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1. Cut-based Conflict Analysis in Mixed Integer Programming

Author

Mexi, Gioni, Serrano, Felipe, Berthold, Timo, Gleixner, Ambros, and Nordström, Jakob

Subjects
Mathematics - Optimization and Control
Abstract

For almost two decades, mixed integer programming (MIP) solvers have used graph-based conflict analysis to learn from local infeasibilities during branch-and-bound search. In this paper, we improve MIP conflict analysis by instead using reasoning based on cuts, inspired by the development of conflict-driven solvers for pseudo-Boolean optimization. Phrased in MIP terminology, this type of conflict analysis can be understood as a sequence of linear combinations, integer roundings, and cut generation. We leverage this MIP perspective to design a new conflict analysis algorithm based on mixed integer rounding cuts, which theoretically dominates the state-of-the-art method in pseudo-Boolean optimization using Chv\'atal-Gomory cuts. Furthermore, we extend this cut-based conflict analysis from pure binary programs to mixed binary programs and-in limited form-to general MIP with also integer-valued variables. We perform an empirical evaluation of cut-based conflict analysis as implemented in the open-source MIP solver SCIP, testing it on a large and diverse set of MIP instances from MIPLIB 2017. Our experimental results indicate that the new algorithm improves the default performance of SCIP in terms of running time, number of nodes in the search tree, and the number of instances solved.

Published
2024

2. Testing the order of fractional integration in the presence of smooth trends, with an application to UK Great Ratios

Author

Kılınç, Mustafa R., Massmann, Michael, and Ambros, Maximilian

Subjects
Economics - Econometrics
Abstract

This note proposes semi-parametric tests for investigating whether a stochastic process is fractionally integrated of order $\delta$, where $|\delta| < 1/2$, when smooth trends are present in the model. We combine the semi-parametric approach by Iacone, Nielsen & Taylor (2022) to model the short range dependence with the use of Chebyshev polynomials by Cuestas & Gil-Alana to describe smooth trends. Our proposed statistics have standard limiting null distributions and match the asymptotic local power of infeasible tests based on unobserved errors. We also establish the conditions under which an information criterion can consistently estimate the order of the Chebyshev polynomial. The finite sample performance is evaluated using simulations, and an empirical application is given for the UK Great Ratios.

Published
2024

3. MIP-DD: A Delta Debugger for Mixed Integer Programming Solvers

Author

Hoen, Alexander, Kamp, Dominik, and Gleixner, Ambros

Subjects
Mathematics - Optimization and Control
Abstract

The recent performance improvements in mixed-integer programming (MIP) went along with a significantly increased complexity of the codes of MIP solvers, which poses challenges in fixing implementation errors. In this paper, we introduce MIP-DD, a solver-independent tool, which is, to the best of our knowledge, the first open-source delta debugger for MIP. Delta debugging is a hypothesis-trial-result approach to isolate the cause of a solver failure. MIP-DD simplifies MIP instances while maintaining the undesired behavior and already supported and motivated fixes for many bugs in the SCIP releases 8.0.4, 8.1.0, and 9.0.0. This translates to an increase of approximately 71.% more bugfixes than in the same time period before and including some fixes of long-known issues. As we highlight in selected case studies, instances triggering fundamental bugs in SCIP can typically be reduced to a few variables and constraints in less than an hour. This makes it significantly easier to manually trace and check the solution process on the resulting simplified instances. A promising future application of MIP-DD is the analysis of performance bottlenecks, which could very well benefit from simple adversarial instances.

Published
2024

4. A diving heuristic for mixed-integer problems with unbounded semi-continuous variables

Author

Halbig, Katrin, Hoen, Alexander, Gleixner, Ambros, Witzig, Jakob, and Weninger, Dieter

Subjects
Mathematics - Optimization and Control, 90C10, 90C59, 90C90
Abstract

Semi-continuous decision variables arise naturally in many real-world applications. They are defined to take either value zero or any value within a specified range, and occur mainly to prevent small nonzero values in the solution. One particular challenge that can come with semi-continuous variables in practical models is that their upper bound may be large or even infinite. In this article, we briefly discuss these challenges, and present a new diving heuristic tailored for mixed-integer optimization problems with general semi-continuous variables. The heuristic is designed to work independently of whether the semi-continuous variables are bounded from above, and thus circumvents the specific difficulties that come with unbounded semi-continuous variables. We conduct extensive computational experiments on three different test sets, integrating the heuristic in an open-source MIP solver. The results indicate that this heuristic is a successful tool for finding high-quality solutions in negligible time. At the root node the primal gap is reduced by an average of 5 % up to 21 %, and considering the overall performance improvement, the primal integral is reduced by 2 % to 17 % on average.

