1. PlanetLab: A Platform for Planetary-Scale Services Mic Bowman (mic.bowman@intel.com)

2. Agenda What Is PlanetLab? Planetary-Scale Services –Evolving the Internet Why PlanetLab?

3. PlanetLab Is… Technology: –An open, global network test-bed for inventing novel planetary-scale services. –A model for introducing innovations into the Internet through the use of overlay networks. Organization: –A collaborative effort involving academic and corporate researchers from around the world –Hosted by Princeton, Washington, Berkeley, and MIT; sponsored by Intel, HP, and Google Socially –Cutting edge research infrastructure made available to the global community

4. PlanetLab Is… IA32 servers (836  1000’s) connected to the Internet at 412 sites Federated with PlanetLab Europe Mostly standard Linux distribution and dev environment A few global services

5. Other brands and names are the property of their respective owners. Academic Partipants

6. Other brands and names are the property of their respective owners. Industry Participants

7. Agenda What Is PlanetLab? Planetary-Scale Services –Evolving the Internet Architecture Why PlanetLab?

8. Content Distribution, 1993 NCSA’s “What’s New” the most viewed page on the web (100K accesses per month). All clients access a single copy of the page stored on a single server. End-to-End design works pretty well for store-and-forward applications

9. Content Distribution, 1998 IBM web “server” handles a record 100K hits per minute at the Nagano Olympics DFS running on SP2’s used to distribute 70K pages to 9 geographically distributed locations End-to-End design breaks down at scale (flash crowds, global distribution, …)

10. Content Distribution Today A Planetary-Scale Service Edge services provide 1000’s of points of presence throughout the Internet Overlay networks are constructed to move the content around efficiently The transition from “end-to-end” to “overlay” enables reliable planetary-scale services

11. Planetary-Scale Services Pervasive –Runs everywhere, all the time Robust –Robust system from flaky components Adaptive –Aware of and adapts to changing environment Scalable –Scales to a global workload

12. To Build One, You Need… Multiple vantage points on the network –Near the edge—low latency to clients –Near the core—good connectivity –Global presence A little computation at many locations –Computation beyond a single machine –Computation beyond a single organization Management services appropriate to the task –Resource allocation –Provisioning and configuration –Monitoring nodes, services, networks But who can afford it? –No single app can justify the infrastructure costs –Network today is like big-iron before timeshare

13. Solution: Share the Platform Everyone contributes a piece of the platform; everyone can use the whole platform –Build a “time-sharing” network-service platform –Cost shared among all the apps using it Model of future public computing utility –Nodes owned by many organizations –Shared cooperatively to provide resilience Platform must provide –Isolation to protect services from one another –Market-based resource allocation

14. PlanetLab Service Architecture Node 1 Node 2 Node 3 Node 5 Node 4 Mgmt. VM Hardware VMM Service Virtual Machines

15. PlanetLab Services are Running EventProcessingNetworkMappingDistributed Hash Tables ContentDistribution Web Casting Infrastructure Services & End-user Services Node 1 Node 2 Node 3 Node 5 Node 4

16. Resource Reservations CPU resources can be scarce during certain periods (before paper deadlines) The Sirius Resource Calendar Service allows PlanetLab users to schedule an increase a slice’s CPU priority for certain time periods –Only CPU and not work Seems to work well: –Rarely 50% subscribed –Services often deal with CPU loading themselves

17. PlanetLab Today… 836 IA32 machines at 412 sites –Principally universities, some enterprise –Research networks: I2, CANet/4, RNP, CERNet –Globally distributed –Some co-location centers –Federated with PlanetLab Europe Machines virtualized at syscall level –Name space isolation for security –Network, CPU, memory, file system isolation –Interface is a Linux machine with minimal install Complete access to the network

18. What We Got Right Immediate impact –Within 18 months 25% of publications at top OS & Comm conferences were PlanetLab experiments –Became a “expectation” for validation of large system results –And we learned some very interesting things

19. What We Got Right (continued) Incident response –Early: very conservative Don’t get turned off before value is established –Later: less restrictions Local administrators defend their researchers –Education Researchers: the kind of experiment that causes alarms Administrators: touchy IDS implementations

20. We Could Have Done Better Community contributions to the infrastructure –Infrastructure development remained centralized, we are paying the price now Support for long-running services –Researchers aren’t motivated to keep services running for multiple years –Decreased the amount of service composition (can’t trust the dependent services will continue to run)

21. We Could Have Done Better (continued) Admission control –Good practices make it possible to run many experiments, but very easy to consume all resources

22. Open Challenges Community ownership of availability –Need to motivate decentralized management Who keeps the nodes running? What happens when the nodes aren’t running? Resource allocation aligned objectives –Performance, innovation, stability

23. Open Challenges (continued) Standardization –Standard interfaces  platform stability –Open architecture  improved innovation Tech Transfer

24. Agenda What Is PlanetLab? Planetary-Scale Services –Evolving the Internet Architecture Why PlanetLab?

25. PlanetLab and Industry Global communications company –Incubator for future Internet infrastructure –Emerging services become a part of the Internet Global computer vendor –Platform for planetary-scale services –Need to understand for our customers Software company –Testbed for next generation applications –Cost-effective way to test new ideas Fortune 500 company –Next generation opportunities for IT staff –Leverage deployed PlanetLab services for CDN, object location, network health…

26. Summary PlanetLab is: –A globally distributed testbed that facilitates experimentation and deployment of scalable Internet services. The testbed has successfully established itself as a platform for cutting edge research. –Active research community using it for a wide variety of technologies. –Multiple papers published top academic conferences, e.g. OSDI, SOSP, NSDI, Sigcomm, … –300+ active projects Come join the fun (www.planet-lab.org)

27. BACKUP

28. Princeton: CoDeeN Content distribution –Partial replication of content –Redirect requests to optimal location of content PlanetLab Deployment –100 nodes, 150+ GB of data moved among the sites –Working to build service redirector Key Learnings –First service targeted for end users (proxy cache) –Maintaining server health is hard and unpredictable BBB B B B B A A A A AA C C C C CCC

29. UWashington: Scriptroute Distributed Internet debugging and measurement –Distribute measurement points throughout the network –Allow user to connect & make a measurement (upload scripts) PlanetLab Deployment –Running on about 100 nodes –Basic service used by other services Observations –Experiments look like port scan attacks –Low BW traffic to lots of addrs breaks some routers –Scriptroute adjusted spray of packets to avoid the problem

30. Cornell: Beehive DHT for object location –High performance –Self-organizing –Scalable Proactive-replication –Hash buckets replicated –O(1) lookup times for queries CoDoNs: DNS replacement –High performance P2P –Adaptive, load balancing –Cache coherent

31. Usage Stats Slices: 600+ Users: 2500+ Bytes-per-day: 4 TB IP-flows-per-day: 190M Unique IP-addrs-per-day: 1M (source: Larry Peterson, May 2007)