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The Web and Content Distribution Networks

This topic explores the basics of HTTP, including HTTP review, persistent HTTP, HTTP caching, and content distribution networks. It covers various concepts such as HTTP requests, responses, headers, and status codes. The lecture also discusses the advantages of persistent connections over non-persistent connections.

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The Web and Content Distribution Networks

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  1. The Web and Content Distribution Networks Nick FeamsterCS 6250Fall 2011 (some notes from David Andersen and Christian Kauffman)

  2. Outline • HTTP review • Persistent HTTP review • HTTP caching • Content distribution networks

  3. HTTP Basics • HTTP layered over bidirectional byte stream • Almost always TCP • Interaction • Client sends request to server, followed by response from server to client • Requests/responses are encoded in text • Stateless • Server maintains no information about past client requests

  4. How to Mark End of Message? • Size of message Content-Length • Must know size of transfer in advance • Delimiter  MIME-style Content-Type • Server must “escape” delimiter in content • Close connection • Only server can do this

  5. HTTP Request • Request line • Method • GET – return URI • HEAD – return headers only of GET response • POST – send data to the server (forms, etc.) • URL (relative) • E.g., /index.html • HTTP version

  6. HTTP Request (cont.) • Request headers • Authorization – authentication info • Acceptable document types/encodings • From – user email • If-Modified-Since • Referrer – what caused this page to be requested • User-Agent – client software • Blank-line • Body

  7. HTTP Request (review)

  8. HTTP Request Example GET / HTTP/1.1 Accept: */* Accept-Language: en-us Accept-Encoding: gzip, deflate User-Agent: Mozilla/5.0 Host: www.gtnoise.net Connection: Keep-Alive

  9. HTTP Response • Status-line • HTTP version • 3 digit response code • 1XX – informational • 2XX – success • 200 OK • 3XX – redirection • 301 Moved Permanently • 303 Moved Temporarily • 304 Not Modified • 4XX – client error • 404 Not Found • 5XX – server error • 505 HTTP Version Not Supported • Reason phrase

  10. HTTP Response • Headers • Location – for redirection • Server – server software • WWW-Authenticate – request for authentication • Allow – list of methods supported (get, head, etc) • Content-Encoding – E.g x-gzip • Content-Length • Content-Type • Expires • Last-Modified • Blank-line • Body

  11. HTTP Response Example % curl -D - -o /dev/null http://gtnoise.net HTTP/1.1 200 OK Date: Tue, 25 Oct 2011 13:50:28 GMT Server: Apache/2.2.16 (Debian) X-Powered-By: PHP/5.3.3-7+squeeze1 Set-Cookie: a1c6441c5610e3424571cceee6bfd0ef=q3a5oq1e47ncpkn97mqbo47qm0; path=/ P3P: CP="NOI ADM DEV PSAi COM NAV OUR OTRo STP IND DEM" Set-Cookie: ja_purity_tpl=ja_purity; expires=Sun, 14-Oct-2012 13:50:28 GMT; path=/ Expires: Mon, 1 Jan 2001 00:00:00 GMT Last-Modified: Tue, 25 Oct 2011 13:50:28 GMT Cache-Control: no-store, no-cache, must-revalidate, post-check=0, pre-check=0 Pragma: no-cache Vary: Accept-Encoding Transfer-Encoding: chunked Content-Type: text/html; charset=utf-8

  12. Outline • HTTP intro and details • Persistent HTTP • HTTP caching • Content distribution networks

  13. HTTP 0.9/1.0 • One request/response per TCP connection • Simple to implement • Disadvantages • Multiple connection setups  three-way handshake each time • Several extra round trips added to transfer • Multiple slow starts

  14. Single Transfer Example Client Server 0 RTT SYN Client opens TCP connection SYN 1 RTT ACK DAT Client sends HTTP request for HTML Server reads from disk ACK DAT FIN 2 RTT ACK Client parses HTML Client opens TCP connection FIN ACK SYN SYN 3 RTT ACK Client sends HTTP request for image DAT Server reads from disk ACK 4 RTT DAT Image begins to arrive Lecture 19: 2006-11-02

  15. More Problems • Short transfers are hard on TCP • Stuck in slow start • Loss recovery is poor when windows are small • Lots of extra connections • Increases server state/processing • Server also forced to keep TIME_WAIT connection state -- Things to think about -- • Why must server keep these? • Tends to be an order of magnitude greater than # of active connections, why?

