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NIRA: A New Internet Routing Architecture

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Title: NIRA: A New Internet Routing Architecture


1
NIRA A New Internet Routing Architecture
  • Xiaowei Yang
  • MIT CSAIL
  • yxw_at_mit.edu

2
Why NIRA?
  • Problems with todays routing system
  • No user choice
  • Does not scale well
  • Continuing growth of global routing state
  • No fault isolation
  • NIRA solves these problems.

3
No User Choice!
Backbones
  • Unlike in the telephone system, users cannot
    choose wide area providers separately from local
    providers.
  • Pricing, quality of service, security
  • Wide area providers cannot offer differentiated
    services directly to users.
  • Quality of service

Comcast
Verizon
21 Million Broadband Subscribers in June 2003.
Duopoly / Monopoly
4
We Want to Let Users Choose Domain-Level Routes
ATT
UUNET
  • Our hypothesis
  • User choice stimulates competition.
  • Competition fosters innovation.
  • Validation requires market deployment.
  • NIRA the technical foundation.

Local ISP
5
Problems with Current Inter-domain Routing
  • No user choice
  • Does not scale well
  • Continuing growth of global routing state
  • No fault isolation

6
Continuing Growth of Global Routing State
Courtesy of http//bgp.potaroo.net/
  • Real world requirements such as multi-homing are
    not well supported.

7
No Fault Isolation
  • Local failure causes global routing update.
  • Routing loop and packet drops happen in
    transient state.
  • Routing convergence takes on the order of
    minutes.

8
My Approach NIRA
9
Overview of NIRA
  • A scalable architecture that gives users the
    ability to select routes.
  • User is an abstract entity, e.g., software
    agent
  • Domain-level choices
  • Encourage ISP competition
  • Individual domains decision to offer
    router-level choices

10
Design Overview (1) Route Discovery
Cindy
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core
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X
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Alice
Bob
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11
Design Overview (2) Route Representation
Cindy
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core
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Alice
Bob
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12
Design Overview (3) Failure handling
Cindy
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core
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Alice
Bob
N1
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  • Will not discuss provider compensation in
    details.

13
Cindy
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core
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Bob
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Alice
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14

System Components of NIRA
  • Addressing
  • Route discovery
  • Name-to-Route mapping
  • Route failure handling

15
NIRAs Addressing
Core
B2
B1
1/16
2/16
13/32 21/32
  • Strict provider-rooted hierarchical addressing
  • An address represents a valid route to the core.

11/32
12/32
R3
R2
R1
131/48 211/48
111/48 121/48
N3
122/48
N1
N2
1111000 1211000
1312000 2112000
16
Why is NIRAs Addressing Scalable?
Core
B2
B1
1/16
2/16
13/32 21/32
  • Financial factors limit the size of core.
  • Provider hierarchy is shallow.
  • A domain has a limited number of providers.

11/32
12/32
R3
R2
R1
131/48 211/48
111/48 121/48
N3
122/48
N1
N2
1111000 1211000
1312000 2112000
17
Efficient Route Representation
Core
B2
B1
1/16
2/16
13/32 21/32
11/32
12/32
R1
R3
R2
131/48 211/48
111/48 121/48
122/48
N3
N1
N2
1111000 1211000
1312000 2112000
  • A source and a destination address unambiguously
    represent a common type of route.
  • General routes may use source routing headers.

18
Routers Forwarding Tables
Uphill table
Core
B2
B1
1/16
2/16
  • Uphill table providers
  • Downhill table customers, self
  • Bridge table all others

13/32 21/32
11/32
12/32
Downhill table
R1
R3
R2
111/48 121/48
131/48 211/48
N3
122/48
N1
N2
1111000 1211000
1312000 2112000
19
Basic Forwarding Algorithm
Core
B2
B1
1/16
2/16
13/32 21/32
11/32
  • Look up destination address in the downhill
    table. If no match,
  • Look up the source address in the uphill table.

