man/man8/tc-drr.8 - maze/iproute2 - Git at Google

 .TH TC 8 "January 2010" "iproute2" "Linux"
 .SH NAME
 drr \- deficit round robin scheduler
 .SH SYNOPSIS
 .B tc qdisc ... add drr
 .B [ quantum
 bytes
 .B ]

 .SH DESCRIPTION

 The Deficit Round Robin Scheduler is a classful queuing discipline as
 a more flexible replacement for Stochastic Fairness Queuing.

 Unlike SFQ, there are no built-in queues \-\- you need to add classes
 and then set up filters to classify packets accordingly.
 This can be useful e.g. for using RED qdiscs with different settings for particular
 traffic. There is no default class \-\- if a packet cannot be classified,
 it is dropped.

 .SH ALGORITHM
 Each class is assigned a deficit counter, initialized to
 .B quantum.

 DRR maintains an (internal) ''active'' list of classes whose qdiscs are
 non-empty.  This list is used for dequeuing.  A packet is dequeued from
 the class at the head of the list if the packet size is smaller or equal
 to the deficit counter.  If the counter is too small, it is increased by
 .B quantum
 and the scheduler moves on to the next class in the active list.


 .SH PARAMETERS
 .TP
 quantum
 Amount of bytes a flow is allowed to dequeue before the scheduler moves to
 the next class.  Defaults to the MTU of the interface. The minimum value is 1.

 .SH EXAMPLE & USAGE

 To attach to device eth0, using the interface MTU as its quantum:
 .P
 # tc qdisc add dev eth0 handle 1 root drr
 .P
 Adding two classes:
 .P
 # tc class add dev eth0 parent 1: classid 1:1 drr
 # tc class add dev eth0 parent 1: classid 1:2 drr
 .P
 You also need to add at least one filter to classify packets.
 .P
 # tc filter add dev eth0 protocol .. classid 1:1
 .P

 Like SFQ, DRR is only useful when it owns the queue \-\- it is a pure scheduler and does
 not delay packets.  Attaching non-work-conserving qdiscs like tbf to it does not make
 sense \-\- other qdiscs in the active list will also become inactive until the dequeue
 operation succeeds.  Embed DRR within another qdisc like HTB or HFSC to ensure it owns the queue.
 .P
 You can mimic SFQ behavior by assigning packets to the attached classes using the
 flow filter:

 .B tc qdisc add dev .. drr

 .B for i in .. 1024;do
 .br
 .B \ttc class add dev ..  classid $handle:$(print %x $i)
 .br
 .B \ttc qdisc add dev .. fifo limit 16
 .br
 .B done

 .B tc filter add .. protocol ip .. $handle flow hash keys src,dst,proto,proto-src,proto-dst divisor 1024 perturb 10


 .SH SOURCE
 .TP
 o
 M. Shreedhar and George Varghese "Efficient Fair
 Queuing using Deficit Round Robin", Proc. SIGCOMM 95.

 .SH NOTES

 This implementation does not drop packets from the longest queue on overrun,
 as limits are handled by the individual child qdiscs.

 .SH SEE ALSO
 .BR tc (8),
 .BR tc-htb (8),
 .BR tc-sfq (8)

 .SH AUTHOR
 sched_drr was written by Patrick McHardy.
	.TH TC 8 "January 2010" "iproute2" "Linux"
	.SH NAME
	drr \- deficit round robin scheduler
	.SH SYNOPSIS
	.B tc qdisc ... add drr
	.B [ quantum
	bytes
	.B ]

	.SH DESCRIPTION

	The Deficit Round Robin Scheduler is a classful queuing discipline as
	a more flexible replacement for Stochastic Fairness Queuing.

	Unlike SFQ, there are no built-in queues \-\- you need to add classes
	and then set up filters to classify packets accordingly.
	This can be useful e.g. for using RED qdiscs with different settings for particular
	traffic. There is no default class \-\- if a packet cannot be classified,
	it is dropped.

	.SH ALGORITHM
	Each class is assigned a deficit counter, initialized to
	.B quantum.

	DRR maintains an (internal) ''active'' list of classes whose qdiscs are
	non-empty. This list is used for dequeuing. A packet is dequeued from
	the class at the head of the list if the packet size is smaller or equal
	to the deficit counter. If the counter is too small, it is increased by
	.B quantum
	and the scheduler moves on to the next class in the active list.


	.SH PARAMETERS
	.TP
	quantum
	Amount of bytes a flow is allowed to dequeue before the scheduler moves to
	the next class. Defaults to the MTU of the interface. The minimum value is 1.

	.SH EXAMPLE & USAGE

	To attach to device eth0, using the interface MTU as its quantum:
	.P
	# tc qdisc add dev eth0 handle 1 root drr
	.P
	Adding two classes:
	.P
	# tc class add dev eth0 parent 1: classid 1:1 drr
	# tc class add dev eth0 parent 1: classid 1:2 drr
	.P
	You also need to add at least one filter to classify packets.
	.P
	# tc filter add dev eth0 protocol .. classid 1:1
	.P

	Like SFQ, DRR is only useful when it owns the queue \-\- it is a pure scheduler and does
	not delay packets. Attaching non-work-conserving qdiscs like tbf to it does not make
	sense \-\- other qdiscs in the active list will also become inactive until the dequeue
	operation succeeds. Embed DRR within another qdisc like HTB or HFSC to ensure it owns the queue.
	.P
	You can mimic SFQ behavior by assigning packets to the attached classes using the
	flow filter:

	.B tc qdisc add dev .. drr

	.B for i in .. 1024;do
	.br
	.B \ttc class add dev .. classid $handle:$(print %x $i)
	.br
	.B \ttc qdisc add dev .. fifo limit 16
	.br
	.B done

	.B tc filter add .. protocol ip .. $handle flow hash keys src,dst,proto,proto-src,proto-dst divisor 1024 perturb 10


	.SH SOURCE
	.TP
	o
	M. Shreedhar and George Varghese "Efficient Fair
	Queuing using Deficit Round Robin", Proc. SIGCOMM 95.

	.SH NOTES

	This implementation does not drop packets from the longest queue on overrun,
	as limits are handled by the individual child qdiscs.

	.SH SEE ALSO
	.BR tc (8),
	.BR tc-htb (8),
	.BR tc-sfq (8)

	.SH AUTHOR
	sched_drr was written by Patrick McHardy.