1. COS 420 Day 3

2. Agenda Assignment Due Feb 2, 2006 Individual Projects assigned Today We will discussing Classful Internet Addressing

3. Individualized project Will be a research project & paper ~ 20 page paper MLA Format 10 Min Presentation You can pick any topic that one of the IETF working groups is developing http://www.ietf.org/html.charters/wg-dir.html Past history, Current state, upcoming developments Due Date Papers due March 20 Presentations will be on March 23

4. CLASSFUL INTERNET ADDRESSES Definitions Name Identifies what an entity is Often textual (e.g., ASCII) Address Identifies where an entity is located Often binary and usually compact Sometimes called locator Route Identifies how to get to the object May be distributed

5. Internet Protocol Address (IP Address) Analogous to hardware address Unique value assigned as unicast address to each host on Internet Used by Internet applications

6. IP Address Details 32-bit binary value 10110101011010101110010101010111 10110101<>01101010<>11100101<>01010111 181.106.229.87 Unique value assigned to each host in Internet Values chosen to make routing efficient

7. IP Address Division Address divided into two parts Prefix (network ID) identifies network to which host attaches Suffix (host ID) identifies host on that network

8. Classful Addressing Original IP scheme Explains many design decisions New schemes are backward compatible

9. Desirable Properties Of An Internet Addressing Scheme Compact (as small as possible) Universal (big enough) Works with all network hardware Supports efficient decision making Test whether a destination can be reached directly Decide which router to use for indirect delivery Choose next router along a path to the destination

10. Division Of Internet Address Into Prefix And Suffix How should division be made? Large prefix, small suffix means many possible networks, but each is limited in size Large suffix, small prefix means each network can be large, but there can only be a few networks Original Internet address scheme designed to accommodate both possibilities Known as classful addressing

11. Original IPv4 Address Classes

12. Important Property Classful addresses are self-identifying Consequences Can determine boundary between prefix and suffix from the address itself No additional state needed to store boundary information Both hosts and routers benefit PrefixClassBits Prefix Bits Net Bits Host 1A1724 10B21416 110C3218 1110D4Multicast 28 bits 1111E4Reserved 28 bits

13. Endpoint Identification Because IP addresses encode both a network and a host on that network, they do not specify an individual computer, but a connection to a network. A router with 8 connections gets 8 different IP’s

14. IP Address Conventions When used to refer to a network Host field contains all 0 bits 130.111.0.0 Broadcast on the local wire Network and host fields both contain all 1 bits 255.255.255.255 Directed broadcast: broadcast on specific (possibly remote) network Host field contains all 1 bits Nonstandard form: host field contains all 0 bits 130.111.255.255

15. Assignment Of IP Addresses All hosts on same network assigned same address prefix Prefixes assigned by central authority ICANN Obtained from ISP Large to small Each host on a network has a unique suffix Assigned locally Local administrator must ensure uniqueness

16. Advantages Of Classful Addressing Computationally efficient First bits specify size of prefix/suffix Just reading the 4 bits or less tells you Allows mixtures of large and small networks

17. Directed Broadcast IP addresses can be used to specify a directed broadcast in which a packet is sent to all computers on a network; such addresses map to hardware broadcast, if available. By convention, a directed broadcast address has a valid netid and has a hostid with all bits set to 1. Directed broadcasts are often filtered out by routers.

18. Limited Broadcast All 1’s Broadcast limited to local network only (no forwarding) Useful for bootstrapping

19. All Zeros IP Address Can only appear as source address Used during bootstrap before computer knows its address Means ‘‘this’’ computer

20. Internet Multicast IP allows Internet multicast, but no Internet- wide multicast delivery system currently in place Class D addresses reserved for multicast Each address corresponds to group of participating computers IP multicast uses hardware multicast when available More later in the course (chap 16)

21. Consequences Of IP Addressing If a host computer moves from one network to another, its IP address must change Big problem with mobile hosts like laptops, PDA’s and Internet capable cell phones For a multi-homed host (with two or more addresses), the path taken by packets depends on the address used

22. Multi-Homed Hosts And Reliability Knowing that B is multi-homed increases reliability

23. Dotted Decimal Notation Syntactic form for expressing 32-bit address Used throughout the Internet and associated literature Represents each octet in decimal separated by periods (dots)

24. Example Of Dotted Decimal Notation A 32-bit number in binary 10000000 00001010 00000010 00000011 The same 32-bit number expressed in dotted decimal notation 128. 10. 2. 3

25. Loopback Address Used for testing Refers to local computer (never sent to Internet) Address is 127.0.0.1

26. Classful Address Ranges 127.0.0.0 192.0.0.0

27. Summary Of Address Conventions

28. Example Of IP Addressing Assume an organization has three networks Organization obtains three prefixes, one per network Host address must begin with network prefix

29. Illustration Of IP Addressing

30. Two networks connected to Internet

31. Same network with Hosts

32. Summary IP address 32 bits long Prefix identifies network Suffix identifies host Classful addressing uses first few bits of address to determine boundary between prefix and suffix Special forms of addresses handle Limited broadcast Directed broadcast Network identification This host Loopback

33. COS 420 DAY 4

34. Agenda Assignment 1 Due Next Class Assignment 2 Posted Due Feb 13 Individual Project Assignments Grading for Individual Projects ARP and RARP

