New algorithms and hardness for incremental single-source shortest paths in directed graphs

Maximilian Probst Gutenberg; Virginia Vassilevska Williams; Nicole Wein

doi:10.1145/3357713.3384236

New algorithms and hardness for incremental single-source shortest paths in directed graphs

Maximilian Probst Gutenberg, Virginia Vassilevska Williams, Nicole Wein

Algorithms and Complexity

Publikation: Bidrag til bog/antologi/rapport › Konferencebidrag i proceedings › Forskning › peer review

22 Citationer (Scopus)

7 Downloads (Pure)

Abstract

In the dynamic Single-Source Shortest Paths (SSSP) problem, we are given a graph G=(V,E) subject to edge insertions and deletions and a source vertex sg V, and the goal is to maintain the distance d(s,t) for all tg V. Fine-grained complexity has provided strong lower bounds for exact partially dynamic SSSP and approximate fully dynamic SSSP [ESA'04, FOCS'14, STOC'15]. Thus much focus has been directed towards finding efficient partially dynamic (1+")-approximate SSSP algorithms [STOC'14, ICALP'15, SODA'14, FOCS'14, STOC'16, SODA'17, ICALP'17, ICALP'19, STOC'19, SODA'20, SODA'20]. Despite this rich literature, for directed graphs there are no known deterministic algorithms for (1+")-approximate dynamic SSSP that perform better than the classic ES-tree [JACM'81]. We present the first such algorithm. We present a deterministic data structure for incremental SSSP in weighted directed graphs with total update time Õ(n² logW/"^O(1)) which is near-optimal for very dense graphs; here W is the ratio of the largest weight in the graph to the smallest. Our algorithm also improves over the best known partially dynamic randomized algorithm for directed SSSP by Henzinger et al. [STOC'14, ICALP'15] if m=ω(n^1.1). Complementing our algorithm, we provide improved conditional lower bounds. Henzinger et al. [STOC'15] showed that under the OMv Hypothesis, the partially dynamic exact s-t Shortest Path problem in undirected graphs requires amortized update or query time m^1/2-o(1), given polynomial preprocessing time. Under a new hypothesis about finding Cliques, we improve the update and query lower bound for algorithms with polynomial preprocessing time to m^0.626-o(1). Further, under the k-Cycle hypothesis, we show that any partially dynamic SSSP algorithm with O(m^2-") preprocessing time requires amortized update or query time m^1-o(1), which is essentially optimal. All previous conditional lower bounds that come close to our bound [ESA'04,FOCS'14] only held for "combinatorial" algorithms, while our new lower bound does not make such restrictions.

Originalsprog	Engelsk
Titel	STOC 2020 : Proceedings of the 52nd Annual ACM SIGACT Symposium on Theory of Computing
Redaktører	Konstantin Makarychev, Yury Makarychev, Madhur Tulsiani, Gautam Kamath, Julia Chuzhoy
Antal sider	14
Forlag	Association for Computing Machinery
Publikationsdato	2020
Sider	153-166
ISBN (Trykt)	978-1-4503-6979-4
DOI	https://doi.org/10.1145/3357713.3384236
Status	Udgivet - 2020
Begivenhed	52nd Annual ACM SIGACT Symposium on Theory of Computing, STOC 2020 - Chicago, USA Varighed: 22 jun. 2020 → 26 jun. 2020

Konference

Konference	52nd Annual ACM SIGACT Symposium on Theory of Computing, STOC 2020
Land/Område	USA
By	Chicago
Periode	22/06/2020 → 26/06/2020
Sponsor	ACM Special Interest Group on Algorithms and Computation Theory (SIGACT)

Navn	Proceedings of the Annual ACM Symposium on Theory of Computing
ISSN	0737-8017

Bibliografisk note

Funding Information:
∗The first author was visiting Massachusetts Institute of Technology, Massachusetts, US, when the work was done and is supported by Thorup’s Investigator Grant from the Villum Foundation under Grant No. 16582 and by STIBOFONDEN’s IT Travel Grant for PhD Students. The second author is supported by an NSF CAREER Award, NSF Grants CCF-1528078 and CCF-1514339, a BSF Grant BSF:2012338, a Sloan Research Fellowship and a Google faculty fellowship. The third author is supported by an NSF Graduate Fellowship and NSF Grant CCF-1514339.

Publisher Copyright:
© 2020 ACM.

