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diff --git a/doc/rfc/rfc5632.txt b/doc/rfc/rfc5632.txt new file mode 100644 index 0000000..1834d0c --- /dev/null +++ b/doc/rfc/rfc5632.txt @@ -0,0 +1,675 @@ + + + + + + +Network Working Group C. Griffiths +Request for Comments: 5632 J. Livingood +Category: Informational Comcast + L. Popkin + Pando + R. Woundy + Comcast + Y. Yang + Yale + September 2009 + + +Comcast's ISP Experiences in a Proactive Network Provider Participation + for P2P (P4P) Technical Trial + +Abstract + + This document describes the experiences of Comcast, a large cable + broadband Internet Service Provider (ISP) in the U.S., in a Proactive + Network Provider Participation for P2P (P4P) technical trial in July + 2008. This trial used P4P iTracker technology, which is being + considered by the IETF as part of the Application Layer Transport + Optimization (ALTO) working group. + +Status of This Memo + + This memo provides information for the Internet community. It does + not specify an Internet standard of any kind. Distribution of this + memo is unlimited. + +Copyright Notice + + Copyright (c) 2009 IETF Trust and the persons identified as the + document authors. All rights reserved. + + This document is subject to BCP 78 and the IETF Trust's Legal + Provisions Relating to IETF Documents in effect on the date of + publication of this document (http://trustee.ietf.org/license-info). + Please review these documents carefully, as they describe your rights + and restrictions with respect to this document. + + + + + + + + + + + +Griffiths, et al. Informational [Page 1] + +RFC 5632 Comcast P4P Experiences September 2009 + + +Table of Contents + + 1. Introduction . . . . . . . . . . . . . . . . . . . . . . . . . 2 + 2. High-Level Details . . . . . . . . . . . . . . . . . . . . . . 3 + 3. Differences between the P4P iTrackers Used . . . . . . . . . . 4 + 3.1. P4P Fine Grain . . . . . . . . . . . . . . . . . . . . . . 4 + 3.2. P4P Coarse Grain . . . . . . . . . . . . . . . . . . . . . 5 + 3.3. P4P Generic Weighted . . . . . . . . . . . . . . . . . . . 5 + 4. High-Level Trial Results . . . . . . . . . . . . . . . . . . . 5 + 4.1. Swarm Size . . . . . . . . . . . . . . . . . . . . . . . . 6 + 4.2. Impact on Download Speed . . . . . . . . . . . . . . . . . 7 + 4.3. General Impacts on Upstream and Downstream Traffic and + Other Interesting Data . . . . . . . . . . . . . . . . . . 7 + 5. Important Notes on Data Collected . . . . . . . . . . . . . . 8 + 6. Next Steps . . . . . . . . . . . . . . . . . . . . . . . . . . 9 + 7. Security Considerations . . . . . . . . . . . . . . . . . . . 10 + 8. Acknowledgements . . . . . . . . . . . . . . . . . . . . . . . 10 + 9. Informative References . . . . . . . . . . . . . . . . . . . . 10 + +1. Introduction + + Comcast is a large broadband Internet Service Provider (ISP), based + in the U.S., serving the majority of its customers via cable modem + technology. A trial was conducted in July 2008 with Pando Networks, + Yale, and several ISP members of the P4P working group, which is part + of the Distributed Computing Industry Association (DCIA). Comcast is + a member of the DCIA's P4P Working Group, whose mission is to work + with Internet Service Providers (ISPs), peer-to-peer (P2P) companies, + and technology researchers to develop "P4P" mechanisms, such as so- + called "iTrackers" (hereafter P4P iTrackers), that accelerate + distribution of content and optimize utilization of ISP network + resources. P4P iTrackers theoretically allow P2P networks to + optimize traffic within each ISP, reducing the volume of data + traversing the ISP's infrastructure and creating a more manageable + flow of data. P4P iTrackers can also accelerate P2P downloads for + end users. + + P4P's iTracker technology [SIGCOMM] was conceptually discussed with + the IETF at the Peer-to-Peer Infrastructure (P2Pi) Workshop held on + May 28, 2008, at the Massachusetts Institute of Technology (MIT), as + documented in [RFC5594]. This work was discussed in greater detail + at the 72nd meeting of the IETF, in Dublin, Ireland, in the ALTO BoF + (Birds of a Feather meeting) on July 29, 2008. Due to interest from + the community, Comcast shared P4P iTracker trial data at the 