35. Individual Assignment Jeff - Emergency Preparedness (IEPRP)(IEPRP) Robyn - Audio Video Transport (AVT)(AVT) Donnie - Mobile Ad-hoc Networks (manet) (manet) Kristin - Network Mobility (nemo)(nemo) Papers due March 20 Presentations will be on March 23

36. Grading for Individualized Projects Rubric Paper Quality of research 30% Quality of Paper 30% Adherence to MLA format 10% Presentation Apparent mastery of material 10% Value of PowerPoint10% Oral effectiveness10% Grading will be done by both students and instructor 50% of Grade is average of your fellow students assessment 50% of Grade is instructor’s assessment Both use the same rubric for grading Students will only see final total

37. PART V MAPPING INTERNET ADDRESSES TO PHYSICAL ADDRESSES (ARP)

38. Motivation Must use hardware (physical) addresses to communicate over network Applications only use Internet addresses

39. Example Computers A and B on same network Application on A generates packet for application on B Protocol software on A must use B’s hardware address when sending a packet

40. Consequence Protocol software needs a mechanism that maps an IP address to equivalent hardware address Known as address resolution problem

41. Address Resolution Performed at each step along path through Internet Two basic algorithms Direct mapping Dynamic binding Choice depends on type of hardware

42. Direct Mapping Easy to understand Efficient Only works when hardware address is small (smaller than Host Portion of Internet Address) Technique: assign computer an IP address that encodes the hardware address

43. Example Of Direct Mapping Hardware: proNet ring network Hardware address: 8 bits Assume IP address 192.5.48.0 (24-bit prefix) Assign computer with hardware address K an IP address 192.5.48.K Resolving an IP address means extracting the hardware address from low-order 8 bits

44. Dynamic Binding Needed when hardware addresses are large (e.g., Ethernet) 48 bits MAC to 32 bit IP (don’t fit!) Allows computer A to find computer B’s hardware address A starts with B’s IP address A knows B is on the local network Technique: broadcast query and obtain response Note: dynamic binding only used across one network at a time

45. Internet Address Resolution Protocol (ARP) Standard for dynamic address resolution in the Internet Requires hardware broadcast Intended for LANs ONLY Important idea: ARP only used to map addresses within a single physical network, never across multiple networks

46. ARP Machine A broadcasts ARP request with B’s IP address All machines on local net receive broadcast Machine B replies with its physical address Machine A adds B’s address information to its table Machine A delivers packet directly to B

47. Illustration Of ARP Request And Reply Messages

48. ARP Packet Format When Used With Ethernet

49. Observations About Packet Format General: can be used with Arbitrary hardware address Arbitrary protocol address (not just IP) Variable length fields (depends on type of addresses) Length fields allow parsing of packet by computer that does not understand the two address types

50. Retention Of Bindings Cannot afford to send ARP request for each packet Solution Maintain a table of bindings Effect Use ARP one time, place results in table, and then send many packets

51. ARP Caching ARP table is a cache Entries time out and are removed Avoids stale bindings Typical timeout: 20 minutes

52. Algorithm For Processing ARP Requests Extract sender’s pair, (IA, EA) and update local ARP table if it exists If this is a request and the target is ‘‘me’’ Add sender’s pair to ARP table if not present Fill in target hardware address Exchange sender and target entries Set operation to reply Send reply back to requester

53. ARP Packet Format When Used With Ethernet

54. Algorithm Features If A ARPs B, B keeps A’s information B will probably send a packet to A soon If A ARPs B, other machines do not keep A’s information Avoids clogging ARP caches needlessly

55. Conceptual Purpose Of ARP Isolates hardware address at low level Allows application programs to use IP addresses

56. ARP Encapsulation ARP message travels in data portion of network frame We say ARP message is encapsulated

57. Illustration Of ARP Encapsulation

58. Ethernet Encapsulation ARP message placed in frame data area Data area padded with zeroes if ARP message is shorter than minimum Ethernet frame Ethernet type 0x0806 used for ARP

59. Arp at WORK

62. IP Address Assignment For conventional computer IP address stored on disk OS obtains address by reading from file at startup For diskless computer IP address obtained from server

63. Reverse Address Resolution Protocol (RARP) Old protocol Designed for diskless computer Obtains an IP address Adapted from ARP Broadcasts request to server Waits for response

64. Ethernet Encapsulation RARP message carried in data portion of Ethernet frame Ethernet type 0x0835 assigned to RARP

65. Illustration Of Packet Flow In (a) client broadcasts a request In (b) one or more servers respond

66. Client Identification Computer must identify itself RARP uses network hardware address as unique ID Only works on network with permanent address (e.g., Ethernet)

67. Modern Bootstrap Except for a few special cases, RARP has largely been replaced by DHCP We will postpone further discussion of bootstrapping until later in the course when we can consider DHCP

68. Summary Computer’s IP address independent of computer’s hardware address Applications use IP addresses Hardware only understands hardware addresses Must map from IP address to hardware address for transmission Two types Direct mapping Dynamic mapping

69. For next week Assignment #2 posted We begin a more in depth look at IP IP Architecture IP routing IP error and control messaging