12/32
R1
R3
R2
131/48 211/48
111/48 121/48
N3
122/48
N1
N2
1312000 2112000
1111000 1211000
20

System Components of NIRA
  • Addressing
  • Route discovery
  • Topology Information Propagation Protocol (TIPP)
  • Name-to-Route mapping
  • Failure handling

21
What does TIPP Do?
Core
B1
B2
X
  • Propagates addresses
  • Propagates up-graph providers and their
    inter-connections on a users routes to the
    core.

R1
R3
R2
N3
N1
N2
1111000 1211000
temporarily unusable
2211000
22
What is TIPP Like?
  • Link-state style protocol
  • Supports scoped propagation
  • Provides a consistent view of network
  • A simple, proven to be correct algorithm SG89
  • No sequence numbers, no periodic refreshments, no
    timestamps
  • Fast convergence

23
Why is TIPP Scalable? (1)
Cindy
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core
N6
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Bob
N1
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Alice
N2
  • Up-graph is small.

24
Why is TIPP Scalable? (2)
Cindy
N11
N10
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  • Scoped propagation ? fault isolation

N8
R7
R8
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core
N6
B4
B3
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R10
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X
N4
R1
R3
R2
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Bob
N1
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Alice
N2
25

System Components of NIRA
  • Addressing
  • Route discovery
  • Name-to-Route mapping
  • Failure handling

26
Name-to-Route Lookup Service (NRLS)
Foo.com server
Core
Alice.foo.com 1312000 2112000
B2
B1
  • An enhanced DNS service

R1
R3
R2
N3
N1
N2
1111000 1211000
1312000 2112000
1312000 2112000
Alice.foo.com 1312000 2112000
27

System Components of NIRA
  • Addressing
  • Route discovery protocol
  • Name-to-Route mapping
  • Failure handling

28
How Route Failures are Handled
Foo.com server
Core
B2
B1
  • A combination of TIPP notifications and router
    feedbacks or timeouts.
  • Switching addresses to switch to a different
    route
  • HIP Moskowitz04, SCTP RFC 2960, TCP migrate
    Snoeren00

X
X
R1
R3
R2
Alice.foo.com 1312000 2112000
N3
N1
N2
1111000 1211000
29
NIRA Solves these Problems
  • User choice
  • Choosing addresses ? choosing routes ? choosing
    providers
  • Scalability
  • Modularized route discovery.
  • Constrained failure propagation.

30
Evaluation
31
Data Sets
  • Domain-level topologies from BGP routing tables
  • Inferred domain relationships Gao00
    Subramanian02
  • Not completely accurate, but best practice.
  • Data from 2001 to 2004 Agarwal

32
Evaluation of Scalability
  • Methodology
  • Measure the amount of state each domain keeps
    assuming NIRA
  • Number of providers in the core
  • Number of address prefixes
  • Size of up-graphs
  • Size of forwarding tables
  • Conclusions
  • Scalable in practice

33
The Internet Continues to Grow
34
Provider-rooted Hierarchical Addressing is
Practical.
  • In practice
  • Level of provider hierarchy (h) is shallow.
  • A domain has a limited number (p) of providers.
  • In theory ph

35
Up-graphs are Small.
  • Analysis
  • Level of provider hierarchy h
  • Number of a domains providers p
  • Number of a domains peers q
  • ?i1h pi-1(pq)

36
Evaluation of TIPP in Dynamic Networks
  • Methodology
  • Packet-level simulations using sampled topologies
  • Conclusion
  • Low communication cost
  • Fast convergence

37
Communication Cost of TIPP is Low.
Convergence No message churning
  • Average total messages (bytes) / link / failure
  • Maximum max seen messages (bytes) over one link
    / failure

Scalable scoped propagation
38
TIPP Converges Fast
  • Link delay uniformly distributes in 10ms,
    110ms.
  • Single failure convergence time is proportional
    to the shortest path propagation delay.