73rd + meeting of the IETF, in Minneapolis, Minnesota, in the ALTO BoF on + November 18, 2008. Since that time, discussion of P4P iTrackers and + alternative technologies has continued among participants of the ALTO + working group. + + + +Griffiths, et al. Informational [Page 2] + +RFC 5632 Comcast P4P Experiences September 2009 + + + The P4P iTracker trial was conducted, in cooperation with Pando, + Yale, and three other P4P member ISPs, from July 2 to July 17, 2008. + This was the first P4P iTracker trial over a cable broadband network. + The trial used a Pando P2P client, and Pando distributed a special + 21-MB licensed video file in order to measure the effectiveness of + P4P iTrackers. A primary objective of the trial was to measure the + effects that increasing the localization of P2P swarms would have on + P2P uploads, P2P downloads, and ISP networks, in comparison to normal + P2P activity. + +2. High-Level Details + + As noted in Section 1 of [DynamicSwarmMgmt], a swarm is defined in + the following way: + + The content and the set of peers distributing it [a file] is + usually called a torrent. A peer that only uploads content is + called a seed, while a peer that uploads and downloads at the same + time is called a leecher. The connected set of peers + participating in the piece exchanges of a torrent is referred to + as a swarm. + + There were five different swarms for the content used in the trial. + The second, third, and fourth used different P4P iTrackers: Generic, + Coarse Grained, and Fine Grained, all of which are described in + Section 3. The fifth was a proprietary Pando mechanism. (The + results of the fifth swarm, while satisfactory, are not included here + since our focus is on open standards and a mechanism that may be + leveraged for the benefit of the entire community of P2P clients.) + Comcast deployed a P4P iTracker server in its production network to + support this trial, and configured multiple iTracker files to provide + varying levels of localization to clients. + + In the trial itself, a P2P client begins a P2P session by querying a + pTracker, which runs and manages the P2P network. The pTracker + occasionally queries the P4P iTracker, which in this case was + maintained by Comcast, the ISP. Other ISPs either managed their own + P4P iTracker or used Pando or Yale to host their P4P iTracker files. + The P4P iTracker returns network topology information to the + pTracker, which then communicates with P2P clients, in order to + enable P2P clients to make network-aware decisions regarding peers. + + The Pando client was enabled to capture extended logging, when the + version of the client included support for it. The extended logging + included the source and destination IP address of all P2P transfers, + the number of bytes transferred, and the start and end timestamps. + This information gives a precise measurement of the data flow in the + network, allowing computation of data transfer volumes as well as + + + +Griffiths, et al. Informational [Page 3] + +RFC 5632 Comcast P4P Experiences September 2009 + + + data flow rates at each point in time. With standard logging, Pando + captured the start and completion times of every download, as well as + the average transfer rate observed by the client for the download. + + Pando served the data from an origin server external to Comcast's + network. This server served about 10 copies of the file, after which + all transfers (about 1 million downloads across all ISPs) were + performed purely via P2P. + + The P2P clients in the trial start with tracker-provided peers, then + use peer exchange to discover additional peers. Thus, the initial + peers were provided according to P4P iTracker guidance (90% guidance + based on P4P iTracker topology and 10% random guidance), then later + peers discover the entire swarm via either additional announces or + peer exchange. + +3. Differences between the P4P iTrackers Used + + Given the size of the Comcast network, it was felt that in order to + truly evaluate the P4P iTracker application we would need to test + various network topologies that reflected its network and would help + gauge the level of effort and design requirements necessary to get + correct statistical