Title: Computer Networks
1Computer Networks
- Habib Youssef, Ph.D.
- youssef_at_ccse.kfupm.edu.sa
- Department of Computer Engineering
- King Fahd University of Petroleum and Minerals
- Dhahran, Saudi Arabia
February 17 - 21, 2001
2Course Schedule
- Saturday
- Introduction to Computer Networking
- Network Evolution
- Basic Terminology Concepts
- Network computing model
- OSI Layered Network architecture
- LAN and WAN standards
3Course Schedule (contd.)
- Sunday
- Data communications concepts
- Connection Services
- Public telephone Network
- ADSL
- X.25, Frame Relay, ISDN, B-ISDN, ATM
- Network Hardware
- Internetworking
- Structured Corporate Networking
4Course Schedule (contd.)
- Monday
- TCP/IP
- Network Security
- Tuesday
- Windows 98, NT and 2000
- Network Management
5Course Schedule (contd.)
- Wednesday
- Internet Services
- Electronic Commerce
- Lunch and Distribution of certificates
6 7Historical glimpses
- The past several decades have witnessed a
phenomenal growth in the computer industry - As computer proliferated, so did the need for
data communication - People became more and more interested in
connecting several computers together. - Computer Network
- Interconnected collection of autonomous computers
and computer resources
8Historical glimpses (contd.)
- Late 1960s -- ARPA (later became DARPA) began a
partnership with 45 universities and research
institutions to investigate Data Communication
Technologies. - 1969 -- ARPANET went into operation with 4 nodes.
- The experiment was a success and ARPANET grew
into a network spanning the entire USA. - 1974 -- Birth of the first LAN (Xerox)
-
9Historical glimpses (contd.)
- In early years of networking, each computer
manufacturer developed its own communication
solution - Structured Network Architecture (SNA) of IBM
- DEC Network Architecture (DNA) of DEC
- ARPANET of ARPA
- etc.
-
10Historical glimpses (contd.)
- 1977 -- ISO established a subcommittee to develop
an architecture/structure that defines
communication tasks and which would - Serve as a reference model for international
standards - would facilitate efficient internetworking among
systems from different technologies,
manufacturers, administrations, nationalities,
and enterprises. -
11Historical glimpses (contd.)
- 1978 -- Meeting of 40 experts in Washington, D.
C. started work that yielded 6 years later the
OSI Reference Model. - Paper by Louis Pouzin and Hubert Zimmermann,
Proc. Of the IEEE November 1978, pp. 1346 - 1370. - 1975 -- ARPANET transitioned to Defense
commercial agency. - 1978-80 -- ARPANET protocol were upgraded with
TCP/IP. - Paper by Cerf and Khann, IEEE Trans. Comm., May
1974. -
12Historical glimpses (contd.)
- February 1980 -- The IEEE started Project 802 to
develop standards for the LAN market. - 1981 -- A new host added to ARPANET every 20
days. - 1983 -- TCP/IP switchover complete.
- TCP/IP adopted as standard by DOD
- ARPANET had over 300 hosts.
- Over 1200 nodes by 1985.
- ARPANET split
- ARPANET Academic (Educational, Research)
- MILNET Military
-
13Historical glimpses (contd.)
- 1984 -- The OSI-RM came out.
- Defines a strategic outline/vision
- Reduces degrees of freedom of standards
developers - Centered around the hierarchical decomposition of
communication functions - 1986 -- NSFnet backbone created.
- 1990 -- ARPANET put to rest
- 1987 -- over 25000 nodes
- 1989 -- 3000 networks for over 200000 users
-
14Historical glimpses (contd.)
- 1991-- WWW invented Gopher introduced
- 1995
- Internet backbone privatized
- Over 7 million networks around the world
- 150000 users join the network every month
- July, 1998 -- over 36 million networks
- Jan, 1999 -- 157 million users
- Projected to be 327 million by year 2000
-
15Historical glimpses (contd.)
- The Internet is an Information Highway
- Dedicated communication links (copper, fiber,
satellite) functioning as the concrete/asphalt - Usually T/E leased lines serve as the on-ramp
connecting to regional networks - Capacity of T1 highways is 1.544 Mbps
- that of T3 is 45 Mbps
- The Internet is becoming a platform for most
computer needs. -
16 171960s and 1970s Communications
- Centered around the host (mainframe).
- On a single computer, accessing resources,
running programs, and copying files are
relatively straightforward.
