1

Review of Important Networking Concepts

Introductory material.

This module uses the example from the previous module to review important networking concepts: protocol architecture, protocol layers, encapsulation, demultiplexing, network abstractions.

2

Networking Concepts

• Layered Architecture to reduce complexity– Encapsulation– Abstractions

3

neon.tcpip-lab.edu"Neon"

128.143.71.21

argon.tcpip-lab.edu"Argon"128.143.137.144

router137.tcpip-lab.edu"Router137"

128.143.137.1

router71.tcpip-lab.edu"Router71"128.143.71.1

Ethernet NetworkEthernet Network

Router

Sending a packet from Argon to Neon

4

DNS: The IP address of

“neon.tcpip-lab.edu” is 128.143.71.21

ARP: What is the MAC address of 128.143.137.1?

neon.tcpip-lab.edu"Neon"

128.143.71.21

argon.tcpip-lab.edu"Argon"128.143.137.144

router137.tcpip-lab.edu"Router137"

128.143.137.1

router71.tcpip-lab.edu"Router71"128.143.71.1

Ethernet NetworkEthernet Network

Router

Sending a packet from Argon to Neon

DNS: What is the IP address

of “neon.tcpip-lab.edu”?ARP: The MAC address of 128.143.137.1 is 00:e0:f9:23:a8:20

128.143.71.21 is not on my local network.Therefore, I need to send the packet to my

default gateway with address 128.143.137.1

frame

128.143.71.21 is on my local network.Therefore, I can send the packet directly.

ARP: The MAC address of 128.143.137.1 is 00:20:af:03:98:28

ARP: What is the MAC address of 128.143.71.21?

frame

5

What’s a protocol?

human protocols:• “what’s the time?”• “I have a question”• introductions

… specific msgs sent

… specific actions taken when msgs received, or other events

network protocols:• machines rather than

humans• all communication activity in

Internet governed by protocols

protocols define format, order of msgs sent and received among

network entities, and actions taken on msg transmission,

receipt

6

What’s a protocol?

a human protocol and a computer network protocol:

Q: Other human protocols?

Hi

Hi

Got thetime?

2:00

TCP connection req

TCP connectionresponseGet http://www.awl.com/kurose-ross

<file>time

7

Communications Architecture

• The complexity of the communication task is reduced by using multiple protocol layers:

• Each protocol is implemented independently• Each protocol is responsible for a specific subtask• Protocols are grouped in a hierarchy

• A structured set of protocols is called a communications architecture or protocol suite

8

TCP/IP Protocol Suite

• The TCP/IP protocol suite is the protocol architecture of the Internet

• The TCP/IP suite has four layers: Application, Transport, Network, and Data Link Layer

• End systems (hosts) implement all four layers. Gateways (Routers) only have the bottom two layers.

Application

Transport

Network Operating system

User-level programs

Data Link

Data Link

Media AccessControl (MAC)

Sublayer inLocal AreaNetworks

9

Functions of the Layers

• Data Link Layer:– Service: Reliable transfer of frames over a link

Media Access Control on a LAN– Functions: Framing, media access control, error checking

• Network Layer:– Service: Move packets from source host to destination host– Functions: Routing, addressing

• Transport Layer:– Service: Delivery of data between hosts– Functions: Connection establishment/termination, error

control, flow control• Application Layer:

– Service: Application specific (delivery of email, retrieval of HTML documents, reliable transfer of file)

– Functions: Application specific

10

TCP/IP Suite and OSI Reference Model

ApplicationLayer

ApplicationLayer

PresentationLayer

SessionLayer

TransportLayer

NetworkLayer

(Data) LinkLayer

PhysicalLayer

TransportLayer

NetworkLayer

OSIReference

Model

(Data) LinkLayer

TCP/IP Suite

The TCP/IP protocol stack does not define the lower layers of a complete protocol stack

11

Assignment of Protocols to Layers

NetworkLayer

Routing Protocols

PIM

OSPF

RIP

ApplicationLayer

Data LinkLayer

IP

ARP Ethernet

NetworkInterface

TransportLayer

TCP UDP

SNMPFTP DNSHTTP

ICMP

IGMP

pingapplication Telnet

DHCP

12

Layered Communications

• An entity of a particular layer can only communicate with:

1. a peer layer entity using a common protocol (Peer Protocol)

2. adjacent layers to provide services and to receive services

N+1 LayerEntity

N+1 LayerEntity

N+1 Layer ProtocolN+1 Layer

N-1 LayerEntity

N-1 LayerEntity

N-1 Layer ProtocolN-1 Layer

N LayerEntity

N LayerEntity

N Layer ProtocolN Layer

layer N+1/Ninterface

layer N/N-1interface

13

Service Primitives

N+1 LayerEntity

N+1 LayerEntity

N LayerEntity

N LayerEntity

N+1 Layer Peer Protocol

Request Delivery

IndicateDelivery

Communication services are invoked via function calls. The functions are called service primitives

14

Service Primitives

Recall: A layer N+1 entity sees the lower layers only as a service provider

Service Provider

N+1 LayerEntity

N+1 LayerEntity

N+1 Layer Peer Protocol

Request Delivery

IndicateDelivery

15

Layers in the Example

HTTP

TCP

IP

argon.tcpip-lab.edu

128.143.137.144

Ethernet Ethernet Ethernet

IP

HTTP

TCP

IP

neon.tcpip-lab.edu128.143.71.21

Ethernet

router71.tcpip-lab.edu

128.143.137.100:e0:f9:23:a8:20

router137.tcpip-lab.edu

128.143.71.1

HTTP protocol

TCP protocol

IP protocol

Ethernet

IP protocol

Ethernet

16

Layers in the Example

HTTP

TCP

IP

argon.tcpip-lab.edu

128.143.137.144

Ethernet Ethernet Ethernet

IP

HTTP

TCP

IP

neon.tcpip-lab.edu128.143.71.21

Ethernet

router71.tcpip-lab.edu

128.143.137.100:e0:f9:23:a8:20

router137.tcpip-lab.edu128.143.71.1

Send HTTP Request to neon

Establish a connection to 128.143.71.21 at port 80Open TCP connection to

128.143.71.21 port 80

Send a datagram (which contains a connection request) to 128.143.71.21Send IP datagram to

128.143.71.21

Send the datagram to 128.143.137.1

Send Ethernet frame to 00:e0:f9:23:a8:20

Send Ethernet frame to 00:20:af:03:98:28

Send IP data-gram to 128.143.71.21

Send the datagram to 128.143.7.21

Frame is an IP datagram

Frame is an IP datagram

IP datagram is a TCP segment for port 80

17

Layers and Services

• Service provided by TCP to HTTP:– reliable transmission of byte streams over a logical

connection• Service provided by IP to TCP:

– unreliable transmission of IP datagrams across an IP network

• Service provided by Ethernet to IP:– transmission of a frame across an Ethernet segment

• Other services:– DNS: translation between domain names and IP addresses– ARP: Translation between IP addresses and MAC addresses

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Encapsulation and Demultiplexing

• As data is moving down the protocol stack, each protocol is adding layer-specific control information

HTTP

TCP

IP

Ethernet

User data

User dataHTTP Header

TCP Header

TCP HeaderIP Header

TCP HeaderIP HeaderEthernetHeader

EthernetTrailer

IP datagram

TCP segment

Ethernet frame

User dataHTTP Header

User dataHTTP Header

User dataHTTP Header

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Encapsulation and Demultiplexing in our Example

• Let us look in detail at the Ethernet frame between Argon and the Router, which contains the TCP connection request to Neon.

• This is the frame in hexadecimal notation.

00e0 f923 a820 00a0 2471 e444 0800 4500 002c 9d08 4000 8006 8bff 808f 8990 808f 4715 065b 0050 0009 465b 0000 0000 6002 2000 598e 0000 0204 05b4

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Encapsulation and Demultiplexing

Application dataTCP HeaderIP HeaderEthernet Header Ethernet Trailer

Ethernet frame

destination address

source address

type

6 bytes

CRC

4 bytes

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00:e0:f9:23:a8:20

0:a0:24:71:e4:44

0x0800

6 bytes

CRC

4 bytes

Encapsulation and Demultiplexing: Ethernet Header

Application dataTCP HeaderIP HeaderEthernet Header Ethernet Trailer

Ethernet frame

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Encapsulation and Demultiplexing: IP Header

