Hyung-Min Lee ©Networking Lab., 2001 Chapter 8 ARP and RARP.
Lower Layers Local Area Network Standards Point-to-Point Link Layer Protocols ARP and RARP
description
Transcript of Lower Layers Local Area Network Standards Point-to-Point Link Layer Protocols ARP and RARP
© Jörg Liebeherr (modified by M. Veeraraghavan)
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• Lower Layers
• Local Area Network Standards
• Point-to-Point Link Layer Protocols
• ARP and RARP
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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.
• In this lecture, we will review the data link layer and the MAC sublayer.
• Most of the material should be familiar from EL 536.
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Data Link Layer
• The main tasks of the data link layer are:• Transfer data from the network layer of one machine to
the network layer of another machine.• Convert the raw bit stream of the physical layer into
groups of bits (“frames”).• Perform flow control between sender and receiver.
NetworkLayer
Data LinkLayer
PhysicalLayer
NetworkLayer
Data LinkLayer
PhysicalLayer
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Types of Networks
• There are two types of communication networks:– Broadcast Networks: All stations share a single
communication channel. – Point-to-Point Networks: Pairs of hosts (or routers) are
directly connected.
• Typically, local area networks (LANs) are broadcast and wide area networks (WANs) are point-to-point.
Broadcast Network Point-to-Point Network
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Local Area Network
• Local area networks (LANs) typically connect computers within a building or a campus.
• Almost all LANs are broadcast networks.
• Typical topologies of LANs are bus or ring.
Bus LAN Ring LAN
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MAC and LLC
• In any broadcast network, the stations must ensure that only one station transmits at a time on the shared communication channel.
• The protocol that determines who can transmit on a broadcast channel is called Medium Access Control (MAC) protocol.
• The MAC protocol is implemented in the MAC sublayer which is the lower sublayer of the data link layer.
• The higher portion of the data link layer is often called Logical Link Control (LLC).
Logical LinkControl
Medium AccessControlD
ata
Link
Laye
r
to Physical Layer
to Network Layer
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IEEE 802 Standards
•IEEE 802 is a family of standards for LANs.
•The 802 defines the LLC and several MAC sublayers.
Higher Layers
802.1 Interface to Higher Layers
LLC
802.2 Logical Link Control
MAC
802.3 CSMA/CD (Ethernet)802.4 Token Bus802.5 Token Ring802.6 DQDB
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IEEE 802 LAN Standard
Higher
802.2
802.3
803.5
802.4
Data Link
Physical
OSI
Layers
Layer
Layer
Logical LinkControl
Medium AccessControl
802.6PhysicalLayer
IEEEReferenceModel
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•IEEE 802.2
•CSMA/CD
• L• L
• C• M
• A• C
• P• h
• y• s•
i• c• a•
l
•Unacknowledged connectionless service•Connection-oriented service•Acknowledged connectionless service
• I•E•
E•E•
• 8• 0
• 2• .•
3
•Broadband
•Unshielded•twisted pair:•1, 10 Mbps
•Optical•:Fiber•10 Mbps
•Token Bus
• I•E•
E•E•
• 8• 0
• 2• .•
4•Broadband•Coaxial:•1,5,10
•Carrierband•1,5,10
•Optical fiber•5,10,20
•Mbps
•Mbps
•Mbps
•Token Ring
• I•E•
E•E•
• 8• 0
• 2• .•
5
•Shielded •twisted•pair:•4, 16 Mbps
•Unshielded•twisted•pair:•4 Mbps
•coaxial:•10 Mbps
•FDDI
• F• D
• D• I
•Optical•fiber:•100•Mbps
•DQDB
• I•E•
E•E•
• 8• 0
• 2•.• 6
•Optical•fiber• or •coaxial•44.736•Mbps
IEEE 802 LAN Standard
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Functions of the LLC
• LLC can provide different services to the network layer:• acknowledged connectionless service• unacknowledged connectionless service• connection-oriented service
• Framing
• Error control
• Addressing
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Functions of the MAC sublayer
• The various MAC sublayers of the IEEE 802 standard are very different.
• We will discuss:– CSMA/CD a.k.a. Ethernet
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IEEE 802.3 (CSMA/CD)
Transceiver 802.3 standardizes the 1-persistent CSMA/CD multi-access
control protocol.
1. Each station listens before it transmits.
2. If the channel is busy, it waits until the channel goes idle, and then it transmits.
3. If the channel is idle it transmits immediately. Continue sensing.
4. If collision is detected, transmit a brief jamming signal, then cease transmission, wait for a random time, and retransmit.