B
A
Unintelligent terminal
Unintelligent terminal
Low speed links
Value-added networks
181960s and 1970s Communications (contd.)
- Even on a system of only two computers,
coordinating resources becomes much more complex.
- Transferring information requires, among other
things, addressing, error detection, error
correction, synchronization, and transmission
coordination.
B
A
Unintelligent terminal
Unintelligent terminal
Low speed links
Value-added networks
191970s and 1980s Networks
- The introduction of PCs revolutionized computer
communication and networking - LANs evolved to share resources (Disks, Printers)
- Minicomputers and shared WANs evolved
- Facilitated the emergence of distributed
processing - Applications remained separate and independent,
and different communication protocols were
developed
Token Ring
201980s and 1990s Internetworks
Token -Ring
Private nets and Internet
FDDI
211980s and 1990s Internetworks
- Most of todays networks are a mixture of old
and new technologies. -
- The approach to computer communication in most
organizations is changing rapidly in response to
new technologies, evolving business requirements,
and the need for more bandwidth and instant
knowledge transfer. - Internetworks tie LANs and WANs, computer
systems, software, and related devices together
to form the corporate communication
infrastructure.
221990s Global Internetworking
231990s Global Internetworking
- Studies show that users increasingly require more
bandwidth. - Networks will have to meet these demands and
provide low delay, bandwidth on demand, and other
new services. - Such networks are characterized by the following
- increasing use of graphics and imaging
- larger files and larger programs
- client/server computing
- bursty network traffic
- Global internetworking will provide an
environment for emerging applications that will
require even greater amounts of bandwidth.
24- Basic Networking concepts
25Simple Data Communication Model
001101
Analog/Digital
Digital
Transceiver
Transport System
Transceiver
Data Network
Digital
Public Telephone Network
001101
26Terminology
- Networks are classified on the basis of
geographic span. - Local Area Networks (LANs)
- Metropolitan Area Networks (MANs)
- Wide Area Networks (WANs)
- The difference in geographical extent between
WANs and LANs account for significant
differences in their respective design issues.
27LAN Characteristics
- LANs are designed to
- Operate within a limited geographic area
- Allow multiaccess to high-bandwidth media
- Control the network privately under local
administration - Provide full-time connectivity to local services
- Connect physically adjacent devices
28LAN Characteristics
- All nodes are connected by a single high speed
shared channel. - Data is packetized and packets are carried past
all nodes in the network. - Addressing is required but routing is not needed.
- Congestion control and network architecture are
among design issues. - Several topologies can be used but the choice of
topology is not a major issue.
29LAN Topologies
30LAN Topologies (Contd.)
31LAN Topologies (Contd.)
32LAN Topologies (Contd.)
- Hierarchical/Inverse Tree.
- Higher power at higher levels.
33LAN Components
- A LAN has the following basic components
- Transmission Medium
- Cable or Cable-less. It connects the various
stations. E.g. twisted pair, coaxial cable, CATV
cable, fiber optics, radio waves. - Stations
- Intelligent workstations which attach to the
medium. E.g. PC or workstation.
34LAN Components (Cont.)
- Non-intelligent which attach to a station. E.g.
Printers, Modems, Hard disks, etc. - File server
- The main unit in the network that offers various
services to the network users. - It refers to a computer, its hard disk, its
network operating system, and the file server
software that manages the network resources.
35LAN Components (Cont.)
- Network Interface Card (NIC)
- Network adapter to send and receive messages. It
is a circuit board with the components necessary
for handling communication tasks - The NIC is plugged onto one of the available
slots on the PC expansion bus. - Installed in each workstation and file server
such as Ethernet NIC.
36LAN Components (Cont.)
- Network Operating System (NOS)
- Installed on the hard disk of the file sever
station. Its function is to control the access to
the common shared resources, such as printers,
hard disks, database applications, etc. - Workstation Operating System
- Consists of a network shell installed on any one
of the popular operating systems such as DOS,
Unix, Linux, MAC-OS, etc.
37Anatomy of a LAN node
Application level API
Application
Protocol API
Operating
Kernel level API
System
Network protocol
Driver Specification
Kernel level API
NIC Driver
Hardware Interface
Receive
Ethernet NIC
Transmit
Hub
38LAN Characteristics
- What distinguishes one LAN from another
- Transmission Medium
- Twisted pair, Coax, CATV, Fiber Optic, or
Wireless. - Topology Star, Bus, Ring
- Transmission method Base/Broadband
- Medium Access Technique
- Random Access (CSMA/CD)
- Controlled Access (Token Passing)
39LAN Characteristics (Cont.)
