Token sliding independent set reconfiguration on graphs with few P₄'s
Pith reviewed 2026-07-01 02:33 UTC · model grok-4.3
The pith
Token-sliding independent set reconfiguration admits polynomial-time algorithms on P4-tidy graphs and (q,q-4)-graphs.
A machine-rendered reading of the paper's core claim, the machinery that carries it, and where it could break.
Core claim
The authors show that the token-sliding independent set reconfiguration problem can be solved in polynomial time for every P4-tidy graph and every (q,q-4)-graph by using the structural decompositions available in these families to search for valid sequences of slides.
What carries the argument
Structural decompositions of P4-tidy graphs and (q,q-4)-graphs that support recursive or dynamic-programming search over independent-set configurations.
If this is right
- Reachability under token slides is decidable in polynomial time for every graph in these two classes.
- The same structural properties that make cographs tractable extend to these strictly larger families.
- Any graph class properly containing P4-tidy graphs or (q,q-4)-graphs may still contain hard instances.
- The algorithms provide explicit certificates of reachability or non-reachability when they terminate.
Where Pith is reading between the lines
- The presence of many induced P4s may be the feature that drives PSPACE-hardness in broader graph classes.
- Similar decomposition techniques could be tested on other token-moving reconfiguration problems such as vertex cover or dominating set on the same graph families.
- One could measure the practical running time of the algorithms on randomly generated graphs whose P4 density is controlled to lie just inside or outside the two classes.
Load-bearing premise
The input graphs belong to the P4-tidy or (q,q-4) classes and therefore possess the decompositions the algorithm requires.
What would settle it
A concrete P4-tidy graph together with two independent sets I and I' on which the algorithm reports no reconfiguration sequence exists, yet an explicit sequence of token slides transforming I into I' can be exhibited.
Figures
read the original abstract
We consider the INDEPENDENT SET RECONFIGURATION problem under the Token Sliding rule. Let $I$ be an independent set of a simple undirected graph $G$. Suppose that each vertex of $I$ has a token placed on it. The tokens are allowed to be moved, one at a time, by sliding along the edges of $G$, so that after each move, the vertices having tokens always form an independent set of $G$. The problem we deal is to decide if we can transform $I$ into $I'$ through a sequence of steps, each of which involves substituting a vertex in the current independent set with one of its neighbours to obtain another independent set. This problem of determining if one independent set of a graph "is reachable" from another independent set of it is known to be PSPACE-hard even for split graphs, planar graphs, and graphs of bounded treewidth. Polynomial time algorithms have been obtained for certain graph classes like trees, interval graphs, claw-free graphs, bipartite permutation graphs, block graphs, and cographs. We present a polynomial time algorithm for the problem on $P_4$-tidy graphs and $(q,q-4)$-graphs, both families of graphs generalizing cographs.
Editorial analysis
A structured set of objections, weighed in public.
Referee Report
Summary. The manuscript asserts the existence of a polynomial-time algorithm for the token-sliding independent set reconfiguration problem on P4-tidy graphs and (q,q-4)-graphs, both of which generalize cographs and admit cotree-like decompositions.
Significance. If the algorithm is correct, the result would modestly extend the known tractable cases for this PSPACE-hard problem by leveraging the bounded-P4 structural decompositions already established for these classes; however, the significance cannot be fully evaluated without a correctness argument or running-time analysis.
major comments (1)
- Abstract: the claim that a polynomial-time algorithm exists is made without any proof sketch, running-time analysis, or correctness argument, so the soundness of the central claim cannot be assessed from the provided information.
Simulated Author's Rebuttal
We thank the referee for their review. We address the single major comment below.
read point-by-point responses
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Referee: [—] Abstract: the claim that a polynomial-time algorithm exists is made without any proof sketch, running-time analysis, or correctness argument, so the soundness of the central claim cannot be assessed from the provided information.
Authors: Abstracts are concise summaries and are not intended to contain full proofs, sketches, or analyses; those appear in the body of the manuscript. The full paper provides a detailed polynomial-time algorithm for token-sliding independent set reconfiguration on P4-tidy graphs and (q,q-4)-graphs. It leverages the known cotree-like decompositions for these classes, describes the algorithm explicitly, includes a correctness proof, and analyzes the running time. revision: no
Circularity Check
No significant circularity in algorithmic claim
full rationale
The paper presents a polynomial-time algorithm for token-sliding independent set reconfiguration on P4-tidy graphs and (q,q-4)-graphs, extending known results for cographs via their structural decompositions. No equations, fitted parameters, predictions, or self-referential derivations appear; the result is an algorithmic existence claim relying on graph class properties rather than reducing to its own inputs by construction. No load-bearing self-citations or ansatzes are invoked in the provided abstract and context.
Axiom & Free-Parameter Ledger
Reference graph
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