SIAM Journal on Discrete Mathematics
Journal of Combinatorial Theory Series B
Computers and Intractability: A Guide to the Theory of NP-Completeness
Computers and Intractability: A Guide to the Theory of NP-Completeness
Complexity of graph covering problems
Nordic Journal of Computing
Local and global properties in networks of processors (Extended Abstract)
STOC '80 Proceedings of the twelfth annual ACM symposium on Theory of computing
A complete complexity classification of the role assignment problem
Theoretical Computer Science - Graph colorings
Locally constrained graph homomorphisms and equitable partitions
European Journal of Combinatorics
Graph labelings derived from models in distributed computing
WG'06 Proceedings of the 32nd international conference on Graph-Theoretic Concepts in Computer Science
Local computations on closed unlabelled edges: the election problem and the naming problem
SOFSEM'05 Proceedings of the 31st international conference on Theory and Practice of Computer Science
The path partition problem and related problems in bipartite graphs
Operations Research Letters
Locally constrained graph homomorphisms-structure, complexity, and applications
Computer Science Review
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For a set $\mathcal{S}$ of graphs, a perfect $\mathcal{S}$-packing ($\mathcal{S}$-factor) of a graph G is a set of mutually vertex-disjoint subgraphs of G that each are isomorphic to a member of $\mathcal{S}$ and that together contain all vertices of G. If G allows a covering (locally bijective homomorphism) to a graph H, then G is an H-cover. For some fixed H let $\mathcal{S}(H)$ consist of all H-covers. Let Kk,ℓ be the complete bipartite graph with partition classes of size k and ℓ, respectively. For all fixed k,ℓ≥1, we determine the computational complexity of the problem that tests if a given bipartite graph has a perfect $\mathcal{S}(K_{k,\ell})$-packing. Our technique is partially based on exploring a close relationship to pseudo-coverings. A pseudo-covering from a graph G to a graph H is a homomorphism from G to H that becomes a covering to H when restricted to a spanning subgraph of G. We settle the computational complexity of the problem that asks if a graph allows a pseudo-covering to Kk,ℓ for all fixed k,ℓ≥1.