- Others
- Type (Peer-to-Peer or Server-based)
- Speed
- in bits per second (bps)
- Span
- distance between end stations
- Load
- number of stations.
40Server-Based LANs
- Server-based A server-based network consists of
a group of user-oriented PCs called clients that
request and receive network services from
specialized computers called servers.
41Peer-to-Peer LANs
- Peer-to-peer A peer-to-peer network is a group
of user-oriented PCs that basically operate as
equals. Each PC is called a peer. The peers share
resources, such as files and printers, but no
specialized servers exists. Each peer is
responsible for its own security, and, in a
sense, each peer is both a client and a server.
42Peer-to-Peer Networking (Workgroup)
- Resources are distributed throughout the network
on computer systems that may act as both service
requesters and service providers. - The user of each PC is responsible for the
administration and sharing of resources for his
PC. - Ideal for small organizations where security is
not of concern.
43Resources for Peer-to-Peer Network
- Personal computers.
- Network Operating System
- Ex Windows 98/ NT/ 2000, Linux, Unix.
- Network Interface Card (NIC) the driver of the
NIC. - Network cables.
- Hubs (in case twisted-pair cables are used).
44Client Server Model
- Client-Server paradigm is the primary pattern of
interactions among cooperating applications. - This model constitutes the foundation on which
distributed algorithms are built.
45What is the Client-Server Paradigm?
- The paradigm divides communicating applications
into 2 broad categories, depending on whether the
application waits for communication or initiates
it. - An application that initiates a communication is
called a client. - End users usually invoke a client software when
they use a network service.
46Client Server Model (cont.)
- Server Any program that offers a service
reachable over the network - If a machines primary purpose is to support a
particular server program, the term server is
usually applied to both, the machine and the
server program - Client An executing program becomes a client
when it sends a request to a server and waits for
a response
47Client Server Model (cont.)
- A server is any program that waits for incoming
communication requests from a client. - Each time a client application needs to contact a
server, it sends a request and awaits a response. - The server receives a clients request, performs
the necessary computation, and returns the result
to the client. - When the response arrives at the client, the
client continues processing.
48Client Server Model (cont.)
Machine Running Client Application
Machine Running Server Application
Request
Server Program
Client Program
Reply
49Client Server Model (cont.)
- A Misconception
- Technically, a server is a program and not a
piece of hardware. - However, computer users frequently (mis)apply the
term to the computer responsible for running a
particular server program. - For example, Web Server, is usually a computer
running the http server program.
50WANs
- To make optimum use of expensive communication
links, WANs are structured with irregular
placement of the nodes. Store-and-Forward packet
switching is used to deliver packets to their
destination.
51Wide-Area Networks and Devices
- WANs are designed to
- Allow access over serial interfaces operating at
lower speeds - Control the network subject to regulated public
services - Connect devices separated over wide, even global
areas
52WANs
S
D
Design Issues
Capacity assignment
Network topology
Routing algorithm
Congestion control
Network architecture
53Enterprise Developments
- The enterprise is a corporation, agency, service,
or other organization that will tie together its
data, communication, computing, and storage
resources. - Developments on the enterprise network include
- LANs interconnected to provide client/server
applications integrated with the traditional
legacy applications from mainframe data centers - End-user needs for higher bandwidth on the LAN,
which can be consolidated at a switch and
delivered on dedicated media - Integration of formerly separate networks so that
the non-bursty traffic from voice and video
applications coexist on a single network - Relaying technologies for WAN service, with very
rapid growth in Frame Relay and cell relay (ATM)
54 55Communication Protocols
- To provide error-free and maximally convenient
information transfers, the network communication
is regulated by a set of rules and conventions
called network protocols. - Protocols define connectors, cables, signals,
data formats, error control techniques, and
algorithms for message preparation, analysis and
transfer.
56Communication Protocols (Contd.)
- Network Protocol
- A set of rules defining the syntax (form) and
semantics (meaning) in order to regulate
communication between network nodes. - Protocols can be implemented in either hardware
or software - The EIA-232-D is a physical layer protocol
implemented in hardware. - TCP/IP are implemented in software.
57Protocol Data Units (PDU)
- Each PDU must contain two major parts
- Header
- Identifies how the following parts are to be
handled and routed. - Message
- This is the message body itself.
- This is where the protocol is determined to be
character oriented or bit oriented.