Published
2024

5. Certified Constraint Propagation and Dual Proof Analysis in a Numerically Exact MIP Solver

Author

Borst, Sander, Eifler, Leon, and Gleixner, Ambros

Subjects
Mathematics - Optimization and Control
Abstract

This paper presents the integration of constraint propagation and dual proof analysis in an exact, roundoff-error-free MIP solver. The authors employ safe rounding methods to ensure that all results remain provably correct, while sacrificing as little computational performance as possible in comparison to a pure floating-point implementation. The study also addresses the adaptation of certification techniques for correctness verification. Computational studies demonstrate the effectiveness of these techniques, showcasing a 23% performance improvement on the MIPLIB 2017 benchmark test set.

Published
2024

6. The SCIP Optimization Suite 9.0

Author

Bolusani, Suresh, Besançon, Mathieu, Bestuzheva, Ksenia, Chmiela, Antonia, Dionísio, João, Donkiewicz, Tim, van Doornmalen, Jasper, Eifler, Leon, Ghannam, Mohammed, Gleixner, Ambros, Graczyk, Christoph, Halbig, Katrin, Hedtke, Ivo, Hoen, Alexander, Hojny, Christopher, van der Hulst, Rolf, Kamp, Dominik, Koch, Thorsten, Kofler, Kevin, Lentz, Jurgen, Manns, Julian, Mexi, Gioni, Mühmer, Erik, Pfetsch, Marc E., Schlösser, Franziska, Serrano, Felipe, Shinano, Yuji, Turner, Mark, Vigerske, Stefan, Weninger, Dieter, and Xu, Lixing

Subjects
Mathematics - Optimization and Control, 90C05, 90C10, 90C11, 90C30, 90C90, 65Y05
Abstract

The SCIP Optimization Suite provides a collection of software packages for mathematical optimization, centered around the constraint integer programming (CIP) framework SCIP. This report discusses the enhancements and extensions included in the SCIP Optimization Suite 9.0. The updates in SCIP 9.0 include improved symmetry handling, additions and improvements of nonlinear handlers and primal heuristics, a new cut generator and two new cut selection schemes, a new branching rule, a new LP interface, and several bug fixes. The SCIP Optimization Suite 9.0 also features new Rust and C++ interfaces for SCIP, new Python interface for SoPlex, along with enhancements to existing interfaces. The SCIP Optimization Suite 9.0 also includes new and improved features in the LP solver SoPlex, the presolving library PaPILO, the parallel framework UG, the decomposition framework GCG, and the SCIP extension SCIP-SDP. These additions and enhancements have resulted in an overall performance improvement of SCIP in terms of solving time, number of nodes in the branch-and-bound tree, as well as the reliability of the solver., Comment: The release report of the SCIP Optimization Suite version 9.0

Published
2024

7. Branch and Price for the Length-Constrained Cycle Partition Problem

Author

Ghannam, Mohammed, Mexi, Gioni, Lam, Edward, and Gleixner, Ambros

Subjects
Mathematics - Optimization and Control, Computer Science - Discrete Mathematics
Abstract

The length-constrained cycle partition problem (LCCP) is a graph optimization problem in which a set of nodes must be partitioned into a minimum number of cycles. Every node is associated with a critical time and the length of every cycle must not exceed the critical time of any node in the cycle. We formulate LCCP as a set partitioning model and solve it using an exact branch-and-price approach. We use a dynamic programming-based pricing algorithm to generate improving cycles, exploiting the particular structure of the pricing problem for efficient bidirectional search and symmetry breaking. Computational results show that the LP relaxation of the set partitioning model produces strong dual bounds and our branch-and-price method improves significantly over the state of the art. It is able to solve closed instances in a fraction of the previously needed time and closes 13 previously unsolved instances, one of which has 76 nodes, a notable improvement over the previous limit of 52 nodes.

Published
2024

8. Certifying MIP-based Presolve Reductions for 0-1 Integer Linear Programs

Author

Hoen, Alexander, Oertel, Andy, Gleixner, Ambros, and Nordström, Jakob

Subjects
Mathematics - Optimization and Control
Abstract

It is well known that reformulating the original problem can be crucial for the performance of mixed-integer programming (MIP) solvers. To ensure correctness, all transformations must preserve the fea sibility status and optimal value of the problem, but there is currently no established methodology to express and verify the equivalence of two mixed-integer programs. In this work, we take a first step in this direction by showing how the correctness of MIP presolve reductions on 0-1 integer linear programs can be certified by using (and suitably extending) the VeriPB tool for pseudo-Boolean proof logging. Our experimental evaluation on both decision and optimization instances demonstrates the computational viability of the approach and leads to suggestions for future revisions of the proof format that will help to reduce the verbosity of the certificates and to accelerate the certification and verification process further.