Application dataTCP HeaderEthernet Header Ethernet Trailer

Ethernet frame

IP Header

DS ECNversion(4 bits)

headerlength

Total Length (in bytes)(16 bits)

Identification (16 bits)flags

(3 bits)Fragment Offset (13 bits)

Source IP address (32 bits)

Destination IP address (32 bits)

TTL Time-to-Live(8 bits)

Protocol(8 bits)

Header Checksum (16 bits)

32 bits

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Encapsulation and Demultiplexing: IP Header

Application dataTCP HeaderEthernet Header Ethernet Trailer

Ethernet frame

IP Header

0x0 0x00x4 0x5 4410

9d08 0102 00000000000002

128.143.137.144

128.143.71.21

12810 0x06 8bff

32 bits

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Encapsulation and Demultiplexing: TCP Header

Application dataEthernet Header Ethernet Trailer

Ethernet frame

IP Header TCP Header

Sequence number (32 bits)

Source Port Number Destination Port Number

Acknowledgement number (32 bits)

window sizeheaderlength

0 Flags

TCP checksum urgent pointer

32 bits

length Max. segment sizeoptiontype Option:

maximum segment size

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Encapsulation and Demultiplexing: TCP Header

Application dataEthernet Header Ethernet Trailer

Ethernet frame

IP Header TCP Header

60783510

162710 8010

010

819210610 0000002 0000102

0x598e 00002

32 bits

410 146010210

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Encapsulation and Demultiplexing: Application data

Application dataEthernet Header Ethernet Trailer

Ethernet frame

IP Header TCP Header

27

Different Views of Networking

• Different Layers of the protocol stack have a different view of the network. This is HTTP’s and TCP’s view of the network.

HTTP client

TCP client

Argon128.143.137.144

HTTPserver

TCP server

Neon128.143.71.21

IP Network

HTTPserver

TCP server

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Network View of IP Protocol

128.143.71.21128.143.137.144

Router

128.143.137.0/24Network

128.143.137.1 128.143.71.1

128.143.71.0/24Network

29

Network View of Ethernet

• Ethernet’s view of the network

Argon(128.143.137.144)

Router137(128.143.137.1)

Ethernet Network

30

The Evolution of Internet

Introductory material.

An overview lecture that covers Internet related topics, including a definition of the Internet, an overview of its history and growth, and standardization and naming.

31

A Definition

• On October 24, 1995, the FNC unanimously passed a resolution defining the term Internet.

•RESOLUTION: The Federal Networking Council (FNC) agrees that the following language reflects our definition of the term "Internet". "Internet" refers to the global information system that --

•(i) is logically linked together by a globally unique address space based on the Internet Protocol (IP) or its subsequent extensions/follow-ons;

•(ii) is able to support communications using the Transmission Control Protocol/Internet Protocol (TCP/IP) suite or its subsequent extensions/follow-ons, and/or other IP-compatible protocols; and

•(iii) provides, uses or makes accessible, either publicly or privately, high level services layered on the communications and related infrastructure described herein.

32

Internet History

• 1961: Kleinrock - queueing theory shows effectiveness of packet-switching

• 1964: Baran - packet-switching in military nets

• 1967: ARPAnet conceived by Advanced Research Projects Agency

• 1969: first ARPAnet node operational

• 1972: – ARPAnet demonstrated

publicly– NCP (Network Control

Protocol) first host-host protocol

– first e-mail program– ARPAnet has 15 nodes

1961-1972: Early packet-switching principles

33

Internet History

• 1970: ALOHAnet satellite network in Hawaii

• 1973: Metcalfe’s PhD thesis proposes Ethernet

• 1974: Cerf and Kahn - architecture for interconnecting networks

• late70’s: proprietary architectures: DECnet, SNA, XNA

• late 70’s: switching fixed length packets (ATM precursor)

• 1979: ARPAnet has 200 nodes

Cerf and Kahn’s internetworking principles:

– minimalism, autonomy - no internal changes required to interconnect networks

– best effort service model– stateless routers– decentralized control

define today’s Internet architecture

1972-1980: Internetworking, new and proprietary nets

34

Internet History

• Early 1990’s: ARPAnet decommissioned

• 1991: NSF lifts restrictions on commercial use of NSFnet (decommissioned, 1995)