39
Conclusion
  • User choice
  • Choosing addresses ? choosing routes ? choosing
    providers
  • Scalability
  • Modularized route discovery.
  • Constrained failure propagation.
  • Evaluation shows NIRA is practical.
  • Looking forward
  • New provider compensation model
  • Stable routing with user choice
  • Deployment of NIRA

40
Core Routing Region is Scalable
  • Financial factors limit the size of core.

41
Forwarding Tables
  • No need to dynamically compute paths to reach a
    prefix.
  • Common case
  • Small
  • Analysis
  • Number of prefixes r
  • Number of customers c
  • Number of peers q
  • r r rc q

42
TIPP in Dynamic Networks
  • Simulation topologies
  • Pick random leaf domains
  • Recursively include their providers and peers

43
Workload Analysis of NRLS Update
  • A fundamental tradeoff
  • Topology change will cause address change
  • Root servers reside in top-level providers.
  • Route record updates mimic a renumbering event
  • How often can route update happen?
  • Route server processing time 1ms per update
  • 1000 updates / second / server
  • 100,000 updates ! 100 seconds 2 minutes
  • Bandwidth 5 of 100Mb/s for 100,000 users, 100
    bytes per update, ! 625 updates / second ! 160
    seconds 3 minutes to update all users
  • Route update causes contractual or physical
    topology change
  • Could be scheduled
  • Allow for a grace period, say 30 minutes
  • Conclusion manageable

44
Architectural Problem in the Internet
Adds one entry into BGP tables
45

b000/16
a000/16
Core
B2
B1
a0001/32
a0002/32
a0003/32
b0001/32
R1
R3
R2
b00011/48
a00021/48
a00022/48
a00011/48
a00031/48
N3
N1
N2
b00011/96 a00031/96
a00011/96 a00021/96
a000111000 a000211000 1111N11000
b000111000 a000311000 1111N31000
Hierarchy address
Non-hierarchy address
46
Address Allocation
  • A hierarchical address prefix is a leased
    resource.
  • survives connection breakdown and node failures.
  • periodic lease renewal.
  • de-allocated when lease expires.

B
R
N
Established
a000/16
Address allocation decision making
a0001/32

R
a00011/48
N
Time
47
Edge Record Origination and Distribution
B
R
N
a000/16
a0001/32

R
Internal reachable B ? R a0001/32 External
reachable B ? R e
Internal reachable B? R a0001/32 External
reachable B ? R e Internal reachable R ? B
a000/32 External reachable R ? B
Topology update procedure
a00011/48
edge (B, R)
N
Time
  • One directional attributes exchanged during
    connection setup.
  • Topology update procedure distributes edge
    records to neighbors.

48
A Sampled Topology
49
Ensuring Edge Record Consistency
  • Common techniques
  • Sequence numbers (OSPF, IS-IS)
  • Flooding
  • Timestamps
  • Loosely synchronized clocks
  • Modified Shortest Path Topology Algorithm (SPTA)
    SG89
  • Pros
  • No sequence numbers or timestamps
  • Simple, proven correct
  • Cons
  • Computation cost per update.
  • Communication cost in a theoretical worst case
    is unbounded.

50
Scalable Route Discovery with Transit Policies
Net3
Net4
  • Addressing must take policies into consideration.
  • A natural solution provider-rooted hierarchical
    addressing Tsuchiya91 Francis94

Backbone1
Backbone2
X
ISP1
ISP2
peer
peer
Net1
Net2
provider
customer
51
Design Components and Requirements


X
  • Design components
  • Route discovery
  • Route representation
  • Route failure handling
  • Provider compensation
  • Design requirements
  • Scalable
  • Efficient
  • Robust
  • Heterogeneous user choice
  • Practical provider compensation

52
Design Overview of TIPP
  • Design focus simplicity and correctness
  • Address allocation straightforward
  • Topology information propagation tricky
  • OSPF (RFC 2328) 244 pages, BGP (RFC 1771) 57
    pages
  • Policy-controlled topology propagation
  • Information hiding
  • Scope
  • Key design decisions
  • Shortest Path Topology Algorithm SG89
  • simple, proven to be correct
  • No sequence numbers or timestamps
  • Not guaranteed to discover all possible routes

53
Policy-controlled Topology Propagation
Core
B2
B1
1/16
2/16
13/32 21/32
  • Edge record
  • Originated by a domain
  • Contains bidirectional attributes and policy
    specification
  • An edge record is propagated based on policies.