Published
2024

9. Combining Precision Boosting with LP Iterative Refinement for Exact Linear Optimization

Author

Eifler, Leon, Nicolas-Thouvenin, Jules, and Gleixner, Ambros

Subjects
Mathematics - Optimization and Control, 65K05, 90C11, 90-08
Abstract

This article studies a combination of the two state-of-the-art algorithms for the exact solution of linear programs (LPs) over the rational numbers, i.e., without any roundoff errors or numerical tolerances. By integrating the method of precision boosting inside an LP iterative refinement loop, the combined algorithm is able to leverage the strengths of both methods: the speed of LP iterative refinement, in particular in the majority of cases when a double-precision floating-point solver is able to compute approximate solutions with small errors, and the robustness of precision boosting whenever extended levels of precision become necessary. We compare the practical performance of the resulting algorithm with both puremethods on a large set of LPs and mixed-integer programs (MIPs). The results show that the combined algorithm solves more instances than a pure LP iterative refinement approach, while being faster than pure precision boosting. When embedded in an exact branch-and-cut framework for MIPs, the combined algorithm is able to reduce the number of failed calls to the exact LP solver to zero, while maintaining the speed of the pure LP iterative refinement approach.

Published
2023

10. A proof system for certifying symmetry and optimality reasoning in integer programming

Author

van Doornmalen, Jasper, Eifler, Leon, Gleixner, Ambros, and Hojny, Christopher

Subjects
Mathematics - Optimization and Control, 05-XX COMBINATORICS, 90-XX OPERATIONS RESEARCH, MATHEMATICAL PROGRAMMING
Abstract

We present a proof system for establishing the correctness of results produced by optimization algorithms, with a focus on mixed-integer programming (MIP). Our system generalizes the seminal work of Bogaerts, Gocht, McCreesh, and Nordstr\"om (2022) for binary programs to handle any additional difficulties arising from unbounded and continuous variables, and covers a broad range of solving techniques, including symmetry handling, cutting planes, and presolving reductions. Consistency across all decisions that affect the feasible region is achieved by a pair of transitive relations on the set of solutions, which relies on the newly introduced notion of consistent branching trees. Combined with a series of machine-verifiable derivation rules, the resulting framework offers practical solutions to enhance the trust in integer programming as a methodology for applications where reliability and correctness are key.

Published
2023

11. Improving Conflict Analysis in MIP Solvers by Pseudo-Boolean Reasoning

Author

Mexi, Gioni, Berthold, Timo, Gleixner, Ambros, and Nordström, Jakob

Subjects
Mathematics - Optimization and Control, Computer Science - Discrete Mathematics
Abstract

Conflict analysis has been successfully generalized from Boolean satisfiability (SAT) solving to mixed integer programming (MIP) solvers, but although MIP solvers operate with general linear inequalities, the conflict analysis in MIP has been limited to reasoning with the more restricted class of clausal constraint. This is in contrast to how conflict analysis is performed in so-called pseudo-Boolean solving, where solvers can reason directly with 0-1 integer linear inequalities rather than with clausal constraints extracted from such inequalities. In this work, we investigate how pseudo-Boolean conflict analysis can be integrated in MIP solving, focusing on 0-1 integer linear programs (0-1 ILPs). Phrased in MIP terminology, conflict analysis can be understood as a sequence of linear combinations and cuts. We leverage this perspective to design a new conflict analysis algorithm based on mixed integer rounding (MIR) cuts, which theoretically dominates the state-of-the-art division-based method in pseudo-Boolean solving. We also report results from a first proof-of-concept implementation of different pseudo-Boolean conflict analysis methods in the open-source MIP solver SCIP. When evaluated on a large and diverse set of 0-1 ILP instances from MIPLIB 2017, our new MIR-based conflict analysis outperforms both previous pseudo-Boolean methods and the clause-based method used in MIP. Our conclusion is that pseudo-Boolean conflict analysis in MIP is a promising research direction that merits further study, and that it might also make sense to investigate the use of such conflict analysis to generate stronger no-goods in constraint programming.

Published
2023

12. Hybrid Genetic Search for Dynamic Vehicle Routing with Time Windows

Author

Ghannam, Mohammed and Gleixner, Ambros

Subjects
Computer Science - Neural and Evolutionary Computing, Mathematics - Optimization and Control
Abstract

The dynamic vehicle routing problem with time windows (DVRPTW) is a generalization of the classical VRPTW to an online setting, where customer data arrives in batches and real-time routing solutions are required. In this paper we adapt the Hybrid Genetic Search (HGS) algorithm, a successful heuristic for VRPTW, to the dynamic variant. We discuss the affected components of the HGS algorithm including giant-tour representation, cost computation, initial population, crossover, and local search. Our approach modifies these components for DVRPTW, attempting to balance solution quality and constraints on future customer arrivals. To this end, we devise methods for comparing different-sized solutions, normalizing costs, and accounting for future epochs that do not require any prior training. Despite this limitation, computational results on data from the EURO meets NeurIPS Vehicle Routing Competition 2022 demonstrate significantly improved solution quality over the best-performing baseline algorithm.

Published
2023

13. Scylla: a matrix-free fix-propagate-and-project heuristic for mixed-integer optimization

Author

Mexi, Gioni, Besançon, Mathieu, Bolusani, Suresh, Chmiela, Antonia, Hoen, Alexander, and Gleixner, Ambros

Subjects
Mathematics - Optimization and Control, Computer Science - Mathematical Software
Abstract

We introduce Scylla, a primal heuristic for mixed-integer optimization problems. It exploits approximate solves of the Linear Programming relaxations through the matrix-free Primal-Dual Hybrid Gradient algorithm with specialized termination criteria, and derives integer-feasible solutions via fix-and-propagate procedures and feasibility-pump-like updates to the objective function. Computational experiments show that the method is particularly suited to instances with hard linear relaxations.