58Communication Standards
- The goal of the ISO subcommittee developing the
OSI model was to provide a framework for network
standards acceptable to all manufacturers
59ISO OSI Reference Architecture
- The architecture is layered to reduce complexity.
- Each layer offers certain services to the layer
immediately above it. - Each layer shields the higher layer from the
details of implementation of how the services are
offered. - Layer "n" on one station carries on a
conversation with layer "n" on another network
station.
60OSI Reference Model
- The ISO OSI Layered Model
- Application File transfer, mail, rlogin, etc.
- Presentation Data formatting.
- Session Negotiation and connection.
- Transport End-to-end delivery.
- Network Routing of packets.
- Data link Transfer of frames.
- Physical Cabling system.
61Why a Layered Model
- 7 Application
- 6 Presentation
- 5 Session
- 4 Transport
- 3 Network
- 2 Datalink
- 1 Physical
- Reduces complexity
- Standardizes interfaces
- Facilitates modular engineering
- Ensures interoperable technology
- Accelerates evolution
- Simplifies teaching and learning
62Layer Functions
- 7 Application Network processes to
applications - 6 Presentation Data representation
- 5 Session Inter-host
communication - 4 Transport End-to-end connections
- 3 Network Addresses and best path
- 2 Datalink Access to media
- 1 Physical Binary transmission
63Layer Functions
- Application Application
- Presentation Presentation
- Session Session
- Transport Transport
- Network Network
- Datalink Datalink
- Physical Physical
segments
packets
frames
bits
Host A Host B
64Data Encapsulation
- Application Application
- Presentation Presentation
- Session Session
- Transport Transport
- Network Network
- Datalink Datalink
- Physical Physical
data
segment data header
network segment data header header
01001000111010
65Data Encapsulation Example
data
Data Segment Packet Frame Bits
segment data header
network segment
data header header
Frame Network Segment Data Frame
header header header
trailer
01111111010101101000100100010110101
66- Application,
- Presentation,
- and Session Layers
67Application Layer
- Computer Applications
- Word Processing
- Presentation Graphics
- Spreadsheet
- Database
- Design/Manufacturing
- Project Planning
- Others
- Network Applications
- Electronic mail
- File Transfer
- Remote Access
- Client/Server Process
- Information Location
- Network Management
- WWW
- Video-Conferencing
- Others
68Application Layer (cont.)
- Network Applications
- (For enterprise communication)
- Electronic mail
- File Transfer
- Remote Access
- Client/Server Process
- Information Location
- Network Management
- Others
- Internetwork Applications
- (Extend beyond the enterprise)
- Electronic Data Interchange
- World Wide Web
- E-mail Gateways
- Special-Interest Bulletin Boards
- Financial Transaction Services
- Internet Navigation Utilities
- Conferencing (Video, Voice, Data)
69Presentation Layer
- Text
- Data
- ASCII, EBCDIC
- Encrypted
- Sound
- Video
- MIDI (Musical Instrument Digital Interface)
- MPEG (Motion Picture Experts Group)
- QuickTime
70Presentation Layer
- Graphics
- Visual Images
- PICT(format to transfer QuickDraw graphics
between Macintosh or PowerPC programs) - TIFF (Tagged Image File Format)
- JPEG (Joint Photographic Experts Group)
- GIF
- Provides code formatting and conversion for
applications
71Session Layer
- Coordinates applications as they interact on
different hosts
Service Request
Service Reply
72Session Layer (contd.)
- Network File System (NFS)
- Allows trasnparent access to remote network
resources - Structured Query Language (SQL)
- Remote-Procedure Call (RPC)
- RPC procedures are built on clients and executed
on servers - X Window System
- Allows intelligent terminals to communicate with
remote UNIX machines - AppleTalk Session Protocol (ASP)
- Establishes and maintains sessions between an
AppleTalk client and server - DNA Session Control Protocol (SCP)
73 74Transport Layer Overview
- Segments upper-layer applications
- Establishes an end-to-end connection
- Sends segments from one end host to another
- Ensures end-to-end data reliability
75Segment Upper-Layer Applications
- Application Electronic
File Terminal - Presentation Mail Transfer
Session - Session
- Transport
- Transport segments share traffic stream
Application Data Application
Data port
port
76Establishes Connection
receiver
sender
synchronize
Negotiate connection
synchronize
Connection established
Data transfer (send segments)
77Establishes Connection
transmit
Buffer full process segments Buffer OK
not ready
ready
Resume Transmission
78Reliability with Windowing
- In the most basic form of reliable
connection-oriented transfer, data segments must
be delivered to the recipient in the same
sequence that they were transmitted. - Windowing is a method to control the amount of
information transferred end-to-end. Some
protocols measure information in terms of number
of packets
79Reliability with Windowing
- send 1 window size 1 receive
1 - Ack 2
- send 2
receive 2 -
Ack 3 - send 1 window size 3 receive 1
- send 2
receive 2 - send 3
receive 3 -
Ack 4 - send 4
80An Acknowledgement Technique
- Reliable delivery guarantees that a stream of
data sent from one machine will be delivered
through a functioning data link to another
machine without duplication or data loss.
