The Border Gateway Protocol and Classless InterDomain Routing - PowerPoint PPT Presentation

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The Border Gateway Protocol and Classless InterDomain Routing

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... (R seaux IP Europ ens) -- Europe. INRIA -- France. BGP.ppt ... Unrecognized Well-known Attribute, Attribute Flags Error, etc ... Hold Timer Expired (code 4) ... – PowerPoint PPT presentation

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Title: The Border Gateway Protocol and Classless InterDomain Routing


1
The Border Gateway Protocoland Classless
Inter-Domain Routing
  • Allan Halme
  • Seminar on Telecommunications Technology
  • October 5, 1998

2
Classless Inter-Domain Routing
  • Running out of class B addresses (half allocated
    by 1992)
  • Routing tables getting too big
  • Solution
  • Allocate consecutive class C addresses
  • Addresses are contiguous and share the same most
    significant bits
  • Routing protocols and routing tables need only
    refer to this supernet prefix
  • only one entry needed in routing protocols
  • Addresses are allocated by geographical region
  • network numbers within a region share the same
    prefix
  • can be referred to by a single entry in other
    regions routing tables
  • routing table aggregation
  • Enough addresses to 2000 (1995 estimate)

3
Regional Allocation
  • Continental division of class C addresses
  • Multi-regional
  • Europe
  • North America
  • Central/South America
  • Pacific Rim
  • Others
  • Allocation of addresses is delegated
    hierarchically to regional authorities
  • ie,
  • RIPE (Réseaux IP Européens) -- Europe
  • INRIA -- France

4
Address Assignments
  • Organization Assignment
  • requires fewer than 256 addresses 1 class C
    network
  • requires fewer than 512 addresses 2
    contiguous class C networks
  • requires fewer than 1024 addresses 4 contiguous
    class C networks
  • requires fewer than 2048 addresses 8 contiguous
    class C networks
  • requires fewer than 4096 addresses 16 contiguous
    class C networks
  • requires fewer than 8192 addresses 32 contiguous
    class C networks
  • requires fewer than 16384 addresses 64 contiguous
    class C networks

5
The Border Gateway Protocol
  • The BGP is an inter-autonomous system routing
    protocol designed for TCP/IP systems defined
    primarily in RFC 1771
  • Learns multiple paths via internal and external
    BGP speakers
  • Picks the best path and installs in the IP
    forwarding table
  • Policies applied by influencing the best path
    selection
  • Procedures in BGP
  • Neighbor acquisition -- initial connection and
    initialization
  • Neighbor reachability -- keeping track of the
    peer (keepalive)
  • Network reachability -- maintain list of
    reachable prefixes and routes to them maintain
    database by accepting updates from other BGP
    routers and forwarding updates onward
  • The following BGP slides are based on
    Introduction to the Border Gateway Protocol (BGP)
    by Paul Ferguson, http//www.academ.com/nanog/feb1
    997/BGPTutorial/index.htm

6
BGP Between ASs
  • eBGP between ASs
  • iBGP within single AS

7
Autonomous Systems
  • Defined in RFC 1930 Guidelines for
    Creation,Selection, and Registration of an
    Autonomous System (AS) as

A connected group of one or more IP prefixes run
by one or more network operators which has a
single and clearly defined routing policy.
  • In practice, this is not totally strict
  • ie, the case where an AS is transitioning from
    RIP to OSPF

AS X
AS Y
AS A
A
B
OSPF network
E
RIP network
C
D
AS Z
AS T
8
Path Vectors and Path Attributes
  • Uses path vectors to indicate routes to
    destination prefixes
  • Destination network is specified by subnet
    (supernet) prefix (à la CIDR)
  • Route is sequence of ASs to be traversed to
    reach AS that contains destination network
  • Path vectors avoids routing loops
  • Consumes memory (each destination prefix needs
    own AS route list), but within reason if CIDR is
    used
  • Attributes describe a particular route
  • Path attribute contains
  • Attribute type code (AS path, next hop, etc)
  • Transitive / non-transitive (local)
  • Mandatory (well-known) / optional
  • Partially / fully evaluated by all routers in the
    AS path

9
Well-Known Attribute Types
  • AS path
  • Next hop
  • Local preference
  • Multi-exit discriminator (MED)
  • Others
  • Origin
  • Communities
  • ...