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Different techniques
• 1-persistent: – if busy, constantly sense channel– if idle, send immediately– if collision is detected, wait a random amount of time before retransmitting
• Non-persistent:– sense channel when station has a packet to send– if busy, wait a random amount of time before sensing again;– if idle, transmit as soon as it is idle– collisions reduced because sensing is not immediately rescheduled– drawback: more delay
• p-persistent: combines 1-persistent goal of reduced idle channel time with the non-persistent goal of reduced collisions.
– sense constantly if busy and the station needs to send a packet– when the channel becomes idle, transmit packet with probability p
– with probability 1-p station waits an additional tprop before sensing again
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Collisions in Ethernet
• The collision resolution process of Ethernet requires that a collision is detected while a station is still transmitting.
• Assume: max. propagation delay on the bus is a.
A Begins TransmissionA B
B Begins TransmissionA B
t0
t0+a-
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Collisions in Ethernet
• Restrictions: Each frame should be at least twice as long as the time to detect a collision (2 · maximum propagation delay).
B Detects CollisionA B
t0+a
A Detects CollisionA B
t0+2a
Just Before Endof Transmission
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Different MAC schemes
• ALOHA: True free-for-all. When a node needs to send, it does so. It listens for an amount of time equal to the maximum round trip delay plus a fixed increment. If it hears an acknowledgment, fine; otherwise it resends. After several attempts, it gives up. Max. utilization: 18%
• Slotted ALOHA: improved utilization: 37% (with time slots; frames that overlap, overlap completely)
• CSMA: Sense carrier, if idle, send.Wait for ack. If there isn’t one, assume there was a collision, retransmit.
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CSMA/CD
• CSMA/CD: – In CSMA, if collision occurs, need to wait till damaged
frames have fully propagated. For long frames compared to propagation delay, this could lead to significant waste of capacity. So add collision detection.
– Rule: Frames should be long enough to allow collision detection prior to the end of transmission (pg 405, EL536 textbook)
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Exponential Backoff Algorithm
• If a station is involved in a collision, it waits a random amount of time before attempting a retransmission.
• The random time is determined by the following algorithm:
• Set “slot time” to 2a.• After first collision wait 0 or 1 time unit.• After i-th collision, wait a random number
between 0 and 2 i-1 time slots.• Do not increase random number range if i=10.• Give up after 16 collisions.
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Physical Layer Specifications for 802.3
• Many types of media are allowed for 802.3. These are the most popular:
Name Cable DataRate
(Mbps)
MaximumLength
(m)
Comments
10Base5 “ThickCoax”
10 500 The “original” from1985
10Base2 “Thin Coax” 10 185 Called “Cheapernet”or “thin Ethernet”
10BaseT Twistedpair
10 100 Uses a star topology(with a central hub).
100BaseT Twistedpair
100 “Fast Ethernet”
100BaseFX Fiber optics 100 2000 Fiber version of FastEthernet
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Ethernet and IEEE 802.3: Any Difference?
• On a conceptual level, they are identical. But there are subtle differences that are relevant if we deal with TCP/IP.
• “Ethernet”: • An industry standard from 1982 that is based on the first
implementation of CSMA/CD by Xerox.• Predominant version of CSMA/CD in the US.
• 802.3:• IEEE’s version of CSMA/CD from 1985.• Interoperates with 802.2 (LLC) as higher layer.
• Difference for our purposes: Ethernet and 802.3 use different methods to encapsulate an IP datagram.
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IEEE 802.2/802.3 Encapsulation (RFC 1042)
802.3 MAC
destinationaddress
6
sourceaddress
6
length
2
DSAPAA
1
SSAPAA
1
cntl03
1
org code0
3
type
2
data
38-1492
CRC
4
802.2 LLC 802.2 SNAP
- destination address, source address:MAC addresses are 48 bit
- lengt h : frame length in number of bytes- DSAP, SSAP : always set to 0xaa- Ctrl: set t o 3- org code: set to 0- type field identifies the content of the
data field- CRC: cylic redundancy check
0800
2
IP datagram
38-1492
0806
2
ARP request/reply
28
PAD
10
0835
2
RARP request/reply
28
PAD
10
Error: This should be 8035 not 0835
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Ethernet Encapsulation (RFC 894 and 893)
CRCDest.Addr
.
Src.Addr. Data
IPdatagram
ARP req./reply
RARP req./reply
Type
66
2 18
PAD
46-1500
28
0800
0806
8035
Type
Type
Type
28 18
PAD
2
2
2
46-1500
4
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Interconnection of LANs
• LANs of different types can be interconnected by data link bridges.
BridgeToken-ring
IP
LLC
802.3 MAC 802.3 MAC 802.5 MAC
LLC
IP
LLC
802.5 MAC