measured \emph{only} in terms of combinatorial properties. In this work we stray away from this tradition and provide a principled way to measure similarity between vertex attributed graphs. We denote this measure as the \emph{graph homomorphism distortion}. We show it can \emph{completely characterize} graphs and thus is also a \emph{complete graph embedding}. However, somewhere along the road, we run into the graph canonization problem. To circumvent this obstacle, we devise to efficiently compute this measure via sampling, which in expectation ensures \emph{completeness}. Additionally, we also discovered that we can obtain a metric from this measure. We validate our claims empirically and find that the \emph{graph homomorphism distortion}: (1.) fully distinguishes the \texttt{BREC} dataset with up to 4-WL non-distinguishable graphs, and (2.) \emph{outperforms} previous methods inspired in homomorphisms under the \texttt{ZINC-12k} dataset.
These theoretical results, (and their empirical validation), pave the way for future characterization of graphs, extending the graph theoretic tradition to new frontiers. |
| Document type | Preprint |
| Language | English |
| Published at | https://doi.org/10.48550/arXiv.2511.03068 |
| Downloads |
2511.03068v1
(Final published version)
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