spring 2006cs 3321 interdomain routing. spring 2006cs 3322 how to make routing scale flat versus...
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Spring 2006CS 3323 Internet Structure Recent Past NSFNET backbone Stanford BARRNET regional Berkeley P ARC NCAR UA UNM Westnet regional UNL KU ISU MidNet regional …TRANSCRIPT
Spring 2006 CS 332 1
Interdomain Routing
Spring 2006 CS 332 2
How to Make Routing Scale• Flat versus Hierarchical Addresses• Inefficient use of Hierarchical Address Space
– class C with 2 hosts (2/255 = 0.78% efficient)– class B with 256 hosts (256/65535 = 0.39% efficient)
• Demand for Class B the problem. So why not just assign 2 class C’s for a 50% efficiency rate?
• Still Too Many Networks– routing tables do not scale– route propagation protocols do not scale
Spring 2006 CS 332 3
Internet StructureRecent Past
NSFNET backboneStanford
BARRNETregional
BerkeleyPARC
NCAR
UA
UNM
Westnetregional
UNL KU
ISU
MidNetregional…
Spring 2006 CS 332 4
Internet Structure
• Autonomous system (AS)– Administered Independently of other ASs– Want to be able to control various ways in which
network is configured, used, etc.• Select their own intranetwork routing protocol• Perhaps select own link metrics, etc.
• Advantageous because it provides finer hierarchy– Good for scalability
Spring 2006 CS 332 5
Subnetting• Add another level to address/routing hierarchy: subnet• Subnet masks define variable partition of host part• Subnets visible only within site
Network number Host number
Class B address
Subnet mask (255.255.255.0)
Subnetted address
111111111111111111111111 00000000
Network number Host IDSubnet ID
Spring 2006 CS 332 6
Subnet Mask
• Written in dotted quad notation (like IP addresses)• Exactly one mask per subnet (all hosts on given
subnet have same subnet mask)• Subnet number of host (or of subnet) = bitwise
AND of subnet mask and IP address 11111111 11111111 11111111 10000000 10000000 01100000 00100010 00001111 10000000 01100000 00100010 00000000
Spring 2006 CS 332 7
Subnetting (cont)• To send IP packet:
– Host performs bitwise AND of its subnet mask with destination IP address
– If result is same subnet number as sending host, then destination is on same subnet, so forward directly (Note: Arp unaffected)
– Else send packet to a router to be forwarded to another subnet
• New routing table entries:<SubnetNumber, SubnetMask, NextHop> replaces
<NetworkNumber, NextHop>
Spring 2006 CS 332 8
Subnet Example
Forwarding table at router R1Subnet Number Subnet Mask Next Hop128.96.34.0 255.255.255.128 interface 0128.96.34.128 255.255.255.128 interface 1128.96.33.0 255.255.255.0 R2
Subnet mask: 255.255.255.128Subnet number: 128.96.34.0
128.96.34.15 128.96.34.1H1
R1
128.96.34.130 Subnet mask: 255.255.255.128Subnet number: 128.96.34.128
128.96.34.129128.96.34.139
R2H2
128.96.33.1128.96.33.14
Subnet mask: 255.255.255.0Subnet number: 128.96.33.0
H3
Spring 2006 CS 332 9
Forwarding AlgorithmD = destination IP addressfor each entry (SubnetNum, SubnetMask, NextHop) D1 = SubnetMask & D if D1 = SubnetNum if NextHop is an interface deliver datagram directly to D else deliver datagram to NextHop
• Use a default router if nothing matches• Not necessary for all 1s in subnet mask to be contiguous • Can put multiple subnets on one physical network(?!)• Subnets not visible from the rest of the Internet
Spring 2006 CS 332 10
The Key
• It’s important to remember that both subnetting and supernetting are attempts to help make routing scale– Even for an AS like U of R, subnetting can help shrink
routing tables, though this isn’t really a serious issue here
– Supernetting is really intended to make Internet routing scale – it benefits primarily the internet service providers and backbone routers, where the real scale problems exist.
Spring 2006 CS 332 11
Supernetting (CIDR)• What we’re shooting for:
backbone
3185*
31*
319*
3172*317*
3174*
317483*317482*
534*
51*
52*
5*
76*748*
73*
7*
Spring 2006 CS 332 12
Supernetting (CIDR)• Called CIDR: Classless Inter-Domain Routing• Assign block of contiguous network numbers to
nearby networks (in same AS or using same ISP)– Aggregates routes: single entry for many networks– E.g. Class B addresses 192.4.16-192.4.31 have same
top 20 bits, so a single 20 bit network address gets packets to correct AS.
• Restrict block sizes to powers of 2• Represent network numbers with(length, value)pair
• All routers must understand CIDR addressing
Spring 2006 CS 332 13
Supernetting (CIDR)• Assign block of contiguous network numbers to
nearby networks• Called CIDR: Classless Inter-Domain Routing• Represent blocks with a single pair (first_network_address, count)
• Restrict block sizes to powers of 2
Spring 2006 CS 332 14
Interdomain Routing• Much more difficult than intradomain routing
– Scale: Internet backbone router has 50,000+ prefixes– Impossible to calculate path costs: Different ASs mean
different link-state metrics which may not be comparable.
