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CSS 432: Routing 1 CSS432 Routing Textbook Ch4.2 Professor: Munehiro Fukuda Augmented By Rob Nash.

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Presentation on theme: "CSS 432: Routing 1 CSS432 Routing Textbook Ch4.2 Professor: Munehiro Fukuda Augmented By Rob Nash."— Presentation transcript:

1 CSS 432: Routing 1 CSS432 Routing Textbook Ch4.2 Professor: Munehiro Fukuda Augmented By Rob Nash

2 IP on Scale Addresses are hierarchical  Reduces total information storage required to forward packets Forward packets towards a single network  Then deliver to the host on that network CSS 432: Routing 2

3 IP on Heterogeneity A under-demanding model: “best-effort”  Due to this, IP has been shown to be interoperable with any type of network Even ones invented after IP Carrier Pigeons?!  Zebra’s are so much cooler…  http://portal.acm.org/citation.cfm?id=1147620 http://portal.acm.org/citation.cfm?id=1147620 Don’t like IP? Aren’t compatible? Try tunneling. CSS 432: Routing 3

4 Terms IGPs – Interior Gateway Protocols BGPs – Border Gateway Protocols RIP - Route Information Protocol OSPF – Open Shortest Path First Protocol ARP – Address Resolution Protocol  Maps IP addrs to physical adapters (MAC addrs) CSS 432: Routing 4

5 ARP The mechanism that translates from IP GuIDs to underlying physical adapter addressing  From IP to MAC, for example CSS 432: Routing 5

6 6 What Is Routing? Forwarding vs Routing  forwarding: To map a network # to an outgoing interface and some MAC information in a forwarding table. To send a packet to an interface as consulting a local and static forwarding table OSI Layer 2: data link level Implemented in specialized hardware (switch)  routing: To build a dynamic routing table To update table contents in a dynamic and distributed fashion OSI Layer 3: network level (internet) Using complex distributed algorithms

7 CSS 432: Routing 7 Overview Network as a Graph Goal  Find lowest cost path between two nodes Static approach has shortcomings:  Hardware failures  Static network topology  Static band width Distributed, dynamic routing algorithms  Distance vector routing (RIP)  Link state routing (OSPF) At Node A E3F E1E E2D E6C E2B Next HopCostDestination

8 CSS 432: Routing 8 Distance Vector Each node maintains a set of triples  (Destination, Cost, NextHop) DestinationCostNext hop B1B C1C D∞- E1E F1F G∞- An initial distance vector at node A

9 CSS 432: Routing 9 Distance Vector Exchange updates directly connected neighbors  periodically (on the order of several seconds)  whenever table changes (called triggered update) Each update is a list of pairs:  ( Destination, Cost) From B:(A, 1), (C, 1) From C:(A, 1), (B, 1), (D, 1) From E:(A, 1) From F:(A, 1), (G, 1) Update local table if receive a “better” route  From B: (C,1) (C, 1, C) < (C, 2, B)  From C: (D, 1) (D, ∞, - ) > (D, 2, C)  From F: (G, 1) (G, ∞, - ) > (G, 2, F) Refresh existing routes; delete if they are expired DestinationCostNext hop B1B C1C D2C E1E F1F G2F

10 CSS 432: Routing 10 Routing Loop Failure-recovering scenario  F detects the link to G has failed  F sets distance to G to ∞ and sends an update to A  A sets distance to G to ∞  A receives periodic update from C with a 2-hop path to G  A sets distance to G to 3 and sends update to F  F sets distance to G in 4 hops via A Count-to-infinity problem  The link from A to E fails  A advertises distance of infinity to E  C advertise a distance of 2 to E  B decides it can reach E in 3 hops  B advertises this to A  A decides it can read E in 4 hops  A advertises this to C  C decides that it can reach E in 5 hops… ∞ To G in 2 ∞ To G in 1 To G in 3 To G in 4 (2) To E in ∞ (1) To E in 2 (3) To E in 3 (5) To E in 4 A E B C (4) To E in ∞ (6) To E in 5

11 CSS 432: Routing 11 Loop-Breaking Heuristics Set infinity to 16  Scheme: Stop an infinity loop in 16.  Problem: No more 16 hops Split horizon  Scheme: Don’t send a neighbor the routing information learned from this neighbor. Ex. B includes (E, 2, A) and thus doesn’t send (E, 3). Split horizon with poison reverse  Scheme: Send the routing information learned from this neighbor as setting hop count to ∞. Ex. B includes (E, 2, A) and thus sends (E, ∞, A)  Problem: Its slow convergence speed