Published
2023

20. Einleitung

Author

Schnitzhofer, Florian, Pils, Patrick, Seper-Ambros, Philipp, Schnitzhofer, Florian, Pils, Patrick, and Seper-Ambros, Philipp

Published
2024
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23. Strengthening SONC Relaxations with Constraints Derived from Variable Bounds

Author

Bestuzheva, Ksenia, Völker, Helena, and Gleixner, Ambros

Subjects
Mathematics - Optimization and Control, 90C23, 90C26, 90C30, 90C57, 90-08, 14-04
Abstract

Nonnegativity certificates can be used to obtain tight dual bounds for polynomial optimization problems. Hierarchies of certificate-based relaxations ensure convergence to the global optimum, but higher levels of such hierarchies can become very computationally expensive, and the well-known sums of squares hierarchies scale poorly with the degree of the polynomials. This has motivated research into alternative certificates and approaches to global optimization. We consider sums of nonnegative circuit polynomials (SONC) certificates, which are well-suited for sparse problems since the computational cost depends on the number of terms in the polynomials and does not depend on the degrees of the polynomials. We propose a method that guarantees that given finite variable domains, a SONC relaxation will yield a finite dual bound. This method opens up a new approach to utilizing variable bounds in SONC-based methods, which is particularly crucial for integrating SONC relaxations into branch-and-bound algorithms. We report on computational experiments with incorporating SONC relaxations into the spatial branch-and-bound algorithm of the mixed-integer nonlinear programming framework SCIP. Applying our strengthening method increases the number of instances where the SONC relaxation of the root node yielded a finite dual bound from 9 to 330 out of 349 instances in the test set.

Published
2023

24. Online Learning for Scheduling MIP Heuristics

Author

Chmiela, Antonia, Gleixner, Ambros, Lichocki, Pawel, and Pokutta, Sebastian

Subjects
Mathematics - Optimization and Control, Computer Science - Artificial Intelligence, Computer Science - Machine Learning
Abstract

Mixed Integer Programming (MIP) is NP-hard, and yet modern solvers often solve large real-world problems within minutes. This success can partially be attributed to heuristics. Since their behavior is highly instance-dependent, relying on hard-coded rules derived from empirical testing on a large heterogeneous corpora of benchmark instances might lead to sub-optimal performance. In this work, we propose an online learning approach that adapts the application of heuristics towards the single instance at hand. We replace the commonly used static heuristic handling with an adaptive framework exploiting past observations about the heuristic's behavior to make future decisions. In particular, we model the problem of controlling Large Neighborhood Search and Diving - two broad and complex classes of heuristics - as a multi-armed bandit problem. Going beyond existing work in the literature, we control two different classes of heuristics simultaneously by a single learning agent. We verify our approach numerically and show consistent node reductions over the MIPLIB 2017 Benchmark set. For harder instances that take at least 1000 seconds to solve, we observe a speedup of 4%., Comment: Published in the Proceedings of CPAIOR 2023

Published
2023

25. Safe and Verified Gomory Mixed Integer Cuts in a Rational MIP Framework

Author

Eifler, Leon and Gleixner, Ambros

Subjects
Mathematics - Optimization and Control, 65K05, 90C11, 90-08
Abstract

This paper is concerned with the exact solution of mixed-integer programs (MIPs) over the rational numbers, i.e., without any roundoff errors and error tolerances. Here, one computational bottleneck that should be avoided whenever possible is to employ large-scale symbolic computations. Instead it is often possible to use safe directed rounding methods, e.g., to generate provably correct dual bounds. In this work, we continue to leverage this paradigm and extend an exact branch-and-bound framework by separation routines for safe cutting planes, based on the approach first introduced by Cook, Dash, Fukasawa, and Goycoolea in 2009. Constraints are aggregated safely using approximate dual multipliers from an LP solve, followed by mixed-integer rounding to generate provably valid, although slightly weaker inequalities. We generalize this approach to problem data that is not representable in floating-point arithmetic, add routines for controlling the encoding length of the resulting cutting planes, and show how these cutting planes can be verified according to the VIPR certificate standard. Furthermore, we analyze the performance impact of these cutting planes in the context of an exact MIP framework, showing that we can solve 21.5% more instances and reduce solving times by 26.8% on the MIPLIB 2017 benchmark test set.

