INS/Twine : A Scalable Peer-to-Peer Architecture for Intentional Resource Discovery

Preview:

DESCRIPTION

INS/Twine : A Scalable Peer-to-Peer Architecture for Intentional Resource Discovery. Magdalena Balazinska , Hari Balakrishnan, and David Karger MIT – Laboratory for Computer Science http://nms.lcs.mit.edu/. Problem Description. Abundant ubiquitous computation and communication - PowerPoint PPT Presentation

Citation preview

INS/Twine : A ScalablePeer-to-Peer Architecture for

Intentional Resource Discovery

Magdalena Balazinska, Hari Balakrishnan, and David Karger

MIT – Laboratory for Computer Science

http://nms.lcs.mit.edu/

Problem Description

• Abundant ubiquitous computation and communication

• Increasingly large computing environments

• Dynamic environments

• Many possible “cool” applications Locate resources using intentional

descriptions

INS Overview

INR: Intentional Name Resolver

INR

INR

INR

INRINR

INR

Self-configuringresolver network

Resources advertise their

capabilities

Client describes attributes of required resources

Resource Discovery Goals

• Allow client applications to locate services and devices

• Handle sophisticated resource descriptions

• Handle dynamism in the operating environment

• Scale to large numbers of resources

Existing Solutions for Scalability

SensorProxy Sensor

Proxy

Resolver

SensorProxy

Resolver ResolverResolver

Partitioning

Resolver

Bldg 1 Bldg 2

Bldg 3

Floors 1-3 Floors 4-6

?

Resolver

Cameras

Existing Solutions for Scalability

SensorProxy Sensor

Proxy

Resolver

SensorProxy

Resolver ResolverResolver

Hierarchies

ResolverResolver

Resolver

INS/Twine Contributions

• Collaborating peer resolvers: no content or location constraints on queries

• Scalability and load distribution via hash-based partitioning of resource descriptions among resolvers

• Semi-structured resource descriptions with arbitrary attribute-set

• Network dynamism• Designed for an environment where all

resources are equally important to users

INS/Twine Approach Overview

Resolver

Resolver

Resolver

Resolver

Resolver

Resolver

Resolver

resource = camerasubject = traffic

resource = motion sensorsubject = traffic

subject = traffic

subject = traffic

resource = motion sensorresource = camera

SensorProxy

INS/Twine Approach Overview

1. A resource advertises its descriptions and network location to any resolver

2. The description is converted into a canonical form: attribute-value tree (AVTree)

3. Using the content of the advertised description, the resolver determines which resolvers should know about the resource

4. The resolver forwards the description to these resolvers for storage

5. Similarly for queries

Architecture of One ResolverResolver

0110 1001 0000Key

StrandMapper

h : 0110 1001 0000

Best(01101001000)K nodes are chosen

KeyRouter

0110 1001 0000

Distributed Hash Table

h = hash(a1v1-a2v2)

Res adv.

a1

v1

a2

v2

Strand

Splitting Descriptions into Strands

Resource description: AVTrees

traffic

root

subjectresource

camera

manufacturer

ACompany

model

AModel

Six strands

• Each strand is then hashed into a 128 bit value which determines the nodes that will store the resource information.

• All queries, even short stranded queries require asking only one resolver!

resource

camera

manufacturer

resource

camera

ACompany

model

AModel

resource

camera

resource

camera

manufacturer model

resource

camera

subject

traffic

Distributed Hash Table: Chord

• Nodes and keys have 160-bit ID’s• Chord maps ID’s to “successor”• Successor: Node with next highest ID

N32

N10

N5

N20

N110

N99

N80

N60

CircularID Space

Stores key-values for keys 21..32

Keys 33..60

Basic Lookup

N32

N90

N105

N60

N10N120

K80

“Where is key 80?”