12 CSS 432: Routing 12 Routing Information Protocol (RIP) Cmd: 1-6  1: request  2: reply Port: 520  Used by routed Advertisement: 30secs Table entry timeout: 3 mins.  Deleted in 60secs Unix commands  Ripquery (BSD)  Tcpdump (available in Linux, too)  Snoop (Solaris) frame header datagram heaader UDP header RIP Message Cmd Ver Addr family (net addr) Address of net 1 Routing domain Route tag Subnet mask Next hop address (1-16) Distance to net 1 Addr family (net addr) Address of net 2 Route tag Subnet mask Next hop address Distance to net 2 (1-16) 25 entries

13 CSS 432: Routing 13 Link State Strategy  Reliable dissemination of link-state information to all nodes over a system.  Calculation of routes from the sum of all the accumulated link-state knowledge. Link State Packet (LSP)  ID of the node that created the LSP  A cost of link to each directly connected neighbor  A sequence number (SEQNO)  A time-to-live (TTL) for this packet

14 CSS 432: Routing 14 Link State (cont) Reliable flooding  Store most recent LSP from each node  Forward LSP to all nodes but one that sent it  Generate new LSP periodically Increment SEQNO  Start SEQNO at 0 when reboot  Decrement TTL of each stored LSP Discard when TTL=0 A C D X B

15 CSS 432: Routing 15 Dijkstra’s Shortest-Path Algorithm* put (myself, 0, -) in the confirmed list Next = myself; while( true ) {  for each edge (X, distance, Next) where X is N’s neighbor if neither confirmed or tentative list has (X, distance, Y) where Y != Next, put (X, distance, Next) in the confirmed list if the tentative list has (X, distance, Y) where Y != Next, and (X, distance, Y) > (X, distance, Next)  Replace (X, distance, Y) with (X, distance, Next)  If the tentative list is empty, exit  else move the shortest edge (A, distance, B) from the tentative to the confirmed list. Next = A }  // O((|E|+|V|) log |V|) time (which is dominated by O(|E| log |V|),

16 Forward Search From the Text M = {me} For each node n in N - {me}  C(n) = l(me, n) //cost function init While ( N != M )  M = M U {w} s.t. C(w) is the min w for all (N-M)  for each n in (N-M) C(n) = MIN( C(n), C(w) + l(w+n)) CSS 432: Routing 16

17 Another OSPF Algorithm Initialize costs, and start with {me} While set M is not empty (tentative list)  Pick a node from the tentative list with the lowest cost = m Move this to the confirmed list  List m’s neigbors, add each to tentative list If I have a neighbor route already in my tentative list with a higher cost, replace that route CSS 432: Routing 17

18 Graph Theory Visually…. CSS 432: Routing 18 http://en.wikipedia.org/wiki/Dijkstra's_algorithm

19 CSS 432: Routing 19 Dijkstra’s Shortest-Path Algorithm (A, 0, -) (B, 5, B) (C, 10, C) (E, 2, E) (F, 4, F) (A, 0, -) (E, 2, E) (B, 5, B) (C, 10, C) (F, 4, F) (A, 0, -) (E, 2, E) (F, 4, F) (C, 10, C) (B, 5, B) (A, 0, -) (E, 2, E) (F, 4, F) (C, 10, C) (B, 5, B) (G, 15, F) (A, 0, -) (E, 2, E) (B, 5, B) (F, 4, F) (C, 8, B) (G, 18, B) (A, 0, -) (E, 2, E) (B, 5, B) (F, 4, F) (C, 8, B) (G, 15, F) (A, 0, -) (E, 2, E) (B, 5, B) (F, 4, F) (C, 8, B) (D, 14, C) (G, 15, F) (A, 0, -) (E, 2, E) (B, 5, B) (F, 4, F) (D, 14, C) (G, 15, F) (A, 0, -) (E, 2, E) (B, 5, B) (F, 4, F) (C, 8, B) (G, 15, F) (A, 0, -) (E, 2, E) (B, 5, B) (F, 4, F) (C, 8, B) (D, 14, C) (G, 15, F) (A, 0, -) (E, 2, E) (B, 5, B) (F, 4, F) (C, 8, B) (D, 14, C) (G, 15, F) 11 5 10 3 2 6 4 2 13

