Deep Dive into NTP Pool's Popularity and Mapping

Author:

Moura Giovane C. M.1ORCID,Davids Marco2ORCID,Schutijser Caspar2ORCID,Hesselman Cristian3ORCID,Heidemann John4ORCID,Smaragdakis Georgios5ORCID

Affiliation:

1. SIDN Labs and Delft University of Technology, Arnhem and Delft, Netherlands

2. SIDN Labs, Arnhem, Netherlands

3. SIDN Labs and University of Twente, Arnhem and Enschede, Netherlands

4. USC/ISI and CS Dept, Los Angeles, California, USA

5. Delft University of Technology, Delft, Netherlands

Abstract

Time synchronization is of paramount importance on the Internet, with the Network Time Protocol (NTP) serving as the primary synchronization protocol. The NTP Pool, a volunteer-driven initiative launched two decades ago, facilitates connections between clients and NTP servers. Our analysis of root DNS queries reveals that the NTP Pool has consistently been the most popular time service. We further investigate the DNS component (GeoDNS) of the NTP Pool, which is responsible for mapping clients to servers. Our findings indicate that the current algorithm is heavily skewed, leading to the emergence of time monopolies for entire countries. For instance, clients in the US are served by 551 NTP servers, while clients in Cameroon and Nigeria are served by only one and two servers, respectively, out of the 4k+ servers available in the NTP Pool. We examine the underlying assumption behind GeoDNS for these mappings and discover that time servers located far away can still provide accurate clock time information to clients. We have shared our findings with the NTP Pool operators, who acknowledge them and plan to revise their algorithm to enhance security.

Funder

NSF

Horizon 2020 Framework Programme

European Research Council

NWO

Publisher

Association for Computing Machinery (ACM)

Reference17 articles.

1. Ask Bjørn Hansen. 2021. GeoDNS servers. https://github.com/abh/geodns/.

2. Physikalisch Technische Bundesanstalt. 2022. FDCF77 - PTB.de. (Nov. 5 2022). https://www.ptb.de/cms/en/ptb/fachabteilungen/abt4/fb-44/ag-442/dissemination-of-legal-time/dcf77.html

3. Omer Deutsch, Neta Rozen Schiff, Danny Dolev, and Michael Schapira. 2018. Preventing (Network) Time Travel with Chronos.. In NDSS.

4. Ralph Droms. 1997. Dynamic Host Configuration Protocol. RFC 2131. IETF. http://tools.ietf.org/rfc/rfc2131.txt

5. Nate Hopper. 2022. The Thorny Problem of Keeping the Internet's Time. The New Yorker (Sept. 30 2022). https://www.newyorker.com/tech/annals-of-technology/the-thorny-problem-of-keeping-the-internets-time

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