Published
2023

26. Enabling Research through the SCIP Optimization Suite 8.0

Author

Bestuzheva, Ksenia, Besançon, Mathieu, Chen, Wei-Kun, Chmiela, Antonia, Donkiewicz, Tim, van Doornmalen, Jasper, Eifler, Leon, Gaul, Oliver, Gamrath, Gerald, Gleixner, Ambros, Gottwald, Leona, Graczyk, Christoph, Halbig, Katrin, Hoen, Alexander, Hojny, Christopher, van der Hulst, Rolf, Koch, Thorsten, Lübbecke, Marco, Maher, Stephen J., Matter, Frederic, Mühmer, Erik, Müller, Benjamin, Pfetsch, Marc E., Rehfeldt, Daniel, Schlein, Steffan, Schlösser, Franziska, Serrano, Felipe, Shinano, Yuji, Sofranac, Boro, Turner, Mark, Vigerske, Stefan, Wegscheider, Fabian, Wellner, Philipp, Weninger, Dieter, and Witzig, Jakob

Subjects
Mathematics - Optimization and Control, 90C05, 90C10, 90C11, 90C30, 90C90, 65Y05
Abstract

The SCIP Optimization Suite provides a collection of software packages for mathematical optimization centered around the constraint integer programming framework SCIP. The focus of this paper is on the role of the SCIP Optimization Suite in supporting research. SCIP's main design principles are discussed, followed by a presentation of the latest performance improvements and developments in version 8.0, which serve both as examples of SCIP's application as a research tool and as a platform for further developments. Further, the paper gives an overview of interfaces to other programming and modeling languages, new features that expand the possibilities for user interaction with the framework, and the latest developments in several extensions built upon SCIP., Comment: arXiv admin note: substantial text overlap with arXiv:2112.08872

Published
2023
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27. Codex Hacks HackerRank: Memorization Issues and a Framework for Code Synthesis Evaluation

Author

Karmakar, Anjan, Prenner, Julian Aron, D'Ambros, Marco, and Robbes, Romain

Subjects
Computer Science - Software Engineering, Computer Science - Machine Learning
Abstract

The Codex model has demonstrated extraordinary competence in synthesizing code from natural language problem descriptions. However, in order to reveal unknown failure modes and hidden biases, such large-scale models must be systematically subjected to multiple and diverse evaluation studies. In this work, we evaluate the code synthesis capabilities of the Codex model based on a set of 115 Python problem statements from a popular competitive programming portal: HackerRank. Our evaluation shows that Codex is indeed proficient in Python, solving 96% of the problems in a zero-shot setting, and 100% of the problems in a few-shot setting. However, Codex exhibits clear signs of generating memorized code based on our evaluation. This is alarming, especially since the adoption and use of such models could directly impact how code is written and produced in the foreseeable future. With this in mind, we further discuss and highlight some of the prominent risks associated with large-scale models of source code. Finally, we propose a framework for code-synthesis evaluation using variations of problem statements based on mutations.

Published
2022

28. Certifying MIP-Based Presolve Reductions for Integer Linear Programs

Author

Hoen, Alexander, Oertel, Andy, Gleixner, Ambros, Nordström, Jakob, Goos, Gerhard, Series Editor, Hartmanis, Juris, Founding Editor, van Leeuwen, Jan, Series Editor, Hutchison, David, Editorial Board Member, Kanade, Takeo, Editorial Board Member, Kittler, Josef, Editorial Board Member, Kleinberg, Jon M., Editorial Board Member, Kobsa, Alfred, Series Editor, Mattern, Friedemann, Editorial Board Member, Mitchell, John C., Editorial Board Member, Naor, Moni, Editorial Board Member, Nierstrasz, Oscar, Series Editor, Pandu Rangan, C., Editorial Board Member, Sudan, Madhu, Series Editor, Terzopoulos, Demetri, Editorial Board Member, Tygar, Doug, Editorial Board Member, Weikum, Gerhard, Series Editor, Vardi, Moshe Y, Series Editor, Bertino, Elisa, Editorial Board Member, Gao, Wen, Editorial Board Member, Steffen, Bernhard, Editorial Board Member, Yung, Moti, Editorial Board Member, Woeginger, Gerhard, Editorial Board Member, and Dilkina, Bistra, editor

Published
2024
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29. Branch and Cut for Partitioning a Graph into a Cycle of Clusters

Author

Eifler, Leon, Witzig, Jakob, Gleixner, Ambros, Hartmanis, Juris, Founding Editor, Goos, Gerhard, Founding Editor, Bertino, Elisa, Editorial Board Member, Gao, Wen, Editorial Board Member, Steffen, Bernhard, Editorial Board Member, Yung, Moti, Editorial Board Member, Basu, Amitabh, editor, Mahjoub, Ali Ridha, editor, and Salazar González, Juan José, editor

Published
2024
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30. Creation and Maintenance of Public Real Estate Records - Business Models in Croatia

Author

Ivanović, Milan, Ambroš, Franjo, Stojnović, Vedran, Kacprzyk, Janusz, Series Editor, Gomide, Fernando, Advisory Editor, Kaynak, Okyay, Advisory Editor, Liu, Derong, Advisory Editor, Pedrycz, Witold, Advisory Editor, Polycarpou, Marios M., Advisory Editor, Rudas, Imre J., Advisory Editor, Wang, Jun, Advisory Editor, Keser, Tomislav, editor, Ademović, Naida, editor, Desnica, Eleonora, editor, and Grgić, Ivan, editor