data out of the trial. In all cases, P4P + iTrackers were configured with automation in mind, so that any + successful P4P iTracker configuration would be automatically + updating, rather than manually configured on an ongoing basis. All + P4P iTrackers were hosted on the same small server, and it appeared + to be relatively easy and inexpensive to scale up a P4P iTracker + infrastructure should P4P iTracker-like mechanisms become + standardized and widely adopted. + +3.1. P4P Fine Grain + + The Fine Grain topology was the first and most complex P4P iTracker + that we built for this trial. It was a detailed mapping of Comcast + backbone-connected network Autonomous System Numbers (ASNs) to IP + Aggregates, which were weighted based on priority and distance from + each other. Included in this design was a prioritization of all Peer + and Internet transit connected ASNs to the Comcast backbone to ensure + that P4P traffic would prefer settlement-free and lower-cost networks + first, and then more expensive transit links. This attempted to + optimize and lower transit costs associated with this traffic. We + then took the additional step of detailing each ASN and IP Aggregate + into IP subnets down to Optical Transport Nodes (OTNs) where all + Cable Modem Termination Systems (CMTS, as briefly defined in Section + 2.6 of [RFC3083]) reside . This design gave a highly localized and + detailed description of the Comcast network for the iTracker to + disseminate. This design defined 1,182 P4P iTracker node + + + +Griffiths, et al. Informational [Page 4] + +RFC 5632 Comcast P4P Experiences September 2009 + + + identifiers, and resulted in a 107,357-line configuration file. + + This P4P iTracker was obviously the most time-consuming to create and + the most complex to maintain. Trial results indicated that this + level of localization was too high, and was less effective compared + to lower levels of localization. + +3.2. P4P Coarse Grain + + Given the level of detail in the Fine Grain design, it was important + that we also enable a high-level design, which still used priority + and weighting mechanisms for the Comcast backbone and transit links. + The Coarse Grain design was a limited or summarized version of the + Fine Grain design, which used the ASN to IP Aggregate and weighted + data for transit links, but removed all additional localization data. + This ensured we would get similar data sets from the Fine Grain + design, but without the more detailed localization of each of the + networks attached to the Comcast backbone. This design defined 22 + P4P iTracker node identifiers, and resulted in a 998-line + configuration file. + + From an overall cost, complexity, risk, and effectiveness standpoint, + this was judged to be the optimal P4P iTracker for Comcast. + Importantly, this did not require revealing the complex, internal + network topology that the Fine Grain did. Updates to this iTracker + were also far simpler to automate, which will better ensure that it + is accurate over time, and keeps administrative overhead relatively + low. However, the differences, costs, and benefits of Coarse Grain + and Generic Weighted (see below) likely merit further study. + +3.3. P4P Generic Weighted + + The Generic Weighted design was a copy of the Coarse Grained design, + but instead of using ISP-designated priority and weights, all weights + were defaulted to pre-determined parameters that the Yale team had + designed. All other data was replicated from the Coarse Grain + design. Gathering and providing the information necessary to support + the Generic Weighted iTracker was roughly the same level of effort as + for Coarse Grain. + +4. High-Level Trial Results + + Trial data was collected by Pando Networks and Yale University, and + raw trial results were shared with Comcast and all of the other ISPs + involved in the trial. Analysis of the raw results was performed by + Pando and Yale, and these organizations delivered an analysis of the + P4P iTracker trial. Using the raw data, Comcast also analyzed the + trial results. Furthermore, the raw trial results for Comcast were + + + +Griffiths, et al. Informational [Page 5] + +RFC 5632 Comcast P4P Experiences September 2009 + + + shared with Net