1
2
3
4
5
6
7
8
9
10
11
12
13
14
15
16
17
18
19
20
21
22
23
24
25
26
27
28
29
30
31
32
33
34
35
36
37
38
39
40
41
42
43
44
45
46
47
48
49
50
51
52
53
54
55
56
57
58
59
60
61
62
63
64
65
66
67
68
69
70
71
72
73
74
75
76
77
78
79
80
81
82
83
84
85
86
87
88
89
90
91
92
93
94
95
96
97
98
99
100
101
102
103
104
105
106
107
108
109
110
111
112
113
114
115
116
117
118
119
120
121
122
123
124
125
126
127
128
129
130
131
132
133
134
135
136
137
138
139
140
141
142
143
144
145
146
147
148
149
150
151
152
153
154
155
156
157
158
159
160
161
162
163
164
165
166
167
168
169
170
171
172
173
174
175
176
177
178
179
180
181
182
183
184
185
186
187
188
189
190
191
192
193
194
195
196
197
198
199
200
201
202
203
204
205
206
207
208
209
210
211
212
213
214
215
216
217
218
219
220
221
222
223
224
225
226
227
228
229
230
231
232
233
234
235
236
237
238
239
240
241
242
243
244
245
246
247
248
249
250
251
252
253
254
255
256
257
258
259
260
261
262
263
264
265
266
267
268
269
270
271
272
273
274
275
276
277
278
279
280
281
282
283
284
285
286
287
288
289
290
291
292
293
294
295
296
297
298
299
300
301
302
303
304
305
306
307
308
309
310
311
312
313
314
315
316
317
318
319
320
321
322
323
324
325
326
327
328
329
330
331
332
333
334
335
336
337
338
339
340
341
342
343
344
345
346
347
348
349
350
351
352
353
354
355
356
357
358
359
360
361
362
363
364
365
366
367
368
369
370
371
372
373
374
375
376
377
378
379
380
381
382
383
384
385
386
387
388
389
390
391
392
393
394
395
396
397
398
399
400
401
402
403
404
405
406
407
408
409
410
411
412
413
414
415
416
417
418
419
420
421
422
423
424
425
426
427
428
429
430
431
432
433
434
435
436
437
438
439
440
441
442
443
444
445
446
447
448
449
450
451
452
453
454
455
456
457
458
459
460
461
462
463
464
465
466
467
468
469
470
471
472
473
474
475
476
477
478
479
480
481
482
483
484
485
486
487
488
489
490
491
492
493
494
495
496
497
498
499
500
501
502
503
504
505
506
507
508
509
510
511
512
513
514
515
516
517
518
519
520
521
522
523
524
525
526
527
528
529
530
531
532
533
534
535
536
537
538
539
540
541
542
543
544
545
546
547
548
549
550
551
552
553
554
555
556
557
558
559
560
561
562
563
564
565
566
567
568
569
570
571
572
573
574
575
576
577
578
579
580
581
582
583
584
585
586
587
588
589
590
591
592
593
594
595
596
597
598
599
600
601
602
603
604
605
606
607
608
609
610
611
612
613
614
615
616
617
618
619
620
621
622
623
624
625
626
627
628
629
630
631
632
633
634
635
636
637
638
639
640
641
642
643
644
645
646
647
648
649
650
651
652
653
654
655
656
657
658
659
660
661
662
663
664
665
666
667
668
669
670
671
672
673
674
675
676
677
678
679
680
681
682
683
684
685
686
687
688
689
690
691
692
693
694
695
696
697
698
699
700
701
702
703
704
705
706
707
708
709
710
711
712
713
714
715
716
717
718
719
720
721
722
723
724
725
726
727
728
729
730
731
732
733
734
735
736
737
738
739
740
741
742
743
744
745
746
747
748
749
750
751
752
753
754
755
756
757
758
759
760
761
762
763
764
765
766
767
768
769
770
771
772
773
774
775
776
777
778
779
780
781
782
783
784
785
786
787
788
789
790
791
792
793
794
795
796
797
798
799
800
801
802
803
804
805
806
807
808
809
810
811
812
813
814
815
816
817
818
819
820
821
822
823
824
825
826
827
828
829
830
831
832
833
834
835
836
837
838
839
840
841
842
843
844
845
846
847
848
849
850
851
852
853
854
855
856
857
858
859
860
861
862
863
864
865
866
867
868
869
870
871
872
873
874
875
876
877
878