Published
2024
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31. Efficient Separation of RLT Cuts for Implicit and Explicit Bilinear Terms

Author

Bestuzheva, Ksenia, Gleixner, Ambros, and Achterberg, Tobias

Subjects
Mathematics - Optimization and Control, 90-08, 90C11, 90C20, 90C26, 90C57
Abstract

The reformulation-linearization technique (RLT) is a prominent approach to constructing tight linear relaxations of non-convex continuous and mixed-integer optimization problems. The goal of this paper is to extend the applicability and improve the performance of RLT for bilinear product relations. First, a method for detecting bilinear product relations implicitly contained in mixed-integer linear programs is developed based on analyzing linear constraints with binary variables, thus enabling the application of bilinear RLT to a new class of problems. Our second contribution addresses the high computational cost of RLT cut separation, which presents one of the major difficulties in applying RLT efficiently in practice. We propose a new RLT cutting plane separation algorithm which identifies combinations of linear constraints and bound factors that are expected to yield an inequality that is violated by the current relaxation solution. This algorithm is applicable to RLT cuts generated for all types of bilinear terms, including but not limited to the detected implicit products. A detailed computational study based on implementations in two solvers evaluates the performance impact of the proposed methods., Comment: 28 pages, 0 figures. This is the extended version of the article published in: Integer Programming and Combinatorial Optimization: 24th International Conference, IPCO 2023

Published
2022
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32. Strengthening SONC Relaxations with Constraints Derived from Variable Bounds

Author

Bestuzheva, Ksenia, Gleixner, Ambros, and Völker, Helena

Subjects
Mathematics - Optimization and Control, 90C23, 90C26, 90C30, 90C57, 90-08, 14-04
Abstract

Certificates of polynomial nonnegativity can be used to obtain tight dual bounds for polynomial optimization problems. We consider Sums of Nonnegative Circuit (SONC) polynomials certificates, which are well suited for sparse problems since the computational cost depends only on the number of terms in the polynomials and does not depend on the degrees of the polynomials. This work is a first step to integrating SONC-based relaxations of polynomial problems into a branch-and-bound algorithm. To this end, the SONC relaxation for constrained optimization problems is extended in order to better utilize variable bounds, since this property is key for the success of a relaxation in the context of branch-and-bound. Computational experiments show that the proposed extension is crucial for making the SONC relaxations applicable to most constrained polynomial optimization problems and for integrating the two approaches., Comment: 4 pages, 0 figures, published in proceedings of the Hungarian Global Optimization Workshop HUGO 2022

Published
2022

33. First Come First Served: The Impact of File Position on Code Review

Author

Fregnan, Enrico, Braz, Larissa, D'Ambros, Marco, Çalikli, Gül, and Bacchelli, Alberto

Subjects
Computer Science - Software Engineering
Abstract

The most popular code review tools (e.g., Gerrit and GitHub) present the files to review sorted in alphabetical order. Could this choice or, more generally, the relative position in which a file is presented bias the outcome of code reviews? We investigate this hypothesis by triangulating complementary evidence in a two-step study. First, we observe developers' code review activity. We analyze the review comments pertaining to 219,476 Pull Requests (PRs) from 138 popular Java projects on GitHub. We found files shown earlier in a PR to receive more comments than files shown later, also when controlling for possible confounding factors: e.g., the presence of discussion threads or the lines added in a file. Second, we measure the impact of file position on defect finding in code review. Recruiting 106 participants, we conduct an online controlled experiment in which we measure participants' performance in detecting two unrelated defects seeded into two different files. Participants are assigned to one of two treatments in which the position of the defective files is switched. For one type of defect, participants are not affected by its file's position; for the other, they have 64% lower odds to identify it when its file is last as opposed to first. Overall, our findings provide evidence that the relative position in which files are presented has an impact on code reviews' outcome; we discuss these results and implications for tool design and code review. Data and materials: https://doi.org/10.5281/zenodo.6901285, Comment: This paper has been accepted at ESEC/FSE '22 (30th ACM Joint European Software Engineering Conference and Symposium on the Foundations of Software Engineering)

Published
2022
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34. PaPILO: A Parallel Presolving Library for Integer and Linear Programming with Multiprecision Support

Author

Gleixner, Ambros, Gottwald, Leona, and Hoen, Alexander

Subjects
Mathematics - Optimization and Control
Abstract

Presolving has become an essential component of modern MIP solvers both in terms of computational performance and numerical robustness. In this paper, we present PaPILO, a new C++ header-only library that provides a large set of presolving routines for MIP and LP problems from the literature. The creation of PaPILO was motivated by the current lack of (a) solver-independent implementations that (b) exploit parallel hardware, and (c) support multiprecision arithmetic. Traditionally, presolving is designed to be fast. Whenever necessary, its low computational overhead is usually achieved by strict working limits. PaPILO's parallelization framework aims at reducing the computational overhead also when presolving is executed more aggressively or is applied to large-scale problems. To rule out conflicts between parallel presolve reductions, PaPILO uses a transaction-based design. This helps to avoid both the memory-intensive allocation of multiple copies of the problem and special synchronization between presolvers. Additionally, the use of Intel's TBB library aids PaPILO to efficiently exploit recursive parallelism within expensive presolving routines such as probing, dominated columns, or constraint sparsification. We provide an overview of PaPILO's capabilities and insights into important design choices.