  16. Persistent Connection Solution • Multiplex multiple transfers onto one TCP connection • How to identify requests/responses • Delimiter  Server must examine response for delimiter string • Content-length and delimiter  Must know size of transfer in advance • Block-based transmission  send in multiple length delimited blocks • Store-and-forward  wait for entire response and then use content-length • Solution  use existing methods and close connection otherwise

  17. Persistent Connection Example Client Server 0 RTT DAT Client sends HTTP request for HTML Server reads from disk ACK DAT 1 RTT ACK Client parses HTML Client sends HTTP request for image DAT Server reads from disk ACK DAT 2 RTT Image begins to arrive Lecture 19: 2006-11-02

  18. Persistent HTTP Nonpersistent HTTP issues: • Requires 2 RTTs per object • OS must work and allocate host resources for each TCP connection • But browsers often open parallel TCP connections to fetch referenced objects Persistent HTTP • Server leaves connection open after sending response • Subsequent HTTP messages between same client/server are sent over connection Persistent without pipelining: • Client issues new request only when previous response has been received • One RTT for each referenced object Persistent with pipelining: • Default in HTTP/1.1 • Client sends requests as soon as it encounters a referenced object • As little as one RTT for all the referenced objects

  19. Outline • HTTP intro and details • Persistent HTTP • HTTP caching • Content distribution networks

  20. HTTP Caching • Clients often cache documents • Challenge: update of documents • If-Modified-Since requests to check • HTTP 0.9/1.0 used just date • HTTP 1.1 has an opaque “entity tag” (could be a file signature, etc.) as well • When/how often should the original be checked for changes? • Check every time? • Check each session? Day? Etc? • Use Expires header • If no Expires, often use Last-Modified as estimate

  21. Example Cache Check Request GET / HTTP/1.1 Accept: */* Accept-Language: en-us Accept-Encoding: gzip, deflate If-Modified-Since: Mon, Oct 24 2011 17:54:18 GMT If-None-Match: "7a11f-10ed-3a75ae4a" User-Agent: Mozilla/5.0 (Windows; U; Windows NT 5.1; de; rv:1.9.2.3) Host: www.gtnoise.net Connection: Keep-Alive

  22. Example Cache Check Response HTTP/1.1 304 Not Modified Date: Mon, 24 Oct 2011 03:50:51 GMT Server: Server: Apache/2.2.16 (Debian) Connection: Keep-Alive Keep-Alive: timeout=15, max=100 ETag: "7a11f-10ed-3a75ae4a”

  23. Ways to cache Client-directed caching: Web Proxies Server-directed caching: Content Delivery Networks (CDNs)

  24. Web Proxy Caches • User configures browser: Web accesses via cache • Browser sends all HTTP requests to cache • Object in cache: cache returns object • Else cache requests object from origin server, then returns object to client origin server Proxy server HTTP request HTTP request client HTTP response HTTP response HTTP request HTTP response client origin server

  25. Caching Example (1) Assumptions • Average object size = 100,000 bits • Avg. request rate from institution’s browser to origin servers = 15/sec • Delay from institutional router to any origin server and back to router = 2 sec Consequences • Utilization on LAN = 15% • Utilization on access link = 100% • Total delay = Internet delay + access delay + LAN delay = 2 sec + minutes + milliseconds origin servers public Internet 1.5 Mbps access link institutional network 10 Mbps LAN

  26. Caching Example (2) Install cache • Suppose hit rate is .4 Consequence • 40% requests will be satisfied almost immediately (say 10 msec) • 60% requests satisfied by origin server • Utilization of access link reduced to 60%, resulting in negligible delays • Weighted average of delays = .6*2 sec + .4*10msecs < 1.3 secs origin servers public Internet 1.5 Mbps access link institutional network 10 Mbps LAN institutional cache