Positive acknowledgement with retransmission is
one technique that guarantees reliable delivery
of data streams. - The sender keeps the record of each segment it
sends and waits for an acknowledgement. - The sender also starts a timer when it sends a
segment, and it retransmits a segment it the
timer expires before an acknowledgement arrives.
81An Acknowledgement Technique
- send 1
- send 2
- send 3
- Ack 4
- send 4
- send 5
- send 6
- Ack 5
- send 5
- Ack 7
-
X
82Transport to Network Layer
Routed packets
83Summary
- Presentation layer formats and converts network
application data to represent text, graphics,
images, video, and audio. - Session-layer functions coordinate communication
interactions between applications. - Reliable transport-layer functions include
- Multiplexing
- Connection synchronization
- Flow control
- Error recovery
- Reliability through windowing
84- Physical and
- Data Link Layers
85Physical and Data-Link Standards
- The data link layer provides data transport
across a physical link. To do so, the data link
layer handles physical addressing, network
topology, line discipline, error notification,
orderly delivery of frames , and optional flow
control. - The physical layer specifies the electrical,
mechanical, procedural, and functional
requirements for activating, maintaining, and
deactivating the physical link between end
systems. - These requirements and characteristics are
codified into standards.
86LAN Data-Link Sublayers
-
- Network LLC
- Data Link MAC
- Physical
Logical Link Control
Media Access Control
MAC Frame 802.2 LLC Packet or datagram
87LAN Data-Link Sublayers
- LLC refers upward to higher-layer software
functions. - MAC refers downward to lower-layer hardware
functions. - LAN protocols occupy the bottom two layers of OSI
reference model the physical layer and data link
layer. The IEEE 802 committee subdivided the data
link layer into two sublayers - The logical link control (LLC) sublayer
- The media access control (MAC) sublayer
88LAN Data-Link Sublayers
- The LLC sublayer provides for environments that
need connectionless or connection-oriented
services and the data link layer. - The MAC sublayer provides access to the LAN
medium in an orderly manner.
89LLC Sublayer Functions
- Enable upper layers to gain independence over LAN
media access. - Allow service access points (SAPs) from interface
sublayers to upper-layer functions. - Provide optional connection, flow control, and
sequencing services.
90Summary
- Internetworking evolved to support current and
future applications - The OSI reference model organizes network
functions into seven layers - Data flows from upper-level user applications to
lower-level bits transmitted over network media - Peer-to-peer functions use encapsulation and
de-encapsulation at layer interfaces - Most network manager tasks configure the lower
three layers
91 92HTTP and Web Browsing
Router
Request
Response
HTTP Client
HTTP Server
93HTTP and Web Browsing
- Request http//www.commm.utoronto.ca/infocom/inde
x.html - Event Message content
- 1.User selects document.
- 2. Network Software of client locates the server
- host and establishes a two-way connection.
- 3. HTTP client sends message requesting GET/INFOC
OM/INDEX.HTML http/1.0 - document.
- 4. HTTP daemon listening on TCP port 80
- interprets message.
- 5. HTTP daemon sends a result code and a
http/1.1 200 OK - description of the information that the
client Server Apache/1.2.5 FrontPage 3.0.4 - will receive. Content-Length 414
- Content-Type text/html
- 6. HTTP daemon reads the file and sends the
lthtmlgt lttitlegt - requested file through the TCP port. lttitlegt
IEEE Infocom pp The Future is now.. - 7. HTTP daemon disconnects the connection.
- 8. Text is displayed by client browser, which
- interprets the HTML format.
94Domain Name System (DNS)
- The DNS is a distributed database that resides in
multiple machines on the Internet and is used to
convert between names and network addresses. - The DNS protocol is used to manage the
communication between DNS clients and servers - The DNS clients are called resolvers.
