Fundamental Limits on the Regret of Online Network-Caching

Optimal caching of files in a content distribution network (CDN) is a problem of fundamental and growing commercial interest. Although many different caching algorithms are in use today, the fundamental performance limits of the network caching algorithms from an online learning point-of-view remain poorly understood to date. In this paper, we resolve this question in the following two settings: (1) a single user connected to a single cache, and (2) a set of users and a set of caches interconnected through a bipartite network. Recently, an online gradient-based coded caching policy was shown to enjoy sub-linear regret. However, due to the lack of known regret lower bounds, the question of the optimality of the proposed policy was left open. In this paper, we settle this question by deriving tight non-asymptotic regret lower bounds in the above settings. In addition to that, we propose a new Follow-the-Perturbed-Leader-based uncoded caching policy with near-optimal regret. Technically, the lower-bounds are obtained by relating the online caching problem to the classic probabilistic paradigm of balls-into-bins. Our proofs make extensive use of a new result on the expected load in the most populated half of the bins, which might also be of independent interest. We evaluate the performance of the caching policies by experimenting with the popular MovieLens dataset and conclude the paper with design recommendations and a list of open problems.

[1]  Ramesh K. Sitaraman,et al.  The Akamai network: a platform for high-performance internet applications , 2010, OPSR.

[2]  Yunnan Wu,et al.  Network coding for distributed storage systems , 2010, IEEE Trans. Inf. Theory.

[3]  Philippe Flajolet,et al.  Birthday Paradox, Coupon Collectors, Caching Algorithms and Self-Organizing Search , 1992, Discret. Appl. Math..

[4]  Sergei Vassilvitskii,et al.  Competitive caching with machine learned advice , 2018, ICML.

[5]  Gianfranco Ciardo,et al.  Role of Aging, Frequency, and Size in Web Cache Replacement Policies , 2001, HPCN Europe.

[6]  Alexandros G. Dimakis,et al.  FemtoCaching: Wireless Content Delivery Through Distributed Caching Helpers , 2013, IEEE Transactions on Information Theory.

[7]  Roy Friedman,et al.  TinyLFU: A Highly Efficient Cache Admission Policy , 2014, 2014 22nd Euromicro International Conference on Parallel, Distributed, and Network-Based Processing.

[8]  Bruce M. Maggs,et al.  Algorithmic Nuggets in Content Delivery , 2015, CCRV.

[9]  Li Fan,et al.  Web caching and Zipf-like distributions: evidence and implications , 1999, IEEE INFOCOM '99. Conference on Computer Communications. Proceedings. Eighteenth Annual Joint Conference of the IEEE Computer and Communications Societies. The Future is Now (Cat. No.99CH36320).

[10]  Abraham Silberschatz,et al.  Operating System Principles , 2004 .

[11]  Sanjeev Arora,et al.  Efficient algorithms for online convex optimization and their applications , 2006 .

[12]  Giuseppe Caire,et al.  Cache Optimization Models and Algorithms , 2019, Found. Trends Commun. Inf. Theory.

[13]  W. Rudin Principles of mathematical analysis , 1964 .

[14]  James F. Kurose,et al.  On the steady-state of cache networks , 2013, 2013 Proceedings IEEE INFOCOM.

[15]  George Iosifidis,et al.  Learning to Cache With No Regrets , 2019, IEEE INFOCOM 2019 - IEEE Conference on Computer Communications.

[16]  Giuseppe Caire,et al.  Fundamental Limits of Caching in Wireless D2D Networks , 2014, IEEE Transactions on Information Theory.

[17]  Zheng Wen,et al.  Tight Regret Bounds for Stochastic Combinatorial Semi-Bandits , 2014, AISTATS.

[18]  Elad Hazan,et al.  Logarithmic regret algorithms for online convex optimization , 2006, Machine Learning.

[19]  Thomas Stockhammer,et al.  Raptor Forward Error Correction Scheme for Object Delivery , 2007, RFC.

[20]  HazanElad,et al.  Beyond the regret minimization barrier , 2014 .

[21]  Ramesh K. Sitaraman,et al.  Model-based design and analysis of cache hierarchies , 2017, 2017 IFIP Networking Conference (IFIP Networking) and Workshops.

[22]  Urs Niesen,et al.  Coding for caching: fundamental limits and practical challenges , 2016, IEEE Communications Magazine.

[23]  Chuan Wu,et al.  rStream: Resilient and Optimal Peer-to-Peer Streaming with Rateless Codes , 2008, IEEE Transactions on Parallel and Distributed Systems.

[24]  D. Berend,et al.  A sharp estimate of the binomial mean absolute deviation with applications , 2013 .

[25]  H. Robbins A Remark on Stirling’s Formula , 1955 .

[26]  Philip S. Yu,et al.  Caching on the World Wide Web , 1999, IEEE Trans. Knowl. Data Eng..

[27]  Predrag R. Jelenkovic,et al.  Characterizing the miss sequence of the LRU cache , 2008, PERV.

[28]  F. Maxwell Harper,et al.  The MovieLens Datasets: History and Context , 2016, TIIS.

[29]  Martin Raab,et al.  "Balls into Bins" - A Simple and Tight Analysis , 1998, RANDOM.

[30]  Armand M. Makowski,et al.  The output of a cache under the independent reference model: where did the locality of reference go? , 2004, SIGMETRICS '04/Performance '04.

[31]  Sang Lyul Min,et al.  On the existence of a spectrum of policies that subsumes the least recently used (LRU) and least frequently used (LFU) policies , 1999, SIGMETRICS '99.

[32]  Paolo Giaccone,et al.  Unravelling the Impact of Temporal and Geographical Locality in Content Caching Systems , 2015, IEEE Transactions on Multimedia.

[33]  Gaston H. Gonnet,et al.  Expected Length of the Longest Probe Sequence in Hash Code Searching , 1981, JACM.

[34]  Konstantinos Poularakis,et al.  Joint Caching and Routing in Congestible Networks of Arbitrary Topology , 2019, IEEE Internet of Things Journal.

[35]  Noga Alon,et al.  The Probabilistic Method , 2015, Fundamentals of Ramsey Theory.

[36]  Jaime Llorca,et al.  On the fundamental limits of caching in combination networks , 2015, 2015 IEEE 16th International Workshop on Signal Processing Advances in Wireless Communications (SPAWC).

[37]  Jacob Chakareski,et al.  VR/AR Immersive Communication: Caching, Edge Computing, and Transmission Trade-Offs , 2017, VR/AR Network@SIGCOMM.

[38]  Asit Dan,et al.  An approximate analysis of the LRU and FIFO buffer replacement schemes , 1990, SIGMETRICS '90.

[39]  Steve Uhlig,et al.  Open Connect Everywhere: A Glimpse at the Internet Ecosystem through the Lens of the Netflix CDN , 2016, CCRV.

[40]  PedarsaniRamtin,et al.  Online coded caching , 2016 .

[41]  Urs Niesen,et al.  Fundamental Limits of Caching , 2014, IEEE Trans. Inf. Theory.