Adgang til dokumentet

10.1145/3357713.3384236Licens: Ikke-specificeret

New algorithms and hardness for incremental single-source shortest paths in directed graphsForlagets udgivne version, 0,99 MBLicens: Ikke-specificeret

Citationsformater

Gutenberg, M. P., Vassilevska Williams, V., & Wein, N. (2020). New algorithms and hardness for incremental single-source shortest paths in directed graphs. I K. Makarychev, Y. Makarychev, M. Tulsiani, G. Kamath, & J. Chuzhoy (red.), STOC 2020 : Proceedings of the 52nd Annual ACM SIGACT Symposium on Theory of Computing (s. 153-166). Association for Computing Machinery. https://doi.org/10.1145/3357713.3384236

New algorithms and hardness for incremental single-source shortest paths in directed graphs. / Gutenberg, Maximilian Probst; Vassilevska Williams, Virginia; Wein, Nicole.
STOC 2020 : Proceedings of the 52nd Annual ACM SIGACT Symposium on Theory of Computing. red. / Konstantin Makarychev; Yury Makarychev; Madhur Tulsiani; Gautam Kamath; Julia Chuzhoy. Association for Computing Machinery, 2020. s. 153-166 (Proceedings of the Annual ACM Symposium on Theory of Computing).

Publikation: Bidrag til bog/antologi/rapport › Konferencebidrag i proceedings › Forskning › peer review

Gutenberg, MP, Vassilevska Williams, V & Wein, N 2020, New algorithms and hardness for incremental single-source shortest paths in directed graphs. i K Makarychev, Y Makarychev, M Tulsiani, G Kamath & J Chuzhoy (red), STOC 2020 : Proceedings of the 52nd Annual ACM SIGACT Symposium on Theory of Computing. Association for Computing Machinery, Proceedings of the Annual ACM Symposium on Theory of Computing, s. 153-166, 52nd Annual ACM SIGACT Symposium on Theory of Computing, STOC 2020, Chicago, USA, 22/06/2020. https://doi.org/10.1145/3357713.3384236

Gutenberg MP, Vassilevska Williams V, Wein N. New algorithms and hardness for incremental single-source shortest paths in directed graphs. I Makarychev K, Makarychev Y, Tulsiani M, Kamath G, Chuzhoy J, red., STOC 2020 : Proceedings of the 52nd Annual ACM SIGACT Symposium on Theory of Computing. Association for Computing Machinery. 2020. s. 153-166. (Proceedings of the Annual ACM Symposium on Theory of Computing). doi: 10.1145/3357713.3384236

Gutenberg, Maximilian Probst ; Vassilevska Williams, Virginia ; Wein, Nicole. / New algorithms and hardness for incremental single-source shortest paths in directed graphs. STOC 2020 : Proceedings of the 52nd Annual ACM SIGACT Symposium on Theory of Computing. red. / Konstantin Makarychev ; Yury Makarychev ; Madhur Tulsiani ; Gautam Kamath ; Julia Chuzhoy. Association for Computing Machinery, 2020. s. 153-166 (Proceedings of the Annual ACM Symposium on Theory of Computing).

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title = "New algorithms and hardness for incremental single-source shortest paths in directed graphs",

abstract = "In the dynamic Single-Source Shortest Paths (SSSP) problem, we are given a graph G=(V,E) subject to edge insertions and deletions and a source vertex sg V, and the goal is to maintain the distance d(s,t) for all tg V. Fine-grained complexity has provided strong lower bounds for exact partially dynamic SSSP and approximate fully dynamic SSSP [ESA'04, FOCS'14, STOC'15]. Thus much focus has been directed towards finding efficient partially dynamic (1+{"})-approximate SSSP algorithms [STOC'14, ICALP'15, SODA'14, FOCS'14, STOC'16, SODA'17, ICALP'17, ICALP'19, STOC'19, SODA'20, SODA'20]. Despite this rich literature, for directed graphs there are no known deterministic algorithms for (1+{"})-approximate dynamic SSSP that perform better than the classic ES-tree [JACM'81]. We present the first such algorithm. We present a deterministic data structure for incremental SSSP in weighted directed graphs with total update time {\~O}(n2 logW/{"}O(1)) which is near-optimal for very dense graphs; here W is the ratio of the largest weight in the graph to the smallest. Our algorithm also improves over the best known partially dynamic randomized algorithm for directed SSSP by Henzinger et al. [STOC'14, ICALP'15] if m=ω(n1.1). Complementing our algorithm, we provide improved conditional lower bounds. Henzinger et al. [STOC'15] showed that under the OMv Hypothesis, the partially dynamic exact s-t Shortest Path problem in undirected graphs requires amortized update or query time m1/2-o(1), given polynomial preprocessing time. Under a new hypothesis about finding Cliques, we improve the update and query lower bound for algorithms with polynomial preprocessing time to m0.626-o(1). Further, under the k-Cycle hypothesis, we show that any partially dynamic SSSP algorithm with O(m2-{"}) preprocessing time requires amortized update or query time m1-o(1), which is essentially optimal. All previous conditional lower bounds that come close to our bound [ESA'04,FOCS'14] only held for {"}combinatorial{"} algorithms, while our new lower bound does not make such restrictions.",