  27. Problems • Over 50% of all HTTP objects are uncacheable – why? • Not easily solvable • Dynamic data  stock prices, scores, web cams • CGI scripts  results based on passed parameters • Obvious fixes • SSL  encrypted data is not cacheable • Most web clients don’t handle mixed pages well many generic objects transferred with SSL • Cookies  results may be based on past data • Hit metering  owner wants to measure # of hits for revenue, etc. • What will be the end result?

  28. Outline • HTTP intro and details • Persistent HTTP • HTTP caching • Content distribution networks

  29. Content Distribution Networks (CDNs) • The content providers are the CDN customers. Content replication • CDN company installs hundreds of CDN servers throughout Internet • Close to users • CDN replicates its customers’ content in CDN servers. When provider updates content, CDN updates servers origin server in North America CDN distribution node CDN server in S. America CDN server in Asia CDN server in Europe

  30. Content Distribution Networks & Server Selection • Replicate content on many servers • Challenges • How to replicate content • Where to replicate content • How to find replicated content • How to choose among know replicas • How to direct clients towards replica

  31. Server Selection • Which server? • Lowest load  to balance load on servers • Best performance  to improve client performance • Based on Geography? RTT? Throughput? Load? • Any alive node  to provide fault tolerance • How to direct clients to a particular server? • As part of routing  anycast, cluster load balancing • Not covered • As part of application  HTTP redirect • As part of naming  DNS

  32. Application-Based Content Routing • HTTP supports simple way to indicate that Web page has moved (30X responses) • Server receives GET request from client • Decides which server is best suited for particular client and object • Returns HTTP redirect to that server • Can make informed application specific decision • May introduce additional overhead  multiple connection setup, name lookups, etc. • OK solution in general, but… • HTTP Redirect has some flaws – especially with current browsers • Incurs many delays, which operators may really care about

  33. Naming-Based Content Routing • Client does DNS name lookup for service • Name server chooses appropriate server address • A-record returned is “best” one for the client • What information can name server base decision on? • Server load/location  must be collected • Information in the name lookup request • Name service client  typically the local name server for client

  34. Other Findings • Each CDN performed best for at least one (NIMI) client • Why? Because of proximity? • The best origin sites were better than the worst CDNs • CDNs with more servers don’t necessarily perform better • Note that they don’t know load on servers… • HTTP 1.1 improvements (parallel download, pipelined download) help a lot • Even more so for origin (non-CDN) cases • Note not all origin sites implement pipelining

  35. What is a Content Distribution Network? • A CDN is an overlay network, designed to deliver content from the optimal location • In many cases, optimal does not mean geographically closest • CDNs are made of distinct, geographically disparate groups of servers, with each group able to serve all content on the CDN • Servers may be separated by type • E.g. One group may serve Windows Streaming Media, another group may serve HTTP • Servers are not typically shared between media types

  36. What is a Content Distribution Network • Some CDNs are network-owned (Level 3, Limelight, AT&T), some are not (Akamai, Mirror Image, CacheFly, Panther Express) • Network-owned CDNs have all / most of their servers in their own ASN • Non-network CDNs can place servers directly in other ASNs • This means things like NetFlow will not be useful for determining traffic to/from non-network CDNs

  37. The Akamai EdgePlatform: 85,000+ Servers 1700+ POPs 950+Networks 660+ Cities 72+ Countries The Akamai System • Resulting in traffic of: • 5.4 petabytes / day • 790+ billion hits / day • 436+ million unique clients IPs / day (circa April 2011)

  38. How CDNs Work • When content is requested from a CDN, the user is directed to the optimal server • This is usually done through the DNS, especially for non-network CDNs • It can be done though anycasting for network owned CDNs • Users who query DNS-based CDNs be returned different A records for the same hostname • This is called “mapping” • The better the mapping, the better the CDN