Forecast, Inc., which performed an independent + analysis of the trial for Comcast. + +4.1. Swarm Size + + During the trial, downloads peaked at 24,728 per day, per swarm, or + nearly 124,000 per day for all five swarms. The swarm size peaked at + 11,703 peers per swarm, or nearly 57,000 peers for all five swarms. + We observed a comparable number of downloads in each of the five + swarms. + + For each swarm, Table 1 below gives the number of downloads per swarm + from Comcast that finished downloading, and the number of downloads + from Comcast that canceled downloading before finishing. + + Characteristics of P4P iTracker Swarms: + + +-----------+-----------+---------------+------------+--------------+ + | Swarm | Completed | Cancellations | Total | Cancellation | + | | Downloads | | Attempts | Rate | + +-----------+-----------+---------------+------------+--------------+ + | Random | 2,719 | 89 | 2,808 | 3.17% | + | (Control) | | | | | + | --------- | --------- | ----------- | ---------- | ----------- | + | P4P Fine | 2,846 | 64 | 2,910 | 2.20% | + | Grained | | | | | + | --------- | --------- | ----------- | ---------- | ----------- | + | P4P | 2,775 | 63 | 2,838 | 2.22% | + | Generic | | | | | + | Weight | | | | | + | --------- | --------- | ----------- | ---------- | ----------- | + | P4P | 2,886 | 52 | 2,938 | 1.77% | + | Coarse | | | | | + | Grained | | | | | + +-----------+-----------+---------------+------------+--------------+ + + Table 1: Per-Swarm Size and Cancellation Rates + + + + + + + + + + + + + + +Griffiths, et al. Informational [Page 6] + +RFC 5632 Comcast P4P Experiences September 2009 + + +4.2. Impact on Download Speed + + The results of the trial indicated that P4P iTrackers can improve the + speed of downloads to P2P clients. In addition, P4P iTrackers were + effective in localizing P2P traffic within the Comcast network. + + Impact of P4P iTrackers on Downloads: + + +--------------+------------+------------+-------------+------------+ + | Swarm | Global Avg | Change | Comcast Avg | Change | + | | bps | | bps | | + +--------------+------------+------------+-------------+------------+ + | Random | 144,045 | n/a | 254,671 bps | n/a | + | (Control) | bps | | | | + | ---------- | ---------- | ---------- | ---------- | ---------- | + | P4P Fine | 162,344 | +13% | 402,043 bps | +57% | + | Grained | bps | | | | + | ---------- | ---------- | ---------- | ---------- | ---------- | + | P4P Generic | 163,205 | +13% | 463,782 bps | +82% | + | Weight | bps | | | | + | ---------- | ---------- | ---------- | ---------- | ---------- | + | P4P Coarse | 166,273 | +15% | 471,218 bps | +85% | + | Grained | bps | | | | + +--------------+------------+------------+-------------+------------+ + + Table 2: Per-Swarm Global and Comcast Download Speeds + +4.3. General Impacts on Upstream and Downstream Traffic and Other + Interesting Data + + An analysis of the effects of P4P iTracker use on upstream + utilization and Internet transit was also interesting. It did not + appear that P4P iTrackers significantly increased upstream + utilization in the Comcast access network; in essence, uploading was + already occurring no matter what and a P4P iTracker in and of itself + did not appear to materially increase uploading for this specific, + licensed content. (A P4P iTracker is not intended as a solution for + the potential of network congestion to occur.) Random was 143,236 MB + and P4P Generic Weight was 143,143 MB, while P4P Coarse Grained was + 139,669 MB. We also observed that using a P4P iTracker reduced + outgoing Internet traffic by an average of 34% at peering points. + Random was 134,219 MB and P4P Generic Weight was 91,979 MB, while P4P + Coarse Grained was 86,652 MB. + + In terms of downstream utilization, we observed that the use of a P4P + iTracker reduced incoming Internet traffic by an average of 80% at + peering points. Random was 47,013 MB, P4P Generic Weight was 8,610 + MB, and P4P Coarse Grained was 7,764 MB. However, we did notice that + + + +Griffiths, et al. Informational [Page 7] + +RFC 5632 Comcast P4P Experiences September 2009 + + + download activity in the Comcast access network increased somewhat, + from 56,030 MB for Random, to 59,765 MB for P4P Generic Weight, and + 60,781 MB for P4P Coarse Grained. Note that for each swarm, the + number of downloaded bytes according to logging reports is very close + to the number of downloads multiplied by file size. But they do not + exactly match due to log report errors and duplicated chunks. One + factor contributing to the differences in access network download + activity is that different swarms have different numbers of + downloaders, due to random variations during uniform random + assignment of downloaders to swarms (see Table 1). One interesting + observation is that Random has higher cancellation rate (3.17%) than + that of the guided swarms (1.77%-2.22%). Whether guided swarms + achieve lower cancellation rate is an interesting issue for future + research. + +5. Important Notes on Data Collected + + Raw data is presented in this document. We did not normalize traffic + volume data (e.g., upload and download) by the number of downloads in + order to preserve this underlying raw data. + + We also recommend that readers not focus too much on the absolute + numbers, such as bytes downloaded from internal sources and bytes + downloaded from external sources. Instead, we recommend readers + focus on ratios such as the percentage of bytes downloaded that came + from internal sources in each swarm. As a result, the small random + variation between number of downloads of each swarm does not distract + readers from important metrics like shifting traffic from external to + internal sources, among other things. + + We also wish to note that the data was collected from a sample of the + total swarm. Specifically, there were some peers running older + versions of the Pando client that did not implement the extended + transfer logging. For those nodes, which participated in the swarms + but did not report their data transfers, we have download counts. + The result of this is that, for example, the download counts + generated from the standard logging are a bit higher than the + download counts generated by the extended logging. That being said, + over 90% of downloads were by peers running the newer software, which + we believe shows that the transfer records are highly representative + of the total data flow. + + In terms of which analysis was performed from the standard logging + compared to extended logging, all of the data flow analysis was + performed using the extended logging. Pando's download counts and + performance numbers were generated via standard logging (i.e., all + peers report download complete/cancel, data volumes, and measured + download speed on the client). Yale's download counts and + + + +Griffiths, et al. Informational [Page 8] + +RFC 5632 Comcast P4P Experiences September 2009 + + + performance numbers were derived via extended logging (e.g., by + summing the transfer records, counting IP addresses reported, etc.). + + One benefit of having two data sources is that we can compare the + two. In this case, the two approaches both reported comparable + impacts. + +6. Next Steps + + One objective of this document is to share with the IETF community + the results of one P4P iTracker trial in a large broadband network, + given skepticism regarding the benefits to P2P users as well as to + ISPs. From the perspective of P2P users, P4P iTrackers potentially + deliver faster P2P downloads. At the same time, ISPs can increase + the localization of swarms, enabling them to reduce bytes flowing + over transit points, while also delivering an optimized P2P + experience to customers. However, an internal analysis of varying + levels of P4P iTracker adoption by ISPs leads us to believe that, + while P4P iTracker-type mechanisms are valuable on a single ISP + basis, the value of P4P iTrackers increases dramatically as many ISPs + choose to deploy it. + + We believe these results can inform the technical discussion in the + IETF over how to use P4P iTracker mechanisms. Should such a + mechanism be standardized, the use of ISP-provided P4P iTrackers + should probably be an opt-in feature for P2P users, or at least a + feature of which they are explicitly aware of and which has been + enabled by default in a particular P2P client. In this way, P2P + users could choose to opt-in either explicitly or by