20 CSS 432: Routing 20 Open Shortest Path First Protocol (OSPF) Header 1. Hello (reachability) 2. Database description (topology) 3. Link status request 4. Link status update 5. Link status acknowledgment Advertisement (header type=4)  LS Age: = TTL  Type=1: link cost b/w routers  Link-State ID = Advertising Router  Seq # from the same router  Link ID = the other end route ID of link  Link data = used if there are two or more links to the same router  Metric = link cost  Link type = P2P, ethernet, etc  TOS = delay-sensitive, etc frame header datagram heaader OSPF header OSPF Message Version Type(=4) AreaId Message Length Checksum Authentication 0-3 Authentication type SourceAddr Authentication 4-7 # of link status advertisements Link-state ID LS Age Options Advertising router LS sequence number Link Checksum Length 0Flag0# of links Type=1 Link ID Link data Metric Num TOS Link type Optional TOS information

21 CSS 432: Routing 21 OSPF Con’td Gated daemon: directly uses IP datagram. Header Type2: Database description (topology) message  Used when the current topology has changed.  Sent from an initialized router to another router which has a topology information LS Sequence number  Used to determine which message is the latest  Send a message with a new sequence number and metric= ∞ when a router or a link fails.

22 Link State V.S. OSPF Historically, OSPF has demonstrated more desirable properties  Less bandwidth usage on large networks After init, OSPF LPSs are deltas  Convergence speed Rip can take 10, 30, even 60 seconds  OSPF supports CIDR & netmasks CSS 432: Routing 22

23 Practically Speaking… RIP tells each direct neighbor about everyone  So, neighbor-to-neighbor dissemination OSPF (P) tells everyone about my direct neighbors  “Reliable” Flooding to all CSS 432: Routing 23

24 CSS 432: Routing 24 Metrics Original ARPANET metric  measures number of packets enqueued on each link  took neither latency or bandwidth into consideration New ARPANET metric  stamp each incoming packet with its arrival time ( AT )  record departure time ( DT )  when link-level ACK arrives, compute Delay = (DT - AT) + Transmit + Latency  if timeout, reset DT to departure time for retransmission  link cost = average delay over some time period Fine Tuning  compressed dynamic range  replaced Delay with link utilization

25 CSS 432: Routing 25 Internet Virtual Private Networks and Tunnels B A Company Branch Company Branch A B C A B Application Level Router Level Physical Network Level Source router Dest router Router 10.0.0.120.0.0.1 10.0.0.120.0.0.1 10.0.0.1 To: 20.0.0.1 215.0.0.1 To: 10.0.0.2 To: 215.0.0.1 To: 20.0.0.1 To: 215.0.0.1 To: 20.0.0.1

26 CSS 432: Routing 26 Why VPN? 1. Security The final destination/contents of packet cannot be easily intercepted. 2. Routers Routers with special features such as multicasting can form a virtual network. 3. No-IP packets Packets may be non-IP compatible packets. 4. Mobile IPs The final destination may be a mobile computer.

27 CSS 432: Routing 27 Mobile IP Home agent Internet Mobile Host 10.0.0.9 (12.0.0.7) DHCP server Mobile Host Sending host 10.0.0.3 12.0.0.6 Invariant: Sending hosts want to use the same IP address mapped to a mobile host regardless of its location. Questions  How does the home agent intercept a packet that is destined for the mobile agent? --- Use ARP  How does the home agent then deliver the packet to the mobile host? – Use DHCP and VPN

28 CSS 432: Routing 28 Mobile IP (Cont’d) Home agent Internet Mobile Host 10.0.0.9 (12.0.0.7) DHCP server Mobile Host 1. ARP request: What’s the physical addr corresponding to 10.0.0.9? 2. ARP response: sends back MAC of 10.0.0.3 instead of 10.0.0.9 IP tunneling: wraps the packet inside an IP header destined for the mobile host (12.0.0.7). 1. DHCP: receives a new IP in the foreign network. Sending host 3. Packet request: sends a packet destined for 10.0.0.9 to the home agent’s MAC address 2. Care-of-address: a mobile host informs its Home agent of its original and new IPs. 10.0.0.3 12.0.0.6

29 CSS 432: Routing 29 Reviews  RIP: distance vector, routing loop and breaking heurictics  OSPF: link state, Dijkstra’s shortest path algorithm  VPN and mobile IP Exercises in Chapter 4  Ex. 15 (RIP)  Ex. 18 (RIP)  Ex. 28 (OSPF)  Ex. 30 (OSPF)

30 CSS432: Applications 30 File Transfer Protocol Transfer file to/from remote host Client/server model  Client: initiates a control TCP connection to a server on port 21.  Client: sends a user ID and password as part of FTP commands.  Server: authorizes the client  Client: opens a data TCP connection to a server on port 20.  Server: maintains state: current directory, earlier authentication. A ftp client is allowed to initiate a transfer between two ftp servers. FTP local file system remote file system FTP server FTP client FTP user interface TCP port 20 for data transfer (not persistent) TCP port 21 for control (persistent)

