Parameterised Approximation and Complexity of Minimum Flow Decompositions

Abstract: Minimum flow decomposition (MFD) is the strongly NP-hard problem of finding a smallest set of integer weighted paths in a graph $G$ whose weighted sum is equal to a given flow $f$ on $G$. Despite its many practical applications, we lack an understanding of graph structures that make MFD easy or hard. In particular, it is not known whether a good approximation algorithm exists when the weights are positive. On the positive side, the main result of this paper is that MFD can be approximated within a factor $O(\log\Vert f\Vert)$ (where $\Vert f\Vert$ is the largest flow weight of all edges) times the ratio between the parallel-width of $G$ (introduced by Deligkas and Meir, MFCS 2018) and the width of $G$ (minimum number of paths to cover all edges). In particular, when the MFD size is at least the parallel-width of $G$, this becomes the first parameterised $O(\log\Vert f\Vert)$-factor approximation algorithm for MFD over positive integers. We also show that there exist instances where the ratio between the parallel-width of $G$ and the MFD size is arbitrarily large, thus narrowing down the class of graphs whose approximation is still open. We achieve these results by introducing a new notion of flow-width of $(G,f)$, which unifies both the width and the parallel-width and may be of independent interest. On the negative side, we show that small-width graphs do not make MFD easy. This question was previously open, because width-1 graphs (i.e. paths) are trivially solvable, and the existing NP-hardness proofs use graphs of unbounded width. We close this problem by showing the tight results that MFD remains strongly NP-hard on graphs of width 3, and NP-hard on graphs of width 2 (and thus also parallel-width 2). Moreover, on width-2 graphs (and more generally, on constant parallel-width graphs), MFD is solvable in quasi-polynomial time on unary-coded flows.