879
880
881
882
883
884
885
886
887
888
889
890
891
892
893
894
895
896
897
898
899
900
901
902
903
904
905
906
907
908
909
910
911
912
913
914
915
916
917
918
919
920
921
922
923
924
925
926
927
928
929
930
931
932
933
934
935
936
937
938
939
940
941
942
943
944
945
946
947
948
949
950
951
952
953
954
955
956
957
958
959
960
961
962
963
964
965
966
967
968
969
970
971
972
973
974
975
976
977
978
979
980
981
982
983
984
985
986
987
988
989
990
991
992
993
994
995
996
997
998
999
1000
1001
1002
1003
1004
1005
1006
1007
1008
1009
1010
1011
1012
1013
1014
1015
1016
1017
1018
1019
1020
1021
1022
1023
1024
1025
1026
1027
1028
1029
1030
1031
1032
1033
1034
1035
1036
1037
1038
1039
1040
1041
1042
1043
1044
1045
1046
1047
1048
1049
1050
1051
1052
1053
1054
1055
1056
1057
1058
1059
1060
1061
1062
1063
1064
1065
1066
1067
1068
1069
1070
1071
1072
1073
1074
1075
1076
1077
1078
1079
1080
1081
1082
1083
1084
1085
1086
1087
1088
1089
1090
1091
1092
1093
1094
1095
1096
1097
1098
1099
1100
1101
1102
1103
1104
1105
1106
1107
1108
1109
1110
1111
1112
1113
1114
1115
1116
1117
1118
1119
1120
1121
1122
1123
1124
1125
1126
1127
1128
1129
1130
1131
1132
1133
1134
1135
1136
1137
1138
1139
1140
1141
1142
1143
1144
1145
1146
1147
1148
1149
|
.. _qos:
***
QoS
***
The generic name of Quality of Service or Traffic Control involves
things like shaping traffic, scheduling or dropping packets, which
are the kind of things you may want to play with when you have, for
instance, a bandwidth bottleneck in a link and you want to somehow
prioritize some type of traffic over another.
tc_ is a powerful tool for Traffic Control found at the Linux kernel.
However, its configuration is often considered a cumbersome task.
Fortunately, VyOS eases the job through its CLI, while using ``tc`` as
backend.
How to make it work
===================
In order to have VyOS Traffic Control working you need to follow 2
steps:
1. Create a traffic policy.
2. Apply the traffic policy to an interface ingress or egress.
But before learning to configure your policy, we will warn you
about the different units you can use and also show you what *classes*
are and how they work, as some policies may require you to configure
them.
Units
=====
When configuring your traffic policy, you will have to set data rate
values, watch out the units you are managing, it is easy to get confused
with the different prefixes and suffixes you can use. VyOS will always
show you the different units you can use.
Prefixes
--------
They can be **decimal** prefixes.
.. code-block:: none
kbit (10^3) kilobit per second
mbit (10^6) megabit per second
gbit (10^9) gigabit per second
tbit (10^12) terabit per second
kbps (8*10^3) kilobyte per second
mbps (8*10^6) megabyte per second
gbps (8*10^9) gigabyte per second
tbps (8*10^12) terabyte per second
Or **binary** prefixes.
.. code-block:: none
kibit (2^10 = 1024) kibibit per second
mibit (2^20 = 1024^2) mebibit per second
gibit (2^30 = 1024^3) gibibit per second
tbit (2^40 = 1024^4) tebibit per second
kibps (1024*8) kibibyte (KiB) per second
mibps (1024^2*8) mebibyte (MiB) per second
gibps (1024^3*8) gibibyte (GiB) per second
tibps (1024^4*8) tebibyte (TiB) per second
Suffixes
--------
A *bit* is written as **bit**,
.. code-block:: none
kbit (kilobits per second)
mbit (megabits per second)
gbit (gigabits per second)
tbit (terabits per second)
while a *byte* is written as a single **b**.