• early 1990s: Web

– hypertext [Bush 1945, Nelson 1960’s]

– HTML, HTTP: Berners-Lee– 1994: Mosaic, later Netscape– late 1990’s: commercialization

of the Web

Late 1990’s – 2000’s:• more killer apps: instant

messaging, P2P file sharing

• network security to forefront

• est. 50 million host, 100 million+ users

• backbone links running at Gbps

1990, 2000’s: commercialization, the Web, new apps

35

Applications of the Internet

• Traditional core applications:EmailNewsRemote LoginFile Transfer

• The killer application:World-Wide Web (WWW), P2P

• Future applications:Videoconferencing and TelephonyMultimedia ServicesInternet Broadcast

36

Growth of the Internet

Source: Internet Software Consortium

37

Internet Infrastructure

local ISP

campusnetwork

corporatenetwork

IXP

RegionalNetwork

RegionalNetwork

local ISP

local ISP

IXP

IXP

Backbone Network

Backbone Network

RegionalNetwork

RegionalNetwork

38

Internet Infrastructure

• The infrastructure of the Internet consists of a federation of connected networks that are each independently managed (“autonomous system”)– Note: Each “autononmous system may consist of multiple

IP networks• Hierarchy of network service providers

– Tier-1: nation or worldwide network (US: less than 20)– Tier-2: regional networks (in US: less than 100)– Tier-3: local Internet service provider (in US: several

thousand)

39

Internet Infrastructure

• Location where a network (ISP, corporate network, or regional network) gets access to the Internet is called a Point-of-Presence (POP).

• Locations (Tier-1 or Tier-2) networks are connected for the purpose of exchanging traffic are called peering points.– Public peering: Traffic is swapped in a specific location,

called Internet exchange points (IXPs)– Private peering: Two networks establish a direct link to

each other.

40

Tier-1 ISP: e.g., Sprint

Sprint US backbone network

41

Who is Who on the Internet ?

• Internet Society (ISOC): Founded in 1992, an international nonprofit professional organization that provides administrative support for the Internet. Founded in 1992, ISOC is the organizational home for the standardization bodies of the Internet.

• Internet Engineering Task Force (IETF): Forum that coordinates the development of new protocols and standards. Organized into working groups that are each devoted to a specific topic or protocol. Working groups document their work in reports, called Request For Comments (RFCs).

• IRTF (Internet Research Task Force): The Internet Research Task Force is a composed of a number of focused, long-term and small Research Groups.

• Internet Architecture Board (IAB): a technical advisory group of the Internet Society, provides oversight of the architecture for the protocols and the standardization process

• The Internet Engineering Steering Group (IESG): The IESG is responsible for technical management of IETF activities and the Internet standards process. Standards. Composed of the Area Directors of the IETF working groups.

42

Internet Standardization Process

• Working groups present their work i of the Internet are published as RFC (Request for Comments).

• RFCs are the basis for Internet standards.• Not all RFCs become Internet Standards ! (There are >3000

RFCs and less than 70 Internet standards• A typical (but not only) way of standardization is:

– Internet Drafts– RFC– Proposed Standard – Draft Standard (requires 2 working implementation)– Internet Standard (declared by IAB)

43

Assigning Identifiers for the Internet

• Who gives University the domain name “tcpip-lab.edu” and who assigns it the network prefix “128.143.0.0/16”? Who assigns port 80 as the default port for web servers?

• The functions associated with the assignment of numbers is referred to as Internet Assigned Number Authority (IANA).

• Early days of the Internet: IANA functions are administered by a single person (Jon Postel).

Today: • Internet Corporation for Assigned Names and Numbers (ICANN)

assumes the responsibility for the assignment of technical protocol parameters, allocation of the IP address space, management of the domain name system, and others.

• Management of IP address done by Regional Internet Registries (RIRs):– APNIC (Asia Pacific Network Information Centre) – RIPE NCC (Réseaux IP Européens Network Coordination Centre) – ARIN (American Registry for Internet Numbers)

Domain names are administered by a large number of private organizations that are accredited by ICANN.

44

Summary

• Layered Internet architecture– Reduce complexity– Higher layer views lower layer as service provider– Application layer, transport layer, network layer, and link

layer