  39. How CDNs Work • Example of CDN mapping • Notice the different A records for different locations: [NYC]% host www.symantec.com www.symantec.com CNAME a568.d.akamai.net a568.d.akamai.net A 207.40.194.46 a568.d.akamai.net A 207.40.194.49 [Boston]% host www.symantec.com www.symantec.com CNAME a568.d.akamai.net a568.d.akamai.net A 81.23.243.152 a568.d.akamai.net A 81.23.243.145

  40. CDN Mapping: Another Example • From Atlanta • % ping youtube.comPING youtube.com (74.125.45.93) 56(84) bytes of data. • 64 bytes from yx-in-f93.1e100.net (74.125.45.93): icmp_req=1 ttl=54 time=1.81 ms • From Boston • % ping youtube.comPING youtube.com (74.125.225.73) 56(84) bytes of data.64 bytes from ord08s07-in-f9.1e100.net (74.125.225.73): icmp_seq=1 ttl=52 time=22.8 ms

  41. How CDNs Work • CDNs use multiple criteria to choose the optimal server • These include standard network metrics: • Latency • Throughput • Packet loss • These also include things like CPU load on the server, HD space, network utilization, etc. • Geography still counts • That whole speed-of-light thing • Should be able to solve that with the next version of ethernet…

  42. Why CDNs Peer with ISPs • The first and foremost reason to peer is improved performance • Since a CDN tries to serve content as “close” to the end user as possible, peering directly with networks (over non-congested links) obviously helps • Peering gives better throughput • Removing intermediate AS hops seems to give higher peak traffic for same demand profile • Might be due to lower latency opening TCP windows faster • Might be due to lower packet loss

  43. Why CDNs Peer with ISPs • Redundancy • Having more possible vectors to deliver content increases reliability • Burstability • During large events, having direct connectivity to multiple networks allows for higher burstability than a single connection to a transit provider • Burstability is important to CDNs • One of the reasons customers use CDNs is for burstability

  44. Why CDNs Peer with ISPs • Peering reduces costs • Reduces transit bill (duh) • Network Intelligence • Receiving BGP directly from multiple ASes helps CDNs map the Internet • Backup for on-net servers • If there are servers on-net, the IX can act as a backup during downtime and overflow • Allows serving different content types

  45. Why ISPs peer with CDNs • Performance • CDNs and ISPs are in the same business, just on different sides - we both want to serve end users as quickly and reliably as possible • You know more about your network than any CDN ever will, so working with the CDN directly can help them deliver the content more quickly and reliably • Cost Reduction • Transit savings • Possible backbone savings

  46. How Non-Network CDNs use IXes Peer Network • Non-network CDNs do not have a backbone, so each IX instance is independent • The CDN uses transit to pull content into the servers • Content is then served to peers over the IX IX Content CDN Servers Transit Origin Server

  47. How CDNs use IXes • Non-network CDNs usually do not announce large blocks of address space because no one location has a large number of servers • It is not uncommon to see a single /24 from a CDN at an IX • This does not mean you will not see a lot of traffic • How many web servers does it take to fill a gigabit these days?

  48. How well do CDNs work? Hosting Center Hosting Center OS Backbone ISP Backbone ISP Backbone ISP CS CS CS IX IX Site ISP CS ISP ISP CS S S S Sites S S S S S C C C

  49. Reduced latency can improve TCP performance • DNS round trip • TCP handshake (2 round trips) • Slow-start • ~8 round trips to fill DSL pipe • total 128K bytes • Compare to 56 Kbytes for cnn.com home page • Download finished before slow-start completes • Total 11 round trips • Coast-to-coast propagation delay is about 15 ms • Measured RTT last night was 50ms • No difference between west coast and Cornell! • 30 ms improvement in RTT means 330 ms total improvement • Certainly noticeable

  50. Lets look at a study • Zhang, Krishnamurthy and Wills • AT&T Labs • Traces taken in Sept. 2000 and Jan. 2001 • Compared CDNs with each other • Compared CDNs against non-CDN

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