“N90 has K80”

Successor pointer

“Finger table” allows log(N)-time lookups

N80

½¼

1/8

1/161/321/641/128finger[i] points to

successor (n + 2i)log(n) fingers in all

K = log(n) immediateSuccessors for robustness

Stabilization methods for concurrency

Back to Example

Resolver

Resolver

Resolver

Resolver

Resolver

Resolver

Resolver

resource = camerasubject = traffic

resource = motion sensorsubject = traffic

subject = traffic

subject = traffic

resource = motion sensorresource = camera

SensorProxy

Properties of INS/Twine

• For a resource description with a attributes, t at the top-level : – Number of strands is : s = 2a – t

• For R resources, S strands, K replication level, and N resolvers :– Storage requirement at each resolver : (RSK)/N

• Advertisement: – SK resolvers contacted (+ O(log N) for key routing)

• Query: – K resolvers contacted (+ O(log N) for key routing)– 100% success rate for less than K failures– Failure rate decreases exponentially with K

State Management

• Resources join, move, leave and fail

• Resolvers join and fail

• How to maintain consistency while achieving fault tolerance?– Hard state– Soft state– Hybrid solution implemented in INS/Twine

State Management

INR

INR: Intentional Name Resolver

INR

INR

INR

INR

INR

INR

INR

Resource

State Management

INR

INR: Intentional Name Resolver

INR

INR

INR

INR

INR

INR

INR

Resource

Remove RemoveRemove

State Management

INR

INR: Intentional Name Resolver

INR

INR

INR

INR

INR

INR

INR

Resource

State Management

INR

INR: Intentional Name Resolver

INR

INR

INR

INR

INR

INR

INR

Resource

ExpireExpire

Expire

Evaluation: Data Distribution

Cumulative fraction of resolvers

0

0.1

0.2

0.3

0.4

0.5

0.6

0.7

0.8

0.9

1

0 0.05 0.1 0.15 0.2 0.25 0.3 0.35 0.4 0.45Fraction of resources

mp3 descr. Thresh. 50mp3 descriptions

Bib entries. Thresh. 100Bibliographical entries

Data distribution rather even. Each resolvers holds a small fraction of resource descriptions

Evaluation: Query Resolution

0

0.1

0.2

0.3

0.4

0.5

0.6

0.7

0.8

0.9

1

0 0.01 0.02 0.03 0.04 0.05 0.06

Cumulative fraction of resolvers

Fraction of queries

mp3 descriptionsBibliographical entries

Even distribution of queries among resolvers

Conclusion

• Intentional resource discovery

• Scalable peer-to-peer network of resolvers

• Hash-based mapping of resource descriptions to resolvers

• Dynamic and even distribution of resource information and queries

• Handles dynamism of resources and resolvers

http://nms.lcs.mit.edu/projects/twine/

Appendix

INS Overview

INR: Intentional Name Resolver

Describing Resources

• INS name-specifier<service>printer <type>color</type> <speed>slow</speed></service><cost> high</cost>

[service=printer [type=color] [speed=slow]][cost=high]

service

printer

root

cost

high

speedtype

color slow

• XML

• AVTrees

Problems using concatenation

1. If numerous resources share the same prefix, some nodes may receive significantly more load than others

2. Fully solving short stranded queries requires the colaboration of a linearly growing number of resolvers (with respect to network size)

3. 1) and 2) are contradictory requirements!

Distributed Hash Table: Chord

A distributed hash-table is used to map keys onto resolvers efficiently:

From: Chord: A Peer-to-Peer Lookup Service for Internet ApplicationsIon Stoica, Robert Morris, David Karger, Frans Kaashoek, Hari Balakrishnan Proc. ACM SIGCOMM Conf., San Diego, CA, September 2001.

Problems using prefixes

1. More insertions for each resource. Small factor since we expect descriptions to be rather short

2. Very popular prefixes may overload certain nodes : many advertisements and queries => the prefix should then become unusable

1. Nodes stop storing resources for that prefix

2. Nodes answer queries for the prefix specifying that they provide a partial answer due to the vague nature of the query

Recommended