Transcript Chapter 24. Congestion Control and Quality of Service

Chapter 24.
Congestion Control and Quality of Service
part 2
23.5
23.6
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23.8
Quality of Service
Techniques to Improve QoS
Integrated Services
Differentiated Services
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Quality of Service (QoS)
Flow Characteristics:
• Reliability:
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needed by flow, Lack of reliability means losing a packet or acknowledgment, which entails
retransmission.
Delay:
– applications can tolerate delay in different degrees.
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Jitter:
– the variation in delay for packets belonging to the same flow
– High jitter means the difference between delays is large; low jitter means the variation is small.
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Bandwidth:
– Different applications need different bandwidths.
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Flow Classes:
Based on the characteristics, we can classify flows into groups, with each group having similar
levels of characteristics
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QoS Techniques
four common techniques that can be used to improve
the quality of service :
– Scheduling:
A good scheduling technique treats the different flows
in a fair and appropriate manner.
– Traffic shaping: Leaky bucket, token bucket
– Resource reservation
– Admission control: accept or reject a flow based on predefined
parameters called flow specification
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1. Scheduling
FIFO queuing:
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packets wait in a buffer (queue) until the (router or switch) is ready to process
them.
• If the average arrival rate is higher than the average processing rate, the
queue will fill up and new packets will be discarded.
Priority Queuing:
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Packets are first assigned to priority class. Each priority class has its own queue
The packets in the highest-priority queue are processed first
Starvation may occurs
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1. Scheduling (cont..)
Weighted Fair Queuing
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The queues are weighted based on the priority of the queues
The system processes packets in each queue in a round-robin fashion with the
number of packets selected from each queue based on the weight
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2. Traffic Shaping
Traffic shaping is a mechanism to control the
amount and the rate of the traffic sent to the
network. Two techniques can shape traffic:
leaky bucket and token bucket.
First technique :Leaky Bucket
algorithm shapes bursty traffic into fixed-rate traffic by averaging the data rate. It may
drop the packets if the bucket is full.
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2. Traffic Shaping (cont)
simple Leaky Bucket Implementation:
• A FIFO queue holds the packets.
• If the traffic consists of fixed-size packets the
process removes a fixed number of packets
from the queue at each tick of the clock.
• If the traffic consists of variable-length
packets, the fixed
output rate must be based on the number of
bytes or bits.
– Algorithm for variable-length packets:
1) Initialize a counter to n at the tick of the clock
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2. Traffic Shaping (cont)
Second technique: Token Bucket
• The token bucket allows bursty traffic at a regulated maximum rate.
• The bucket holds tokens.
• To transmit a packet, we “use” one token.
• Allows the output rate to vary.
• Generate a token every r time units
• For an arriving packet enqueue
• While buffer not empty and there are tokens send a packet and discard a token
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2. Traffic Shaping (cont)
arrival
queue
Token
bucket
sent
p1 (5)
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0
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p2 (2)
p1
3
-
p3 (1)
p2
6-5=1
p1
4-2-1=1
p3,p2
Token bucket example:
parameters:
• MaxTokens=6
• (3 token/time)
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Combining Token Bucket and Leaky Bucket:
•The two techniques can be combined to credit an idle host and at the same time
regulate the traffic.
•The leaky bucket is applied after the token bucket
• the rate of the leaky bucket needs to be higher than the rate of tokens dropped
in the bucket.
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Integrated Services (IntServ)
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Integrated Services is a flow-based QoS model designed for IP
Signaling:
– implement a flow-based model over a connectionless protocol
– Resource Reservation Protocol (RSVP)
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Flow specification:
– Rspec (resource specification) defines the resource that the flow needs to reserve
(buffer, bandwidth, etc.)
– Tspec (traffic specification) defines the traffic characterization of the flow
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Admission:
– a router decides to admit or deny the flow specification based on the previous
commitments of the router and the current availability of the resource.
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Service classes: guaranteed service and controlled-load service
– Guaranteed service class: guaranteed minimum end-to-end delay
– Controlled-load service class: accept some delays, but is sensitive to an overloaded
network and to the danger of losing packets
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RSVP
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In IntServ, the resource reservation is for a flow, a kind of virtual circuit network
out of the IP
RSVP is a signaling protocol to help IP create a flow and consequently make a
resource reservation
RSVP is a signaling system designed for multicasting
Receiver-based reservation
RSVP message several types of messages : Path and Resv
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RSVP Messages
Path message: from sender to all receivers. Recall that the receivers in a flow make
the reservation in RSVP.
Resv Messages : Make a resource reservation from each receiver to sender
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Reservation Merging
• the resources are not reserved for each
receiver in a flow; the reservation is
merged.
• Rc3 requests a 2-Mbps bandwidth and Rc2
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Reservation Styles
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When there is more than one flow the router needs to make a reservation to
accommodate all of them.
RSVP defines three types of reservation styles
– Wild card filter style: a single reservation for all senders
– Fixed filter style: a distinct reservation for each flow
– Shared explicit style: a single reservation which can be shared by a set of flow
Reservation information (state):
• soft state Reservation information stored in every node for a flow needs to be refreshed
periodically.
•hard state used in other virtual-circuit protocols such as ATM or Frame Relay, where the
information about the flow is maintained until it is erased.
•Default interval for refreshing is currently 30 s.
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Problems with Integrated Services
1. Scalability
• The Integrated Services model requires that
each router keep information
for each flow, the Internet is growing every
day, this is a serious problem.
2. Service-Type Limitation
• The Integrated Services model provides only
two types of services
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Differentiated Service (Diffserv)
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Differentiated Services is a class-based QoS model designed for IP.
Diffserv handles the shortcomings of IntServ
1. The main processing was moved from the core of the network to the edge of the
network. This solves the scalability problem, where routers do not have to store
information about flows applications, or hosts, define the type of service need
by each send a packet.
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2. The per-flow service is changed to per-class service. The router routes the
packet
based on the class of service defined in the packet, not the flow. This solves the
service-type limitation problem.
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Differentiated Service (Diffserv)
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In Diffserv, each packet contains a field called the DS field.
The value of DS field is set at the boundary of the network by the host or the first
router designated as the boundary router.
Ds filed replace the existing TOS (type of service) field in IPv4 or the
class field in IPv6
DS field contains two subfields:
– DSCP (DS Code Point) is a 6-bit field that define per-hop behavior (PHB)
– CU (currently unused) is 2-bit
• The Diffserv capable node (router) uses the
DSCP 6 bits as an index to
table defining the packet-handling
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Per-hop Behavior (PHB)
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Diffserv defines three PHBs
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DE PHB (default PHB) is the same as best-effort delivery
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EF PHB (expedited forwarding PHB) provides the following services:
– Low loss, low latency, ensured bandwidth
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AF PHB (assured forwarding PHB) delivers the packet with a high assurance as long
as the class traffic does not exceed the traffic profile of the node
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Traffic Conditioner
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Meter checks to see if the incoming flow matches the negotiated traffic profile
Marker can re-mark a packet with best-effort delivery or down-mark a packet
based on the meter information; no up-mark
Shaper use the meter information to reshape the traffic if not compliant with the
negotiated profile.
Dropper, like a shaper with no buffer, discard packets if the flow severely violates
the profile
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