31 CSS432: Applications 31 FTP Commands delimits each command (and reply). Commands consist of four uppercase ASCII characters, some with optional arguments:  USER username : sends a user identification to server.  PASS password : sends the user password to the server.  PASV: requests the server to send back its IP and port on which it listens to a data TCP connection from the user.  LIST : ask the server to send back its current directory contents through the data connection.  RETR filename : gets a file from the current remote directory.  STOR filename : stores a file into the current remote directory. Each command is followed by a reply:  331 Username OK, password required  125 Data connection already open; transfer starting  425 Can't open data connection  452 Error writing file FTP

32 CSS432: Applications 32 FTP Example FTP [mfukuda@uw1-320-20]$ telnet ftp.tripod.com 21 Trying 209.202.240.80… Connected to ftp.tripod.com (209.202.240.80). Escape character is ‘^]’. 220 Welcome to Tripod FTP. USER css432 331 Username set to css432. Now enter your password. PASS ******** 230 User ‘css432’ logged on. LIST 425 Can’t open data connection for LIST. PASV 227 Entering Passiv Mode (209,202,240,80,195,210) // Open another xterm and telnet 209.202.240.80 50130 (=195*256+210) // Trying 209.202.240.80… // Connected to ftp.tripod.com (209.202.240.80). // Escape character is ‘^]’. // drwxr-xr-x 1 css432 Tripod 0 Sep 15 21:22 cgi-bin // -rw-r--r-- 1 css432 Tripod 26169 Sep 16 18:28 ttcp.c // -rw-r--r-- 1 css432 Tripod 8236 Sep 15 21:22 index.htm // drwxr-xr-x 1 css432 Tripod 0 Sep 16 18:33 project // Connection closed by foreign host. LIST 150 Opening ASCII mode data connection for LIST. 226 Transfer complete. QUIT 221 Goodbye Connection closed by foreign host. [mfukuda@uw1-320-20]$ _

33 CSS432: Applications 33 FTP passive mode FTP server FTP client TCP port 21 for control (persistent) Client request: connect( ), USER, PASS, LIST Server Reply: 220 server ready, 331 send password, 230 login ok, 425 connection timeout TCP port 20 for data transfer (one time) FTP server FTP client TCP port 21 for control (persistent) Client request: connect( ), USER, PASS, PASV, LIST Server Reply: 220 server ready, 331 send password, 230 login ok, 227 Entering Passive Mode (140,142,12,173,195,54), 226 complete TCP port 195*256 + 54 = 49974 for data transfer (one time) data

34 CSS432: Applications 34 FTP proxy command FTP Server 2 FTP Server 1 FTP client (1) USER, PASS, SYST (2) USER, PASS, SYST (3) TYPE I, PASV (4) TYPE I, PORT (140,142,12,173,195,54), STOR file (5) RETR file (3’) 227 Entering Passive Mode (140,142,12,173,195,54) TCP port 195*256 + 54 = 49974 for data transfer (one time) data ftp> open server1 ftp> proxy open server2 ftp> proxy get file …(1) …(2) …(3)~(5)

35 Final Project Introduction FTP project is live on the site  We’ll worry with the last few steps during lecture Signing our archives, etc. CSS 432: Routing 35

36 FTP is Fun Transfer Protocol! (If you tend to think bytes are fun) We’re making a client to interface with an existing server (a class of servers) CSS 432: Routing 36

37 Remote Tips You can always remote into the lab You could install Ubuntu on a USB stick  Has a good ftp server to play with https://help.ubuntu.com/6.06/ubuntu/serverguide/C /ftp-server.html https://help.ubuntu.com/6.06/ubuntu/serverguide/C /ftp-server.html  You write the client to interact with this server CSS 432: Routing 37

38 General Tips Observe Dr. Fukuda’s output  It gives away hints left and right RFC 959 – light reading Telnet to port 21  Act as the client! For example, what does the server return when you issue a “USER” or “PASV” request? CSS 432: Routing 38

39 Telnet Line Terminators Carridge-Return, Line Feed Find this out CSS 432: Routing 39

40 How Many Lines Of Code? Decompose the project  A network component Resue code here from previous projects  A filesystem component Reuse code here if you have it! From Pseudocode to C, or  Pseudocode->intermediary language -> C CSS 432: Routing 40

41 Overarching Strategy (0) Introduce yourself to the server (1) Relay a request to the server (2) Get a socket for data transmission  See PASV (3) Exchange data in ASCII or Binary (4) Loop to (1) or QUIT CSS 432: Routing 41


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