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1. On the Hardness of Scheduling With Non-Uniform Communication Delays

   https://doi.org/10.1137/1.9781611977073.15  

   Davies, Sami; Kulkarni, Janardhan; Rothvoss, Thomas; Sandeep, Sai; Tarnawski, Jakub; Zhang, Yihao (January 2022, Proceedings of the Annual ACMSIAM Symposium on Discrete Algorithms)

   Naor, Joseph; Buchbinder, Niv (Ed.)

   In the problem of scheduling with non-uniform communication delays, the input is a set of jobs with precedence constraints. Associated with every precedence constraint between a pair of jobs is a communication delay, the time duration the scheduler has to wait between the two jobs if they are scheduled on different machines. The objective is to assign the jobs to machines to minimize the makespan of the schedule. Despite being a fundamental problem in theory and a consequential problem in practice, the approximability of scheduling problems with communication delays is not very well understood. One of the top ten open problems in scheduling theory, in the influential list by Schuurman and Woeginger and its latest update by Bansal, asks if the problem admits a constant-factor approximation algorithm. In this paper, we answer this question in the negative by proving a logarithmic hardness for the problem under the standard complexity theory assumption that NP-complete problems do not admit quasi-polynomial-time algorithms. Our hardness result is obtained using a surprisingly simple reduction from a problem that we call Unique Machine Precedence constraints Scheduling (UMPS). We believe that this problem is of central importance in understanding the hardness of many scheduling problems and we conjecture that it is very hard to approximate. Among other things, our conjecture implies a logarithmic hardness of related machine scheduling with precedences, a long-standing open problem in scheduling theory and approximation algorithms. 

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2. Hardness and Approximation Algorithms for Balanced Districting Problems

   https://doi.org/10.4230/LIPIcs.FORC.2025.4  

   Dharangutte, Prathamesh; Gao, Jie; Huang, Shang-En; Yu, Fang-Yi (January 2025, Schloss Dagstuhl – Leibniz-Zentrum für Informatik)

   Bun, Mark (Ed.)

   We introduce and study the problem of balanced districting, where given an undirected graph with vertices carrying two types of weights (different population, resource types, etc) the goal is to maximize the total weights covered in vertex disjoint districts such that each district is a star or (in general) a connected induced subgraph with the two weights to be balanced. This problem is strongly motivated by political redistricting, where contiguity, population balance, and compactness are essential. We provide hardness and approximation algorithms for this problem. In particular, we show NP-hardness for an approximation better than n^{1/2-δ} for any constant δ > 0 in general graphs even when the districts are star graphs, as well as NP-hardness on complete graphs, tree graphs, planar graphs and other restricted settings. On the other hand, we develop an algorithm for balanced star districting that gives an O(√n)-approximation on any graph (which is basically tight considering matching hardness of approximation results), an O(log n) approximation on planar graphs with extensions to minor-free graphs. Our algorithm uses a modified Whack-a-Mole algorithm [Bhattacharya, Kiss, and Saranurak, SODA 2023] to find a sparse solution of a fractional packing linear program (despite exponentially many variables) which requires a new design of a separation oracle specific for our balanced districting problem. To turn the fractional solution to a feasible integer solution, we adopt the randomized rounding algorithm by [Chan and Har-Peled, SoCG 2009]. To get a good approximation ratio of the rounding procedure, a crucial element in the analysis is the balanced scattering separators for planar graphs and minor-free graphs - separators that can be partitioned into a small number of k-hop independent sets for some constant k - which may find independent interest in solving other packing style problems. Further, our algorithm is versatile - the very same algorithm can be analyzed in different ways on various graph classes, which leads to class-dependent approximation ratios. We also provide a FPTAS algorithm for complete graphs and tree graphs, as well as greedy algorithms and approximation ratios when the district cardinality is bounded, the graph has bounded degree or the weights are binary. We refer the readers to the full version of the paper for complete set of results and proofs. 

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3. Hardness of Approximation for Orienteering with Multiple Time Windows

   Garg, Naveen; Khanna, Sanjeev; Kumar, Amit (January 2021, Proceedings of the ACM-SIAM Symposium on Discrete Algorithms)

   null (Ed.)