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author = "Gutenberg, {Maximilian Probst} and {Vassilevska Williams}, Virginia and Nicole Wein",

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N2 - In the dynamic Single-Source Shortest Paths (SSSP) problem, we are given a graph G=(V,E) subject to edge insertions and deletions and a source vertex sg V, and the goal is to maintain the distance d(s,t) for all tg V. Fine-grained complexity has provided strong lower bounds for exact partially dynamic SSSP and approximate fully dynamic SSSP [ESA'04, FOCS'14, STOC'15]. Thus much focus has been directed towards finding efficient partially dynamic (1+")-approximate SSSP algorithms [STOC'14, ICALP'15, SODA'14, FOCS'14, STOC'16, SODA'17, ICALP'17, ICALP'19, STOC'19, SODA'20, SODA'20]. Despite this rich literature, for directed graphs there are no known deterministic algorithms for (1+")-approximate dynamic SSSP that perform better than the classic ES-tree [JACM'81]. We present the first such algorithm. We present a deterministic data structure for incremental SSSP in weighted directed graphs with total update time Õ(n2 logW/"O(1)) which is near-optimal for very dense graphs; here W is the ratio of the largest weight in the graph to the smallest. Our algorithm also improves over the best known partially dynamic randomized algorithm for directed SSSP by Henzinger et al. [STOC'14, ICALP'15] if m=ω(n1.1). Complementing our algorithm, we provide improved conditional lower bounds. Henzinger et al. [STOC'15] showed that under the OMv Hypothesis, the partially dynamic exact s-t Shortest Path problem in undirected graphs requires amortized update or query time m1/2-o(1), given polynomial preprocessing time. Under a new hypothesis about finding Cliques, we improve the update and query lower bound for algorithms with polynomial preprocessing time to m0.626-o(1). Further, under the k-Cycle hypothesis, we show that any partially dynamic SSSP algorithm with O(m2-") preprocessing time requires amortized update or query time m1-o(1), which is essentially optimal. All previous conditional lower bounds that come close to our bound [ESA'04,FOCS'14] only held for "combinatorial" algorithms, while our new lower bound does not make such restrictions.

AB - In the dynamic Single-Source Shortest Paths (SSSP) problem, we are given a graph G=(V,E) subject to edge insertions and deletions and a source vertex sg V, and the goal is to maintain the distance d(s,t) for all tg V. Fine-grained complexity has provided strong lower bounds for exact partially dynamic SSSP and approximate fully dynamic SSSP [ESA'04, FOCS'14, STOC'15]. Thus much focus has been directed towards finding efficient partially dynamic (1+")-approximate SSSP algorithms [STOC'14, ICALP'15, SODA'14, FOCS'14, STOC'16, SODA'17, ICALP'17, ICALP'19, STOC'19, SODA'20, SODA'20]. Despite this rich literature, for directed graphs there are no known deterministic algorithms for (1+")-approximate dynamic SSSP that perform better than the classic ES-tree [JACM'81]. We present the first such algorithm. We present a deterministic data structure for incremental SSSP in weighted directed graphs with total update time Õ(n2 logW/"O(1)) which is near-optimal for very dense graphs; here W is the ratio of the largest weight in the graph to the smallest. Our algorithm also improves over the best known partially dynamic randomized algorithm for directed SSSP by Henzinger et al. [STOC'14, ICALP'15] if m=ω(n1.1). Complementing our algorithm, we provide improved conditional lower bounds. Henzinger et al. [STOC'15] showed that under the OMv Hypothesis, the partially dynamic exact s-t Shortest Path problem in undirected graphs requires amortized update or query time m1/2-o(1), given polynomial preprocessing time. Under a new hypothesis about finding Cliques, we improve the update and query lower bound for algorithms with polynomial preprocessing time to m0.626-o(1). Further, under the k-Cycle hypothesis, we show that any partially dynamic SSSP algorithm with O(m2-") preprocessing time requires amortized update or query time m1-o(1), which is essentially optimal. All previous conditional lower bounds that come close to our bound [ESA'04,FOCS'14] only held for "combinatorial" algorithms, while our new lower bound does not make such restrictions.

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