Published
2022

35. The Machine Learning for Combinatorial Optimization Competition (ML4CO): Results and Insights

Author

Gasse, Maxime, Cappart, Quentin, Charfreitag, Jonas, Charlin, Laurent, Chételat, Didier, Chmiela, Antonia, Dumouchelle, Justin, Gleixner, Ambros, Kazachkov, Aleksandr M., Khalil, Elias, Lichocki, Pawel, Lodi, Andrea, Lubin, Miles, Maddison, Chris J., Morris, Christopher, Papageorgiou, Dimitri J., Parjadis, Augustin, Pokutta, Sebastian, Prouvost, Antoine, Scavuzzo, Lara, Zarpellon, Giulia, Yang, Linxin, Lai, Sha, Wang, Akang, Luo, Xiaodong, Zhou, Xiang, Huang, Haohan, Shao, Shengcheng, Zhu, Yuanming, Zhang, Dong, Quan, Tao, Cao, Zixuan, Xu, Yang, Huang, Zhewei, Zhou, Shuchang, Binbin, Chen, Minggui, He, Hao, Hao, Zhiyu, Zhang, Zhiwu, An, and Kun, Mao

Subjects
Computer Science - Machine Learning, Computer Science - Neural and Evolutionary Computing, Mathematics - Optimization and Control, Statistics - Machine Learning
Abstract

Combinatorial optimization is a well-established area in operations research and computer science. Until recently, its methods have focused on solving problem instances in isolation, ignoring that they often stem from related data distributions in practice. However, recent years have seen a surge of interest in using machine learning as a new approach for solving combinatorial problems, either directly as solvers or by enhancing exact solvers. Based on this context, the ML4CO aims at improving state-of-the-art combinatorial optimization solvers by replacing key heuristic components. The competition featured three challenging tasks: finding the best feasible solution, producing the tightest optimality certificate, and giving an appropriate solver configuration. Three realistic datasets were considered: balanced item placement, workload apportionment, and maritime inventory routing. This last dataset was kept anonymous for the contestants., Comment: Neurips 2021 competition. arXiv admin note: text overlap with arXiv:2112.12251 by other authors

Published
2022

38. Fatty acid conjugated EPI-X4 derivatives with increased activity and in vivo stability

Author

Harms, Mirja, Haase, André, Rodríguez-Alfonso, Armando, Löffler, Jessica, Almeida-Hernández, Yasser, Ruiz-Blanco, Yasser B., Albers, Dan, Gilg, Andrea, von Bank, Franziska, Zech, Fabian, Groß, Rüdiger, Datta, Moumita, Jaikishan, Janeni, Draphoen, Bastian, Habib, Monica, Ständker, Ludger, Wiese, Sebastian, Lindén, Mika, Winter, Gordon, Rasche, Volker, Beer, Ambros J., Jumaa, Hassan, Abadi, Ashraf H., Kirchhoff, Frank, Busch, Maike, Dünker, Nicole, Sanchez-Garcia, Elsa, and Münch, Jan

Published
2024
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39. The SCIP Optimization Suite 8.0

Author

Bestuzheva, Ksenia, Besançon, Mathieu, Chen, Wei-Kun, Chmiela, Antonia, Donkiewicz, Tim, van Doornmalen, Jasper, Eifler, Leon, Gaul, Oliver, Gamrath, Gerald, Gleixner, Ambros, Gottwald, Leona, Graczyk, Christoph, Halbig, Katrin, Hoen, Alexander, Hojny, Christopher, van der Hulst, Rolf, Koch, Thorsten, Lübbecke, Marco, Maher, Stephen J., Matter, Frederic, Mühmer, Erik, Müller, Benjamin, Pfetsch, Marc E., Rehfeldt, Daniel, Schlein, Steffan, Schlösser, Franziska, Serrano, Felipe, Shinano, Yuji, Sofranac, Boro, Turner, Mark, Vigerske, Stefan, Wegscheider, Fabian, Wellner, Philipp, Weninger, Dieter, and Witzig, Jakob

Subjects
Mathematics - Optimization and Control, 90C05, 90C10, 90C11, 90C30, 90C90, 65Y05
Abstract