.. code-block:: none
kbps (kilobytes per second)
mbps (megabytes per second)
gbps (gigabytes per second)
.. _classes:
Classes
=======
In the :ref:`creating_a_traffic_policy` section you will see that
some of the policies use *classes*. Those policies let you distribute
traffic into different classes according to different parameters you can
choose. So, a class is just a specific type of traffic you select.
The ultimate goal of classifying traffic is to give each class a
different treatment.
Matching traffic
----------------
In order to define which traffic goes into which class, you define
filters (that is, the matching criteria). Packets go through these matching rules
(as in the rules of a firewall) and, if a packet matches the filter, it
is assigned to that class.
In VyOS, a class is identified by a number you can choose when
configuring it.
.. note:: The meaning of the Class ID is not the same for every type of
policy. Normally policies just need a meaningless number to identify
a class (Class ID), but that does not apply to every policy.
The the number of a class in a Priority Queue it does not only
identify it, it also defines its priority.
.. code-block:: none
set traffic-policy <policy> <policy-name> class <class-ID> match <class-matching-rule-name>
In the command above, we set the type of policy we are going to
work with and the name we choose for it; a class (so that we can
differentiate some traffic) and an identifiable number for that class;
then we configure a matching rule (or filter) and a name for it.
A class can have multiple match filters:
.. code-block:: none
set traffic-policy shaper MY-SHAPER class 30 match HTTP
set traffic-policy shaper MY-SHAPER class 30 match HTTPs
A match filter can contain multiple criteria and will match traffic if
all those criteria are true.
For example:
.. code-block:: none
set traffic-policy shaper MY-SHAPER class 30 match HTTP ip protocol tcp
set traffic-policy shaper MY-SHAPER class 30 match HTTP ip source port 80
This will match TCP traffic with source port 80.
There are many parameters you will be able to use in order to match the
traffic you want for a class:
- **Ethernet (protocol, destination address or source address)**
- **Interface name**
- **IPv4 (DSCP value, maximum packet length, protocol, source address,**
**destination address, source port, destination port or TCP flags)**
- **IPv6 (DSCP value, maximum payload length, protocol, source address,**
**destination address, source port, destination port or TCP flags)**
- **Firewall mark**
- **VLAN ID**
When configuring your filter, you can use the ``Tab`` key to see the many
different parameters you can configure.
.. code-block:: none
vyos@vyos# set traffic-policy shaper MY-SHAPER class 30 match MY-FIRST-FILTER
Possible completions:
description Description for this match
> ether Ethernet header match
interface Interface name for this match
> ip Match IP protocol header
> ipv6 Match IPV6 header
mark Match on mark applied by firewall
vif Virtual Local Area Network (VLAN) ID for this match
As shown in the example above, one of the possibilities to match packets
is based on marks done by the firewall, `that can give you a great deal of flexibility`_.
You can also write a description for a filter:
.. code-block:: none
set traffic-policy shaper MY-SHAPER class 30 match MY-FIRST-FILTER description "My filter description"
.. note:: An IPv4 TCP filter will only match packets with an IPv4 header length of
20 bytes (which is the majority of IPv4 packets anyway).
.. note:: IPv6 TCP filters will only match IPv6 packets with no header extension, see
https://en.wikipedia.org/wiki/IPv6_packet#Extension_headers
Default
-------
Often you will also have to configure your *default* traffic in the same
way you do with a class. *Default* can be considered a class as it
behaves like that. It contains any traffic that did not match any
of the defined classes, so it is like an open class, a class without
matching filters.
Class treatment
---------------
Once a class has a filter configured, you will also have to define what
you want to do with the traffic of that class, what specific
Traffic-Control treatment you want to give it. You will have different
possibilities depending on the Traffic Policy you are configuring.
.. code-block:: none
vyos@vyos# set traffic-policy shaper MY-SHAPER class 30
Possible completions:
bandwidth Bandwidth used for this class
burst Burst size for this class (default: 15kb)
ceiling Bandwidth limit for this class
codel-quantum
fq-codel - Number of bytes used as 'deficit' (default 1514)
description Description for this traffic class
flows fq-codel - Number of flows (default 1024)
interval fq-codel - Interval (milliseconds) used to measure the delay (default 100)
+> match Class matching rule name
priority Priority for usage of excess bandwidth
queue-limit Maximum queue size (packets)
queue-type Queue type for this class
set-dscp Change the Differentiated Services (DiffServ) field in the IP header
target fq-codel - Acceptable minimum queue delay (milliseconds)
For instance, with :code:`set traffic-policy shaper MY-SHAPER class 30 set-dscp EF`
you would be modifying the DSCP field value of packets in that class to
Expedite Forwarding.