- The programs that store the information about the
domain name space are called name servers.
95Name Servers
- The domain database is divided up into parts
called zones, which are distributed among various
name servers. - The name server that handles a particular zone is
said to have authority over that zone.
95
96Resolvers
- Resolvers are clients that access name servers,
and interface user programs to the DNS. - Programs running on a host that need information
from the domain name space use the resolver. - The resolver is located on the same host as the
program that requests the resolvers services.
96
97- A name server can be authoritative over multiple
zones as well. - A zone contains the domain names and data that a
domain contains, except for domain names and data
that are delegated elsewhere.
97
98kfupm zone
kfupm
ccse
itc
itc zone domain
ee
ri
ccse zone domain
kfupm domain
98
99.
. name server
query for address of www.kfupm.edu.sa
Name server
referral to sa name server
sa name server
sa
edu.sa name server
edu
address of www.kfupm.edu.sa
resolver query
answer
kfupm.edu.sa name server
kfupm
Resolver
99
100DNS Query and Response Example
- Steps to resolve the name www.commm.utoronto.ca
- Event Message content
- 1. Application requests name resolution.
- 2. Resolver composes query message. Header
OPCODESQUERY - Question QNAMEtesla.comm.toronto.edu.,
- QCLASSIN, QTYPEA
- 3. Resolver sends UDP datagram encapsulating
- the query message.
- 3. DNS server looks up address and
prepares Header OPCODESQUERY, RESPONSE, AA - a response message. Question
QNAMEtesla.comm.toronto.edu., - QCLASSIN, QTYPEA
- Answer tesla.comm.toronto.edu., 86400
- IN A 128.100.11.56
- 4. DNS sends UDP datagram encapsulating the
response message.
101Simple Mail Transfer Protocol (SMTP)
- A mail client application interacts with a local
SMTP sever to initiate the delivery of an email
message. - The user prepares an email message that includes
- Recipients email address,
- Subject line, and
- a body
- When the user clicks send, the mail application
- Prepares a file with above information and
additional information specifying format (e.g.
plain ASCII or MIME extensions to encode
non-ASCII data) - Resolve the name of the local SMTP server using
DNS - Then perform the following steps
102Steps in sending e-mail using SMTP
- Event Message content
- 1. The mail application establishes a TCP
connection - (port 25) to its local SMTP server
-
- 2. SMTP daemon issues the following message
to 220 tesla.com.utoronto.edu ESMTP - the client indicating its readiness to
receive mail. Sendmail 8.9.0/8.9.0 Thu, 2 Jul
2000 - 050759 0400 (DT)
- 3. Client sends a HELO message and identifies
itself. HELO bhaskara.com.utoronto.edu.ca - 4. SMTP daemon issues a 250 message, indicating
250 tesla.com.utoronto.edu Hello - the client may proceed. bhaskara.com
128.100.10.91, - pleased to meet you
- 5. Client sends senders address MAIL FROM
ltbanerjea_at_comm.utoronto.cagt - 6. If successful, SMTP daemon replies with a
250 ltbanerjea_at_comm.utoronto.cagt - 250 message. Sender ok
103Steps in sending e-mail using SMTP(contd.)
- Event Message content
- 7. Client sends recipients address. RCPT TO
alg_at_nal.utoronto.ca - 8. A 250 message is returned 250
ltbanerjea_at_comm.utoronto.cagt - Recipient ok
-
- 9. Client sends a DATA message requesting DATA
- permission to send the mail message.
- 10. Daemon sends a message giving the client 354
Enter mail, end with . on a line - permission to send. by itself
- 11. Client sends the actual text of the message
Hi, please . - 12. Daemon indicates that message is accepted
250 FAA00803 Message accepted for delivery - for delivery. A message ID is returned
-
- 13. Client indicates that the mail session is
over. QUIT - 14. Daemon confirms the end of the session 221
tesla.comm.toronto.edu - closing connection
104Conceptual Model of a Mail System
Alias database
TCP connection
Alias expansion and forwarding
Outgoing mail spool area
User sends mail
Client (background transfer)
for outgoing mail
User Inter- face
User reads mail
TCP connection
Server (to accept mail)
Mailboxes for incoming mail
for incoming mail
105Summary
- The examples clearly indicate that a protocol is
solely concerned with the interaction between two
peer processes, that is, the client and the
server. - Application layer protocols operate by using the
communication services provided by the TCP and
UDP protocols. - Actually, both TCP and UDP operate by using the
connectionless service of IP.