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Multiplexing DCN Measurement Subsystems Host Monitoring Packet Radio Measurement XEROX NS IDP Trunk-1 Trunk-2 Leaf-1 Leaf-2 Reliable Data Protocol Internet Reliable Transaction ISO Transport Protocol Class 4 Bulk Data Transfer Protocol MFE Network Services Protocol MERIT Internodal Protocol Sequential Exchange Protocol Third-Party Connect Protocol Inter-Domain Policy Routing Protocol XTP
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30 31
NETBLT MFE-NSP
32 33
MERIT-INP SEP
34 35
3PC IDPR
37 38
DDP IDPR-CMTP
Datagram Delivery Protocol IDPR Control Message Transport Protocol TP++ Transport Protocol IL Transport Protocol IPv6 Source Demand Routing Protocol Routing Header for IPv6 Fragment Header for IPv6 Inter-Domain Routing Protocol Reservation Protocol General Routing Encapsulation Mobile Host Routing Protocol BNA Encap Security Payload for IPv6 Authentication Header for IPv6 Integrated Net Layer Security IP with Encryption NBMA Address Resolution P t l
39 40 41 42
TP++ IL IPv6 SDRP
43 44 45
IPv6-Route IPv6-Frag IDRP
46 47
RSVP GRE
48 49 50
MHRP BNA ESP
I-NLSP
53 54
SWIPE NARP
Protocol 55 56 MOBILE TLSP IP Mobility Transport Layer Security Protocol (using Kryptonet key management) SKIP ICMP for IPv6 No Next Header for IPv6
57 58 59 Table 3 1 (continued) Decimal
SKIP IPv6-ICMP IPv6-NoNxt
Keyword
Protocol
60 61 62 63 64
IPv6-Opts
Destination Options for IPv6 any host internal protocol
CFTP
CFTP any local network
SAT-EXPAK
SATNET and Backroom EXPAK Kryptolan MIT Remote Virtual Disk Protocol Internet Pluribus Packet Core any distributed file system
65 66
KRYPTOLAN RVD
IPPC
68 69 SAT-MON
SATNET Monitoring
70 71 72
VISA IPCV CPNX
VISA Protocol Internet Packet Core Utility Computer Protocol Network Executive computer Protocol Heart Beat Wang Span Network Packet Video Protocol Backroom SATNET Monitoring SUN ND PROTOCOLTemporary WIDEBAND Monitoring WIDEBAND EXPAK ISO Internet Protocol VMTP SECURE-VMPT VINES TTP NSFNET-IGP Dissimilar Gateway Protocol TCF EIGRP
CPHB
74 75 76
WSN PVP BR-SAT-MON
SUN-ND
78 79 80 81 82 83 84 85 86 87 88
WB-MON WB-EXPAK ISO-IP VMTP SECURE-VMTP VINES TTP NSFNET-IGP DGP TCF EIGRP
89 90 91
OSPFIGP Sprite-RPC LARP
OSPFIGP Sprite RPC Protocol Locus Address Resolution Protocol Multicast Transport Protocol AX25 Frames IP-within-IP Encapsulation Protocol Mobile Internetworking Control Protocol Semaphore Communications Sec Protocol Ethernet-within-IP Encapsulation Encapsulation Header any private encryption scheme
92 93 94
MTP AX25 IPIP
MICP
SCC-SP
ETHERIP
98 99
ENCAP
100 101
GMTP IFMP
GMTP Ipsilon Flow Management Protocol PNNI over IP Protocol Independent Multicast ARIS SCPS
102 103
PNNI PIM
104 105
ARIS SCPS
106 107 108
QNX A/N IPPCP
QNX Active Networks IP Payload Compression Protocol Sitara Networks Protocol Compaq Peer Protocol IPX in IP Virtual Router Redundancy Protocol PGM Reliable Transport protocol any 0-hop protocol
109 110 111 112
SNP Compaq-Peer IPX-in-IP VRRP
114 115 L2TP
Layer Two Tunneling Protocol D-II Data Exchange (DDX) Unassigned Reserved
116 117 254 255
Source and Destination Address Fields
The source and destination address fields are both 32 bits in length Each address represents both a network and a host computer on the network Because it is extremely important to understand the composition and formation of IP addresses to correctly configure devices connected to an IP network, we will next turn our attention to this topic Once we obtain an understanding of IP addressing, we will then examine the address resolution process required to enable layer 3 packets that use IP addresses to be correctly delivered via layer 2 addressing
The next generation IP, which is currently being operated on an experimental portion of the Internet, is referred to as version 6 and noted by the mnemonic IPv6 Because of significant differences in the method of addressing used by each version of the IP, we will cover both versions in this section First, we will focus our attention on the addressing used by IPv4 Once we obtain an appreciation for how IPv4 addresses are formed and used, we will turn our attention to IPv6 By first covering the addressing used by IPv4, we will also obtain the ability to discuss address compatibility methods that will allow IPv6 addresses to be used to access devices configured to respond to IPv4 addresses
Overview
IP addresses are used by the IP to identify distinct device interfaces such as interfaces that connect hosts, routers, and gateways to networks as well as to route data to those devices Each device interface in an IP network must be assigned to a unique IP address so that it can receive communications addressed to it This means that a multiport router will have one IP address for each of its network connections IPv4 uses 32-bit binary numbers to identify the source and destination addresses in each packet This address space provides 2,294,967,296 distinct addressable devices, which exceeded the world's population when the Internet was initially developed However, the proliferation of personal computers, the projected growth in the use of cable modems that require individual IP addresses, and the fact that every interface on a gateway or router must have a distinct IP address has contributed to a rapid depletion of available IP addresses Recognizing that hundreds of millions of people who currently do not have access may eventually be connected to the Internet, and also recognizing the potential for cell phones and even pacemakers to communicate via the Internet, the Internet Activities Board (IAB) commenced work on a replacement for the current version of IP during 1992 Although the addressing limitations of IPv4 was of primary concern, the efforts of the IAB resulted in a new protocol with a number of significant improvements over IPv4 to include the use of 128-bit addresses for source and destination devices This new version of IP, IPv6, was finalized during 1995 and is currently being evaluated on an experimental portion of the Internet Because this section is concerned with IP addressing, we will cover the addressing schemes, address notation, host address restrictions, and special addresses associated with both IPv4 and IPv6
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