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TDC375 Autumn 03/04 John Kristoff - DePaul University 1 Network Protocols Internet Protocol (IP)
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TDC375 Autumn 03/04 John Kristoff - DePaul University 1 Will layer 2 networking suffice?
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TDC375 Autumn 03/04 John Kristoff - DePaul University 1 Layer 3 usually provides... Internetworking for data link technologies Globally unique addresses Scalable routing A common communications format Packet fragmentation capability A hardware independent interface Packet independence
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TDC375 Autumn 03/04 John Kristoff - DePaul University 1 An IP router (or gateway)... Is usually a special purpose, dedicated device Connects heterogenous networks Directs packets toward their ultimate destination Often uses dynamic routing algorithms/protocols which make automatic forwarding decisions which make decisions based on various metrics Official pronounciation is rooter layer 3 switch = router = layer 3 switch
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TDC375 Autumn 03/04 John Kristoff - DePaul University 1 IP routing Scope autonomous system (AS), interior, exterior Dynamic routing protocol for route exchange and computation Static routing manually configured routes Destination address driven
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TDC375 Autumn 03/04 John Kristoff - DePaul University 1 Internet Protocol (IP) Documented in IETF RFC 791 Connectionless Unreliable Simple (relatively) The thin waist in the TCP/IP suite hourglass model
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TDC375 Autumn 03/04 John Kristoff - DePaul University 1 IP address Virtual, not specific to a hardware device 32-bit fixed address length (IPv4) Unique address for each interface (typically) Global registrar assigns network bits (prefix) Local administrator assigns host bits (suffix) Usually written in dotted decimal (dotted quad) e.g. 140.192.5.1
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TDC375 Autumn 03/04 John Kristoff - DePaul University 1 IP address types Unicast (one-to-one) source addresses should always be unicast Multicast (one-to-many) receivers join/listen to group destination address Broadcast (one-to-all) special case of multicast, usually unnecessary Anycast (one-to-one-of-many) usually one-to-nearest, often used for reliability
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TDC375 Autumn 03/04 John Kristoff - DePaul University 1 IP address notation
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TDC375 Autumn 03/04 John Kristoff - DePaul University 1 Special IP addresses
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TDC375 Autumn 03/04 John Kristoff - DePaul University 1 Classful IP addressing
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TDC375 Autumn 03/04 John Kristoff - DePaul University 1 Classful address sizes
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TDC375 Autumn 03/04 John Kristoff - DePaul University 1 Example IP network
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TDC375 Autumn 03/04 John Kristoff - DePaul University 1 Example IP router addressing
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TDC375 Autumn 03/04 John Kristoff - DePaul University 1 Classful addressing limitations Internet growth Route table size Address depletion Misappropriation of addresses Lack of support for varying sized networks Class B is often too big, Class C often too small
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TDC375 Autumn 03/04 John Kristoff - DePaul University 1 IP addressing solutions Subnetting Supernetting Classless interdomain routing (CIDR) Variable length subnet masks (VLSM)
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TDC375 Autumn 03/04 John Kristoff - DePaul University 1 Subnetting
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TDC375 Autumn 03/04 John Kristoff - DePaul University 1 Subnet masks The bit length of the prefix (network bits) Prefix (network bits) no longer classful (fixed size) Use of the slash '/' notation to represent addresses 140.192.5.1 with mask of 255.255.255.128 is: 140.192.5.1/25 As viewed in binary for clarity, a /25 mask is: 11111111.11111111.11111111.10000000
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TDC375 Autumn 03/04 John Kristoff - DePaul University 1 Subnet masks example Given 140.192.50.8/20 what is the... subnet mask in dotted decimal notation? directed broadcast address in dotted quad? total number of hosts that can be addressed?
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TDC375 Autumn 03/04 John Kristoff - DePaul University 1 Supernetting Combine smaller address blocks into an aggregate If class B is too big and class C is too small... Combine 199.63.0.0/24 to 199.63.15.0/24 To form 199.63.0.0/20
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TDC375 Autumn 03/04 John Kristoff - DePaul University 1 Supernetting example Given an ISP that has 128.15.0.0/16: what block might be assigned to a customer needing to address 300 hosts? how does the ISP manage their IP address allocation if there are many customers with varying address requirements?
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TDC375 Autumn 03/04 John Kristoff - DePaul University 1 CIDR Routers using aggregated prefixes (CIDR blocks) primarily through the use of supernetting So instead of adding multiple class C blocks......advertise some larger aggregate, e.g. /20 The Internet CIDR report: http://www.cidr-report.org
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TDC375 Autumn 03/04 John Kristoff - DePaul University 1 CIDR example Given an ISP that announces: 64.5.0.0/20 64.5.16.0/20 192.0.2.0/25 192.0.2.192/26 192.0.2.128/26 What is the least number of CIDR announcements that can be made for this ISP? Why might address blocks not be aggregated?