11/32
12/32
R1
R3
R2
131/48 211/48
111/48 121/48
N3
122/48
N1
N2
1111000 1211000
1312000 2112000
Originator ID R3 Neighbor ID B2 Status
up Internal reachable (R3 ? B2) (0,
2/16) External reachable (R3 ? B2) Internal
reachable (B2 ? R3) (1, 21/32) External
reachable (B2 ? R3) e
54
Shortest Path Topology Algorithm
Ns summary of edge records
Network
R1
R2
(P1, P2, down) (R2, P1, down) (N, R2, up)
(P1, P2, up) (R1, P1, up) (N, R1, up)
N
(N, R1, up) (N, R2, up) (R1,P1, up) (R2, P1,
down) (P1, P2, up)
Trust news from the neighbor on the shortest
path.
Ns summary
55
Scalable Route Discovery
  • Three system components
  • A strict provider-rooted hierarchical addressing
    scheme
  • TIPP a user learns his addresses and topology
    information.
  • NRLS a user learns destinations addresses and
    optional topology information.
  • Combining information from TIPP and NRLS, a user
    is able to select an initial route.
  • TIPP a new protocol in NIRA

56
Analysis of Strict Provider-rooted Hierarchical
Addressing
Core
B2
B1
1/16
2/16
13/32 21/32
11/32
12/32
  • Provider hierarchy is shallow.
  • Pro a scalable core routing region.
  • Pro scalable route discovery
  • A valid route to a provider implies a
    policy-valid route to its customers.
  • Con topology-dependent addresses
  • Con multiple address selection

R1
R3
R2
131/48 211/48
22/32
111/48 121/48 221/48
N3
122/48
N1
N2
1111000 1211000 2211000
1312000 2112000
57
Provider Compensation
  • Contractual agreements.
  • Users cannot use arbitrary routes.
  • Providers use policy checking to prevent
    illegitimate route usage.
  • Direct business relationships
  • Common case verify source address
  • General case packet filtering
  • Indirect business relationship end users pay
    remote providers
  • Policy is made upon the originator or the
    consumer of a packet.
  • An open and general problem. Working in progress
    with Jennifer Mulligan and David Clark.
  • Various billing schemes are possible.
  • Flat fee, usage-based billing.

58
Protocol Organization (TIPP)
  • Connection Management
  • Control plane

Idle
Connect
Active
OpenSent
open / address request
OpenConfirm
address request / address
AddreqConfirm
address / topology
AddrSynced
topology / keepalive
TIPP over a reliable transport connection
Established
keepalive
59
TIPP in Action
B
R
N
Established
1/16
B
Address allocation
11/32

R
Topology update
111/48
(B, R) up
N
Time
1111000, ready to use
60
Evaluation Checklist
  • Scalability
  • Size of core
  • Number of address prefixes
  • Number of link records
  • Size of forwarding tables
  • Forwarding efficiency
  • Dynamic networks
  • Communication cost of TIPP
  • Convergence time of TIPP
  • Route setup time with reactive failure detection
  • Workload of NRLS

61
Scalable Route Discovery without Policy Routing
2.1.1
1
2.1
2
1.2
1.1.1
  • A well-studied problem
  • At the hearts of scalable routing
  • An ingenious addressing scheme
  • Nice theoretical bound O(logN) N the total
    number of nodes
  • Cluster-based KK77, landmark routing
    Tsuchiya88

1.1
2.2
3
3.1.1
3.2
3.1
3.2.1
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