   Vehicle routing problems are a broad class of combinatorial optimization problems that can be formulated as the problem of finding a tour in a weighted graph that optimizes some function of the visited vertices. For instance, a canonical and extensively studied vehicle routing problem is the orienteering problem where the goal is to find a tour that maximizes the number of vertices visited by a given deadline. In this paper, we consider the computational tractability of a well-known generalization of the orienteering problem called the Orient-MTW problem. The input to Orient-MTW consists of a weighted graph G(V, E) where for each vertex v ∊ V we are given a set of time instants Tv ⊆ [T], and a source vertex s. A tour starting at s is said to visit a vertex v if it transits through v at any time in the set Tv. The goal is to find a tour starting at the source vertex that maximizes the number of vertices visited. It is known that this problem admits a quasi-polynomial time O(log OPT)-approximation ratio where OPT is the optimal solution value but until now no hardness better than an APX-hardness was known for this problem. Our main result is an -hardness for this problem that holds even when the underlying graph G is an undirected tree. This is the first super-constant hardness result for the Orient-MTW problem. The starting point for our result is the hardness of the SetCover problem which is known to hold on instances with a special structure. We exploit this special structure of the hard SetCover instances to first obtain a new proof of the APX-hardness result for Orient-MTW that holds even on trees of depth 2. We then recursively amplify this constant factor hardness to an -hardness, while keeping the resulting topology to be a tree. Our amplified hardness proof crucially utilizes a delicate concavity property which shows that in our encoding of SetCover instances as instances of the Orient-MTW problem, whenever the optimal cost for SetCover instance is large, any tour, no matter how it allocates its time across different sub-trees, can not visit too many vertices overall. We believe that this reduction template may also prove useful in showing hardness of other vehicle routing problems. 

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4. Hardness and Algorithms for Robust and Sparse Optimization 162:17926-17944, 2022.

   Price, E.; Silwal, S.; Zhou, S. (January 2022, Proceedings of the 39th International Conference on Machine Learning (PMLR))

   We explore algorithms and limitations for sparse optimization problems such as sparse linear regression and robust linear regression. The goal of the sparse linear regression problem is to identify a small number of key features, while the goal of the robust linear regression problem is to identify a small number of erroneous measurements. Specifically, the sparse linear regression problem seeks a k-sparse vector x ∈ Rd to minimize ‖Ax − b‖2, given an input matrix A ∈ Rn×d and a target vector b ∈ Rn, while the robust linear regression problem seeks a set S that ignores at most k rows and a vector x to minimize ‖(Ax − b)S ‖2. We first show bicriteria, NP-hardness of approximation for robust regression building on the work of [OWZ15] which implies a similar result for sparse regression. We further show fine-grained hardness of robust regression through a reduction from the minimum-weight k-clique conjecture. On the positive side, we give an algorithm for robust regression that achieves arbitrarily accurate additive error and uses runtime that closely matches the lower bound from the fine-grained hardness result, as well as an algorithm for sparse regression with similar runtime. Both our upper and lower bounds rely on a general reduction from robust linear regression to sparse regression that we introduce. Our algorithms, inspired by the 3SUM problem, use approximate nearest neighbor data structures and may be of independent interest for solving sparse optimization problems. For instance, we demonstrate that our techniques can also be used for the well-studied sparse PCA problem. 

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5. On the Hardness and Inapproximability of Recognizing Wheeler Graphs

   https://doi.org/10.4230/LIPIcs.ESA.2019.51  

   Gibney, Daniel;  Thankachan, Sharma V. (January 2019, 27th Annual European Symposium on Algorithms (ESA) 2019)

   In recent years several compressed indexes based on variants of the Burrows-Wheeler transformation have been introduced. Some of these are used to index structures far more complex than a single string, as was originally done with the FM-index [Ferragina and Manzini, J. ACM 2005]. As such, there has been an increasing effort to better understand under which conditions such an indexing scheme is possible. This has led to the introduction of Wheeler graphs [Gagie et al., Theor. Comput. Sci., 2017]. Gagie et al. showed that de Bruijn graphs, generalized compressed suffix arrays, and several other BWT related structures can be represented as Wheeler graphs and that Wheeler graphs can be indexed in a way which is space-efficient. Hence, being able to recognize whether a given graph is a Wheeler graph, or being able to approximate a given graph by a Wheeler graph, could have numerous applications in indexing. Here we resolve the open question of whether there exists an efficient algorithm for recognizing if a given graph is a Wheeler graph. We present - The problem of recognizing whether a given graph G=(V,E) is a Wheeler graph is NP-complete for any edge label alphabet of size sigma >= 2, even when G is a DAG. This holds even on a restricted, subset of graphs called d-NFA's for d >= 5. This is in contrast to recent results demonstrating the problem can be solved in polynomial time for d-NFA's where d <= 2. We also show the recognition problem can be solved in linear time for sigma =1; - There exists an 2^{e log sigma + O(n + e)} time exact algorithm where n = |V| and e = |E|. This algorithm relies on graph isomorphism being computable in strictly sub-exponential time; - We define an optimization variant of the problem called Wheeler Graph Violation, abbreviated WGV, where the aim is to remove the minimum number of edges in order to obtain a Wheeler graph. We show WGV is APX-hard, even when G is a DAG, implying there exists a constant C >= 1 for which there is no C-approximation algorithm (unless P = NP). Also, conditioned on the Unique Games Conjecture, for all C >= 1, it is NP-hard to find a C-approximation; - We define the Wheeler Subgraph problem, abbreviated WS, where the aim is to find the largest subgraph which is a Wheeler Graph (the dual of the WGV). In contrast to WGV, we prove that the WS problem is in APX for sigma=O(1); The above findings suggest that most problems under this theme are computationally difficult. However, we identify a class of graphs for which the recognition problem is polynomial-time solvable, raising the open question of which parameters determine this problem's difficulty. 

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