1 / 27

Plutarch: An Argument for Network Pluralism

Plutarch: An Argument for Network Pluralism. Andrew Warfield. Jon Crowcroft, Steven Hand, and Andrew Warfield University of Cambridge Richard Mortier Microsoft Research Cambridge Timothy Roscoe Intel Research Berkeley. Why a new architecture?. “Architecture” papers need good motivation…

Download Presentation

Plutarch: An Argument for Network Pluralism

An Image/Link below is provided (as is) to download presentation Download Policy: Content on the Website is provided to you AS IS for your information and personal use and may not be sold / licensed / shared on other websites without getting consent from its author. Content is provided to you AS IS for your information and personal use only. Download presentation by click this link. While downloading, if for some reason you are not able to download a presentation, the publisher may have deleted the file from their server. During download, if you can't get a presentation, the file might be deleted by the publisher.

E N D

Presentation Transcript


  1. Plutarch: An Argumentfor Network Pluralism Andrew Warfield andrew.warfield@cl.cam.ac.uk Jon Crowcroft, Steven Hand, and Andrew WarfieldUniversity of CambridgeRichard MortierMicrosoft Research CambridgeTimothy RoscoeIntel Research Berkeley

  2. Why a new architecture? • “Architecture” papers need good motivation… • Three major reasons: • Things IP is bad at. (Deficiencies) • Mobility, multicast, route convergence, non-endpoint-based addressing, novel link layers, service differentiation, management, accounting, etc. • The apocalypse. (Scale issues) • Insufficient Address space, routing collapse, DoS/ Worms • Freedom to innovate. (Boredom) • Commodification of IP stifles innovation • Either do incremental polishing or do overlay nets.

  3. IP Philosophy “The top level goal for the DARPA Internet Architecture was to develop an effective technique for multiplexed utilization of existing interconnected networks.” - D. Clark, “The Design Philosophy of the DARPA Internet Protocols”

  4. IP Design Philosophy • IP enabled internetworking by homogenising the network and transport layers • A uniform general-purpose set of protocols • By standardizing the middle, layers above and below were free to evolve. • Clearly, IP was correct! • Hard to imagine faster growth…

  5. Looking forward • IP has been very successful, but… • Is it likely to be the eternal Internet protocol? • Can we realistically expect v6, or any other potential replacement to be more successful? • Most importantly: What is really achieved in deploying an incrementally more scalable protocol? • If you think v6 has deployment problems, wait till v8!

  6. Alternate approaches • Two things seem important: • Less homogeneity. • An end-to-end issue, IP is an interface and it can’t anticipate everything. • Focus outside the scope of the IPv4 Internet. • Address transition. • Allow specialized networks • Do not presume to have a drop-in replacement

  7. Our Position: An Inter-networking architecture must allow communications between dissimilar networks withoutmandating a standardised data path.

  8. Plutarch • Aim to provide a minimal control plane to allow dissimilar networks to arrange communications. • An extensible Inter-network. • Two fundamental concepts: Contexts and Interstitial Functions. • Develop a management/control service to address naming and connections at an inter-network granularity.

  9. Not completely new… “We call a network which builds coherent user level semantics from a regionalized infrastructure and qualitatively heterogeneous communication technologies a Metanet.”– Wroclawski, Metanet Whitepaper (1997) “In particular [the Yellow Book] aims to provide endpoint communication across multiple independent networks.”– Bennett, INDRA Note 967 (1980)

  10. Core Network Dissimilarities • Naming • Google, not DNS! • Addressing • Two part address: (network address, opaque address) • Transport • Mapping across protocols. Congestion/flow control etc. • Routing • Again at a network granularity – like BGP!

  11. Contexts • A Context is an area of the network that is homogenous in some regard. • Principally naming, addressing, routing and transport. • Two purposes: • Locational: serve as descriptors allowing end-to-end services to be composed through network closures • Mechanical: describe a set of communication mechanisms within which an endpoint might bind for a session

  12. Interstitial Functions (1) • Exist at the borders between contexts. • Allow data to cross contexts. • Already have such creatures • NAT boxes (IP nets), BGP routers (AS domains) • Not just IP though! • Dissimilar transport (IPv4 <-> ATM) • High-level overlays

  13. Interstitial Functions (2) Interstitial Function Includes translation mechanisms, buffering, authentication, etc. Interface To Context A Interface To Context B

  14. Example: Border Nets • Attempting to connect from a GPRS laptop to a sensor net via the Internet. • Both ends are behind opaque gateways. • Same as the two-NAT problem… connection impossible • Three stages to communication: • Name/Address lookup • Chained context instantiation • Application binding / Communication

  15. Ex: a. Lookup • Want a distributed service that passes queries and advertisements across contexts. • Search on name=value pairs. • i.e. find_route(destContextName=myExperimentalSensorNetwork, pathProperties=(protocol=QueryProtov1.2, connection=reliableByteStream)) • Properties act as hints… endpoint selects. • Get back a list of candidates, and pick one.

  16. SensornetGateway IF TCP Proxy IF Translation Mechanisms Buffers, Connection States, etc. Sensornet Stack TCP Stack TCP Stack TCP Stack Ex: b. Instantiation • Now we instantiate the new chained context. • Install an IF at each border. IPv4 Internet Sensor Network GPRS Network

  17. Ex: c. Apps Bind and Talk! • Finally, app binds to the newly created context. IPv4 Internet Sensor Network GPRS Network • End-to-end protocol-specific tunnel. • Midpoint customisations

  18. Future work • Go beyond ranting position paper. • Many unsolved issues. • lookup, • semantics of IFs • Impact / issues on end-to-end service. • Failure • Garbage collection? • Build something!

  19. Review • IP got us here through homogeneity • Want to extend all that – embrace heterogeneity • Key components to our architecture are contexts and IFs. • Also important is the accompanying infrastructure to make it work.

  20. Conclusions • Increasingly difficult to extend IP to support demands of new applications and environments. • We propose Plutarch an architecture that eschews homogeneity, allowing independent networks to work together for end-to-end communications. (the end)

  21. Isn’t this Active Networks?! • (a.k.a “What about untrusted code?”) • Finite set of common IFs. • Can be served from trusted repositories. • IFs not carried inside packets.

  22. Where are these IFs going to run? • IFs live on gateway nodes – these nodes must be accessible from both contexts involved. • Small matter of deployment. ;) • Need a platform for gateways to execute IFs in a reliable, accountable manner… • (Have I mentioned XenoServers?)

  23. Backup slides start here.

  24. The argument is circular! • Plutarch is by no means the be-all-end-all solution! • There may be a general purpose protocol that solves all these problems. • However, if that is the case, we would expect that it would emerge within Plutarch and grow to make all other contexts redundant.

  25. Naming and Addressing • We figure this is one of the hardest parts • (but not the only hard part) • Allowing heterogeneity means a diverse name/address space. • But this is what we have already… v4 is stretched, and v6 primarily suggests more bits • We imagine (context, internal name) pairs

  26. Motivation: key problems • Based on these claims, there seem to be three core issues: • IP is bad at some things. • IP is less than ideal for some environments and applications. • The commodification of IP stifles innovation.

  27. Overview • Motivation • Our Proposal: Plutarch • An Example • Future Work • Conclusion

More Related