• Focus is on reachability, not optimality, and this is plenty difficult all by itself
– Trust: If you trust another AS, you trust their routing advertisements and their network system configuration info.
– Need for flexibility: “Use provider A only for these addresses”, “Use AS X in preference to AS Y”, etc.
Spring 2006 CS 332 15
Route Propagation• Know a smarter router
– hosts know local router (on same physical network)
– local routers know how to get to border router (and to each other)
– Regional ISP routers know how to get to its customers, and also to a border (gateway) router to a backbone provider
– Backbone (core) routers know everything (or at least how to get what they need)
Spring 2006 CS 332 16
Route Propagation
• Two-level route propagation hierarchy– interior gateway protocol (each AS selects its own)
• Also called intradomain routing – exterior gateway protocol (Internet-wide standard)
• Also called interdomain routing– Note again efficiency of default routes (AS need
only know inside AS and how to get out of AS)
Spring 2006 CS 332 17
EGP: Exterior Gateway Protocol• Overview
– designed for tree-structured Internet– This and other limitations caused it to be replaced by BGP
• Protocol messages– neighbor acquisition: one router requests that another be its
peer; peers exchange reachability information– neighbor reachability: one router periodically tests if the
another is still reachable; exchange HELLO/ACK messages; uses a k-out-of-n rule
– routing updates: peers periodically exchange their routing tables (distance-vector)
Spring 2006 CS 332 18
Internet StructureToday
Backbone service provider
Peeringpoint
Peeringpoint
Large corporation
Large corporation
Smallcorporation
“Consumer ” ISP
“Consumer” ISP
“ Consumer” ISP
transit ASs
stub AS
multihomed AS
Spring 2006 CS 332 19
BGP-4: Border Gateway Protocol• Concept of AS Types
– stub AS: has a single connection to one other AS• carries local traffic only
– multihomed AS: has connections to more than one AS• refuses to carry transit traffic
– transit AS: has connections to more than one AS• carries both transit and local traffic
Spring 2006 CS 332 20
BGP-4: Border Gateway Protocol
• Each AS has (aside from possibly 16 bit ID):– one or more border routers (need not be same
as the BGP speaker)– one BGP speaker that advertises (to other BGP
speakers):• local networks• other reachable networks (transit AS only)• gives complete path information (neither
DVR nor link-state, though closer to DVR)– Avoids loops
Spring 2006 CS 332 21
BGP-4: Border Gateway Protocol
Border routers
Spring 2006 CS 332 22
BGP Example• Speaker for AS2 advertises reachability to P and Q
– network 128.96, 192.4.153, 192.4.32, and 192.4.3, can be reached directly from AS2
• Speaker for backbone advertises– networks 128.96, 192.4.153, 192.4.32, and 192.4.3 can be reached along
the path (AS1, AS2).• Speaker can cancel previously advertised paths
Backbone network(AS 1)
Regional provider A(AS 2)
Regional provider B(AS 3)
Customer P(AS 4)
Customer Q(AS 5)
Customer R(AS 6)
Customer S(AS 7)
128.96192.4.153
192.4.32192.4.3
192.12.69
192.4.54192.4.23
Transit networks
stubs
Spring 2006 CS 332 23
Avoiding Loops
• Because of full path info, this scenario can be avoided:
AS 2
AS 1
AS 3
AS 1 learns it can reach Network 10.0.1 through AS 2, it advertises this toAS 3, who in turn advertisesit back to AS 2. If AS 2decides that it should sendpackets for 10.0.1 throughAS 3, we’ve got a loop.
Spring 2006 CS 332 24
Final BGP Notes
• BGP was designed to work with CIDR, so the “network” numbers that are passed around are really variable length prefixes, as used in CIDR– Typically written 144.166.206/19 and the like
• Number of nodes participating in BGP is on order of number of Ass (much smaller than number of networks)
• Finding good interdomain route amounts to finding path to the right border router, and there are only a few of these per AS
• Complexity of intradomain routing is on order of number of networks in the particular AS
Spring 2006 CS 332 25
Integrating Intra and Inter
• Stub AS (very common): border router “injects” default route into intradomain protocol
• Non-stub, but non backbone: Border routers inject learned (either through BGP or static config) info into intradomain protocol
• Backbone: IBGP (interior BGP): Too much info to inject into traditional intradomain protocol (10,000 prefixes = > big LSP + complex shortest path info). Traditional intradomain + protocols for querying border routers.
Spring 2006 CS 332 26
Scalability (again)• Nodes using BGP = O(number of ASs)• Finding good interdomain route = finding path to
correct border router (few per AS)• Complexity of intradomain = O(number physical
networks in AS)• Tradeoff between scalability and optimality
– Hierarchy hides info, hinders optimality– Hiding info key to scaling, since nodes don’t need
global info– In large networks, scalability more important
Spring 2006 CS 332 27
IP Version 6• Features
– 128-bit addresses (classless)– multicast– real-time service– authentication and security – autoconfiguration – end-to-end fragmentation– protocol extensions
• Header– 40-byte “base” header– extension headers (fixed order, mostly fixed length)
• fragmentation• source routing• authentication and security• other options