The SCIP Optimization Suite provides a collection of software packages for mathematical optimization centered around the constraint integer programming framework SCIP. This paper discusses enhancements and extensions contained in version 8.0 of the SCIP Optimization Suite. Major updates in SCIP include improvements in symmetry handling and decomposition algorithms, new cutting planes, a new plugin type for cut selection, and a complete rework of the way nonlinear constraints are handled. Additionally, SCIP 8.0 now supports interfaces for Julia as well as Matlab. Further, UG now includes a unified framework to parallelize all solvers, a utility to analyze computational experiments has been added to GCG, dual solutions can be postsolved by PaPILO, new heuristics and presolving methods were added to SCIP-SDP, and additional problem classes and major performance improvements are available in SCIP-Jack., Comment: 114 pages, 8 figures

Published
2021

43. Clinical relevance of timing of assessment of ICU mortality in patients with moderate-to-severe Acute Respiratory Distress Syndrome

Author

Villar, Jesús, González-Martin, Jesús M., Añón, José M., Ferrando, Carlos, Soler, Juan A., Mosteiro, Fernando, Mora-Ordoñez, Juan M., Ambrós, Alfonso, Fernández, Lorena, Montiel, Raquel, Vidal, Anxela, Muñoz, Tomás, Pérez-Méndez, Lina, Rodríguez-Suárez, Pedro, Fernández, Cristina, Fernández, Rosa L., Szakmany, Tamas, Burns, Karen E. A., Steyerberg, Ewout W., and Slutsky, Arthur S.

Published
2023
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44. An Algorithm-Independent Measure of Progress for Linear Constraint Propagation

Author

Sofranac, Boro, Gleixner, Ambros, and Pokutta, Sebastian

Subjects
Mathematics - Optimization and Control, 90C11
Abstract

Propagation of linear constraints has become a crucial sub-routine in modern Mixed-Integer Programming (MIP) solvers. In practice, iterative algorithms with tolerance-based stopping criteria are used to avoid problems with slow or infinite convergence. However, these heuristic stopping criteria can pose difficulties for fairly comparing the efficiency of different implementations of iterative propagation algorithms in a real-world setting. Most significantly, the presence of unbounded variable domains in the problem formulation makes it difficult to quantify the relative size of reductions performed on them. In this work, we develop a method to measure -- independently of the algorithmic design -- the progress that a given iterative propagation procedure has made at a given point in time during its execution. Our measure makes it possible to study and better compare the behavior of bounds propagation algorithms for linear constraints. We apply the new measure to answer two questions of practical relevance: (i) We investigate to what extent heuristic stopping criteria can lead to premature termination on real-world MIP instances. (ii) We compare a GPU-parallel propagation algorithm against a sequential state-of-the-art implementation and show that the parallel version is even more competitive in a real-world setting than originally reported.

Published
2021

49. Learning to Schedule Heuristics in Branch-and-Bound

Author

Chmiela, Antonia, Khalil, Elias B., Gleixner, Ambros, Lodi, Andrea, and Pokutta, Sebastian

Subjects
Computer Science - Machine Learning, Computer Science - Discrete Mathematics, Mathematics - Optimization and Control
Abstract

Primal heuristics play a crucial role in exact solvers for Mixed Integer Programming (MIP). While solvers are guaranteed to find optimal solutions given sufficient time, real-world applications typically require finding good solutions early on in the search to enable fast decision-making. While much of MIP research focuses on designing effective heuristics, the question of how to manage multiple MIP heuristics in a solver has not received equal attention. Generally, solvers follow hard-coded rules derived from empirical testing on broad sets of instances. Since the performance of heuristics is instance-dependent, using these general rules for a particular problem might not yield the best performance. In this work, we propose the first data-driven framework for scheduling heuristics in an exact MIP solver. By learning from data describing the performance of primal heuristics, we obtain a problem-specific schedule of heuristics that collectively find many solutions at minimal cost. We provide a formal description of the problem and propose an efficient algorithm for computing such a schedule. Compared to the default settings of a state-of-the-art academic MIP solver, we are able to reduce the average primal integral by up to 49% on a class of challenging instances.

Published
2021

50. A Computational Study of Perspective Cuts

Author

Bestuzheva, Ksenia, Gleixner, Ambros, and Vigerske, Stefan

Subjects
Mathematics - Optimization and Control, 90-04, 90-08, 90C11, 90C26, 90C30, 90C57, G.4
Abstract

The benefits of cutting planes based on the perspective function are well known for many specific classes of mixed-integer nonlinear programs with on/off structures. However, we are not aware of any empirical studies that evaluate their applicability and computational impact over large, heterogeneous test sets in general-purpose solvers. This paper provides a detailed computational study of perspective cuts within a linear programming based branch-and-cut solver for general mixed-integer nonlinear programs. Within this study, we extend the applicability of perspective cuts from convex to nonconvex nonlinearities. This generalization is achieved by applying a perspective strengthening to valid linear inequalities which separate solutions of linear relaxations. The resulting method can be applied to any constraint where all variables appearing in nonlinear terms are semi-continuous and depend on at least one common indicator variable. Our computational experiments show that adding perspective cuts for convex constraints yields a consistent improvement of performance, and adding perspective cuts for nonconvex constraints reduces branch-and-bound tree sizes and strengthens the root node relaxation, but has no significant impact on the overall mean time.

Published
2021

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