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TDC375 Autumn 03/04 John Kristoff - DePaul University 1 VLSM Many subnet sizes in an autonomous system (AS) Allows for efficient use of address space Can be used to build an internal hierarchy External view of the AS does not change An AS may be allocated 140.192.0.0/16, but... internally may use: 140.192.0.0/17 140.192.128.0/24 140.192.129.0/25 and so on...
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TDC375 Autumn 03/04 John Kristoff - DePaul University 1 VLSM example Given an assignment of 140.192.0.0/16, create an addressing strategy to support: 6 satellite offices and 1 large headquarter site 6000 total hosts on all combined networks headquarters needs about 50% of all addresses satellite offices need 200 to 700 addresses overall growth per year is 500 hosts
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TDC375 Autumn 03/04 John Kristoff - DePaul University 1 Obtaining IP addresses IANA has global authority for assignment Regional registries delegate to ISPs and large nets ISPs assign addresses to end users RFC 1918 defines private address blocks NOT globally unique NOT for hosts attached directly to public Internet 10.0.0.0/8, 172.16.0.0/12 and 192.168.0.0/16 You will understand RFC 1918 consequences
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TDC375 Autumn 03/04 John Kristoff - DePaul University 1 IP datagram layout
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TDC375 Autumn 03/04 John Kristoff - DePaul University 1 Inside an IP datagram Version field usually set to binary 0100 (is what decimal?) Header length length of IP header in 32-bit words typically set to 5 (as in 5 octets) Type of Service (redefined in newer RFCs) an indication of quality/class of service rarely used with success outside a single AS
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TDC375 Autumn 03/04 John Kristoff - DePaul University 1 Inside an IP datagram [cont.] Total length total IP datagram length in octets maximum value is 65535, but rarely > 1500 Identification to identify fragments of a single IP datagram experimentally used in tracing DDoS sources Flags bit 0 reserved, others for fragmentation (or not)
![TDC375 Autumn 03/04 John Kristoff - DePaul University 1 Inside an IP datagram [cont.] Total length total IP datagram length in octets maximum value is 65535, but rarely > 1500 Identification to identify fragments of a single IP datagram experimentally used in tracing DDoS sources Flags bit 0 reserved, others for fragmentation (or not)](http://images.slideplayer.com./16/5131444/slides/slide_29.jpg "TDC375 Autumn 03/04 John Kristoff - DePaul University 1 Inside an IP datagram [cont.] Total length total IP datagram length in octets maximum value is 65535, but rarely > 1500 Identification to identify fragments of a single IP datagram experimentally used in tracing DDoS sources Flags bit 0 reserved, others for fragmentation (or not)")
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TDC375 Autumn 03/04 John Kristoff - DePaul University 1 Inside an IP datagram [cont.] Fragment offset helps piece together IP fragments Time to live (TTL) limts the time/hops of datagram in the net counts down to zero, at zero it is discarded Protocol type indicates next layer protocol in payload
![TDC375 Autumn 03/04 John Kristoff - DePaul University 1 Inside an IP datagram [cont.] Fragment offset helps piece together IP fragments Time to live (TTL) limts the time/hops of datagram in the net counts down to zero, at zero it is discarded Protocol type indicates next layer protocol in payload](http://images.slideplayer.com./16/5131444/slides/slide_30.jpg "TDC375 Autumn 03/04 John Kristoff - DePaul University 1 Inside an IP datagram [cont.] Fragment offset helps piece together IP fragments Time to live (TTL) limts the time/hops of datagram in the net counts down to zero, at zero it is discarded Protocol type indicates next layer protocol in payload")
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TDC375 Autumn 03/04 John Kristoff - DePaul University 1 Inside an IP datagram [cont.] Header checksum used to verify header validity at each hop Source/Destination address 32-bit IP address Options (optional) rarely used, padded to 32-bit boundary if needed Payload variable length
![TDC375 Autumn 03/04 John Kristoff - DePaul University 1 Inside an IP datagram [cont.] Header checksum used to verify header validity at each hop Source/Destination address 32-bit IP address Options (optional) rarely used, padded to 32-bit boundary if needed Payload variable length](http://images.slideplayer.com./16/5131444/slides/slide_31.jpg "TDC375 Autumn 03/04 John Kristoff - DePaul University 1 Inside an IP datagram [cont.] Header checksum used to verify header validity at each hop Source/Destination address 32-bit IP address Options (optional) rarely used, padded to 32-bit boundary if needed Payload variable length")
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TDC375 Autumn 03/04 John Kristoff - DePaul University 1 Basic tools ping traceroute arp route netstat packet capture tcpdump, ethereal routing table monitors, looking glass servers
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TDC375 Autumn 03/04 John Kristoff - DePaul University 1 Final thoughts IP is unreliable, connectionless IP addressing is a pain, wait til you see IPv6 IP addresses today are both a who and a where IP addresses make for poor trust relationships IP fragmentation is generally best avoided Private IPs and NATs, yuck!
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