DSCP values as per :rfc:`2474` and :rfc:`4595`:
+---------+------------+--------+------------------------------+
| Binary | Configured | Drop | Description |
| value | value | rate | |
+=========+============+========+==============================+
| 101110 | 46 | - | Expedited forwarding (EF) |
+---------+------------+--------+------------------------------+
| 000000 | 0 | - | Best effort traffic, default |
+---------+------------+--------+------------------------------+
| 001010 | 10 | Low | Assured Forwarding(AF) 11 |
+---------+------------+--------+------------------------------+
| 001100 | 12 | Medium | Assured Forwarding(AF) 12 |
+---------+------------+--------+------------------------------+
| 001110 | 14 | High | Assured Forwarding(AF) 13 |
+---------+------------+--------+------------------------------+
| 010010 | 18 | Low | Assured Forwarding(AF) 21 |
+---------+------------+--------+------------------------------+
| 010100 | 20 | Medium | Assured Forwarding(AF) 22 |
+---------+------------+--------+------------------------------+
| 010110 | 22 | High | Assured Forwarding(AF) 23 |
+---------+------------+--------+------------------------------+
| 011010 | 26 | Low | Assured Forwarding(AF) 31 |
+---------+------------+--------+------------------------------+
| 011100 | 28 | Medium | Assured Forwarding(AF) 32 |
+---------+------------+--------+------------------------------+
| 011110 | 30 | High | Assured Forwarding(AF) 33 |
+---------+------------+--------+------------------------------+
| 100010 | 34 | Low | Assured Forwarding(AF) 41 |
+---------+------------+--------+------------------------------+
| 100100 | 36 | Medium | Assured Forwarding(AF) 42 |
+---------+------------+--------+------------------------------+
| 100110 | 38 | High | Assured Forwarding(AF) 43 |
+---------+------------+--------+------------------------------+
.. _embed:
Embedding one policy into another one
-------------------------------------
Often we need to embed one policy into another one. It is possible to do
so on classful policies, by attaching a new policy into a class. For
instance, you might want to apply different policies to the different
classes of a Round-Robin policy you have configured.
A common example is the case of some policies which, in order to be
effective, they need to be applied to an interface that is directly
connected to the link where the bottleneck is. If your router is not
directly connected to the bottleneck, but some hop before it, you can
emulate the bottleneck by embedding your non-shaping policy into a
classful shaping one so that it takes effect.
You can configure a policy into a class through the ``queue-type``
setting.
.. code-block:: none
set traffic-policy shaper FQ-SHAPER bandwidth 1gbit
set traffic-policy shaper FQ-SHAPER default bandwidth 100%
set traffic-policy shaper FQ-SHAPER default queue-type fair-queue
As shown in the last command of the example above, the `queue-type`
setting allows these combinations. You will be able to use it
in many policies.
.. _creating_a_traffic_policy:
Creating a traffic policy
=========================
VyOS lets you control traffic in many different ways, here we will cover
every possibility. You can configure as many policies as you want, but
you will only be able to apply one policy per interface and direction
(inbound or outbound).
Some policies can be combined, you will be able to embed_ a different
policy that will be applied to a class of the main policy.
.. hint:: If you are looking for a policy for your outbound traffic but
you do not know what policy you need, you might consider FQ-CoDel_ as
your multipurpose nearly-no-configuration low-delay fair-queue
policy; if delay does not worry you and you want to manually allocate
bandwidth shares to specific traffic, then you should consider
Shaper_.
Drop Tail
---------
| **Queueing discipline:** PFIFO (Packet First In First Out).
| **Applies to:** Outbound traffic.
This the simplest queue possible you can apply to your traffic. Traffic
must go through a finite queue before it is actually sent. You must
define how many packets that queue can contain.
When a packet is to be sent, it will have to go through that queue, so
the packet will be placed at the tail of it. When the packet completely
goes through it, it will be dequeued emptying its place in the queue and
being eventually handed to the NIC to be actually sent out.