10
AS Path
  • List of AS numbers to be traversed to reach
    destination prefix
  • Loop detection (potential loop if own AS occurs
    in imported route)

11
Next Hop / eBGP
  • IP address of next BGP router on the way to
    destination
  • Usually local net in eBGP

12
Next Hop / iBGP
  • Next hop of external routes not changed when
    announced to iBGP neighbors

13
Local Preference
  • Local to AS
  • Used to influence BGP path selection
  • Path with highest local preference wins

14
Multi-exit Discriminator (MED)
  • Non-transitive
  • Used to convey the relative preference of entry
    points
  • Influences best path selection
  • Comparable if paths are from same AS
  • IGP metric can be conveyed as MED

15
Internal BGP (iBGP)
  • Same routing protocol as BGP, different
    application
  • iBGP should be used when AS_PATH information must
    remain intact between multiple eBGP peers
  • All iBGP peers must be fully meshed, logically
    an iBGP peer will not advertise a route learned
    by one iBGP peer to another iBGP peer
    (readvertisement restriction to prevent looping)

16
Scaling iBGP (1)
  • BGP Confederations
  • Method to subdivide a single AS into multiple,
    internal sub-ASs, yet still advertise a single
    AS to external peers
  • Reduces iBGP mesh

17
Scaling iBGP (2)
  • BGP Route Reflectors (RR)
  • Another method to reduce iBGP mesh
  • iBGP re-advertisement restrictions are relaxed
  • Single iBGP peer advertises (reflects) routes to
    subordinate iBGP peers
  • Clients must not peer with RRs outside of
    cluster

18
BGP Initialization
  • Open connection to peer router, TCP port 179
  • Each sends OPEN message to other
  • Possible errors include
  • Version is unsupported
  • send NOTIFICATION indicating supported versions
    and close TCP
  • peer will probably retry specifying lower version
    number
  • Collision
  • each peer tries to connect to the other, results
    in 2 TCP connections
  • one gets through first the latter duplication is
    detected by noticing that the peer is already
    listed in routing table
  • Authentication and sanity checks
  • Eg, peer is found in list of acceptable potential
    neighbors
  • Peer identifier is a valid address, length field
    checks out
  • Rejection indicated by NOTIFICATION message and
    closure of TCP
  • Connection is accepted by sending KEEPALIVE
    message
  • Routing tables are initialized by UPDATE messages

19
Updating
  • Once initial connection is established, route
    information is exchanged with UPDATE messages
  • Send only as needed
  • KEEPALIVE responsible for monitoring neighbor
    reachability
  • All known paths sent, using as many UPDATE
    messages as needed
  • After initial exchange, new UPDATE messages are
    sent only when path information changes or new
    path information is received
  • Upon receipt of new path information
  • If path is new, add to table
  • If destination is unreachable, remove from table
  • If path already exists, old path is replaced only
    if new path is shorter
  • If update came from neighbor responsible for
    routing to path, update
  • Forward new information to all other external
    neighbors

20
Keepalive
  • Neighbor reachability / availability monitoring
  • UPDATE messages are triggered only as necessary
  • Not sufficient to merely send keepalives to
    neighbor
  • BGP router expects also to receive keepalives
    from peer
  • Hold time (negotiated at initialization) is the
    maximum delay during which BGP router should
    expect keepalive from peer
  • If nothing heard, peer is assumed to be down
  • NOTIFICATION is sent to peer
  • TCP connection is closed

21
Error Notification
  • On receipt of faulty message or other error (ie,
    non-receipt of keepalive within hold time),
  • NOTIFICATION message is sent to peer, and
  • TCP connection is closed gracefully
  • Errors
  • Message Header Error (code 1)
  • Unsupported Version Number (code 2, subcode 1)
  • Bad Peer AS / Bad BGP Identifier (code 2,
    subcodes 2 3)
  • Unsupported Authentication Code / Authentication
    Failure (code 2, subcodes 4 5)
  • UPDATE Message Error
  • Unrecognized Well-known Attribute, Attribute
    Flags Error, etc ...
  • Hold Timer Expired (code 4)
  • Finite-State Machine Error (code 5)
  • reception of unexpected message, ie UPDATE before
    OPEN has been accepted
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