their choice of + P2P client in order to choose to use the P4P iTracker to improve + performance, which benefits both the user and the ISP at the same + time. Importantly in terms of privacy, the P4P iTracker makes + available only network topology information, and would not in its + current form enable an ISP, via the P4P iTracker, to determine which + P2P clients were downloading any specific content, whether to + determine, for example, if content was a song or a movie or even the + title. + + It is also possible that a P4P iTracker type of mechanism, in + combination with a P2P cache, could further improve P2P download + performance, which merits further study. In addition, this was a + limited trial that, while very promising, indicates a need for + additional technical investigation and trial work. Such a follow-up + study should explore the effects of P4P iTrackers when more P2P + client software variants are involved, with larger swarms, and with + additional and more technically diverse content (file size, file + type, duration of content, etc.). + + + + +Griffiths, et al. Informational [Page 9] + +RFC 5632 Comcast P4P Experiences September 2009 + + +7. Security Considerations + + This document does not propose any kind of protocol, practice or + standard. + + The experiment did show that an ISP can improve performance without + exposing fine-grained details about network structure, which might + otherwise be a security concern (see Section 3.1 (P4P Fine Grain) and + Section 3.2 (P4P Coarse Grain). Section 6 (Next Steps) mentions that + the opt-in architecture allows P2P users to maintain privacy. + + Other security aspects were not considered in the experiment, which + focused on performance measurements. + +8. Acknowledgements + + The authors wish to acknowledge the hard work of all of the P4P + working group members, and specifically the focused efforts of the + teams at both Pando and Yale for the trial itself. Finally, the + authors recognize and appreciate Peter Sevcik and John Bartlett of + NetForecast, Inc., for their valued independent analysis of the trial + results. + +9. Informative References + + [DynamicSwarmMgmt] + Carlsson, N. and G. Dan, "Dynamic Swarm Management for + Improved BitTorrent Performance", USENIX 8th International + Workshop on Peer-to-Peer Systems, March 2009, + <http://www.usenix.org/events/iptps09/tech/full_papers/ + dan/dan_html/>. + + [RFC3083] Woundy, R., "Baseline Privacy Interface Management + Information Base for DOCSIS Compliant Cable Modems and + Cable Modem Termination Systems", RFC 3083, March 2001. + + [RFC5594] Peterson, J. and A. Cooper, "Report from the IETF Workshop + on Peer-to-Peer (P2P) Infrastructure, May 28, 2008", + RFC 5594, July 2009. + + [SIGCOMM] Xie, H., Yang, Y., Krishnamurthy, A., Liu, Y., and A. + Silberschatz, "ACM SIGCOMM 2008 - P4P: Provider Portal for + Applications", Association for Computing Machinery SIGCOMM + 2008 Proceedings, August 2008, + <http://ccr.sigcomm.org/online/files/p351-xieA.pdf>. + + + + + + +Griffiths, et al. Informational [Page 10] + +RFC 5632 Comcast P4P Experiences September 2009 + + +Authors' Addresses + + Chris Griffiths + Comcast Cable Communications + One Comcast Center + 1701 John F. Kennedy Boulevard + Philadelphia, PA 19103 + US + + EMail: chris_griffiths@cable.comcast.com + URI: http://www.comcast.com + + + Jason Livingood + Comcast Cable Communications + One Comcast Center + 1701 John F. Kennedy Boulevard + Philadelphia, PA 19103 + US + + EMail: jason_livingood@cable.comcast.com + URI: http://www.comcast.com + + + Laird Popkin + Pando Networks + 520 Broadway Street + 10th Floor + New York, NY 10012 + US + + EMail: laird@pando.com + URI: http://www.pando.com + + + Richard Woundy + Comcast Cable Communications + 27 Industrial Avenue + Chelmsford, MA 01824 + US + + EMail: richard_woundy@cable.comcast.com + URI: http://www.comcast.com + + + + + + + + +Griffiths, et al. Informational [Page 11] + +RFC 5632 Comcast P4P Experiences September 2009 + + + Richard Yang + Yale University + 51 Prospect Street + New Haven, CT 06520 + US + + EMail: yry@cs.yale.edu + URI: http://www.cs.yale.edu + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + +Griffiths, et al. Informational [Page 12] + |