Despite the Drop-Tail policy does not slow down packets, if many packets
are to be sent, they could get dropped when trying to get enqueued at
the tail. This can happen if the queue has still not been able to
release enough packets from its head.
**Very likely you do not need this simple policy as you cannot get much
from it. Sometimes it is used just to enable logging.**
.. cfgcmd:: set traffic-policy drop-tail <policy-name> queue-limit <number-of-packets>
Use this command to configure a drop-tail policy (PFIFO). Choose a
unique name for this policy and the size of the queue by setting the
number of packets it can contain (maximum 4294967295).
Fair Queue
----------
| **Queueing discipline:** SFQ (Stochastic Fairness Queuing).
| **Applies to:** Outbound traffic.
Fair Queue is a work-conserving scheduler which schedules the
transmission of packets based on flows, trying to ensure fairness so
that each flow is able to send data in turn, preventing any single one
from drowning out the rest.
.. cfgcmd:: set traffic-policy fair-queue <policy-name>
Use this command to create a Fair-Queue policy and give it a name.
It is based on the Stochastic Fairness Queueing and can be applied to
outbound traffic.
The algorithm enqueues packets to hash buckets based on source address,
destination address and source port. Each of these buckets should
represent a unique flow. Because multiple flows may get hashed to the
same bucket, the hashing algorithm is perturbed at configurable
intervals so that the unfairness lasts only for a short while.
Perturbation may however cause some inadvertent packet reordering to
occur. An advisable value could be 10 seconds.
One of the uses of Fair Queue might be the mitigation of Denial of
Service attacks.
.. cfgcmd:: set traffic-policy fair-queue <policy-name> hash-interval <seconds>`
Use this command to define a Fair-Queue policy, based on the
Stochastic Fairness Queueing, and set the number of seconds at which
a new queue algorithm perturbation will occur (maximum 4294967295).
When dequeuing, each hash-bucket with data is queried in a round robin
fashion. You can configure the length of the queue.
.. cfgcmd:: set traffic-policy fair-queue <policy-name> queue-limit <limit>
Use this command to define a Fair-Queue policy, based on the
Stochastic Fairness Queueing, and set the number of maximum packets
allowed to wait in the queue. Any other packet will be dropped.
.. note:: Fair Queue is a non-shaping (work-conserving) policy, so it
will only be useful if your outgoing interface is really full. If it
is not, VyOS will not own the queue and Fair Queue will have no
effect. If there is bandwidth available on the physical link, you can
embed_ Fair-Queue into a classful shaping policy to make sure it owns
the queue.
.. _FQ-CoDel
FQ-CoDel
--------
| **Queueing discipline** Fair/Flow Queue CoDel.
| **Applies to:** Outbound Traffic.
The FQ-CoDel policy distributes the traffic into 1024 FIFO queues and
tries to provide good service between all of them. It also tries to keep
the length of all the queues short.
FQ-CoDel fights bufferbloat and reduces latency without the need of
complex configurations. It has become the new default Queueing
Discipline for the interfaces of some GNU/Linux distributions.
It uses a stochastic model to classify incoming packets into
different flows and is used to provide a fair share of the bandwidth to
all the flows using the queue. Each flow is managed by the CoDel
queuing discipline. Reordering within a flow is avoided since Codel
internally uses a FIFO queue.
FQ-CoDel is based on a modified Deficit Round Robin (DRR_) queue
scheduler with the CoDel Active Queue Management (AQM) algorithm
operating on each queue.
.. note:: FQ-Codel is a non-shaping (work-conserving) policy, so it
will only be useful if your outgoing interface is really full. If it
is not, VyOS will not own the queue and FQ-Codel will have no
effect. If there is bandwidth available on the physical link, you can
embed_ FQ-Codel into a classful shaping policy to make sure it owns
the queue. If you are not sure if you need to embed your FQ-CoDel
policy into a Shaper, do it.
FQ-CoDel is tuned to run ok with its default parameters at 10Gbit
speeds. It might work ok too at other speeds without configuring
anything, but here we will explain some cases when you might want to
tune its parameters.
When running it at 1Gbit and lower, you may want to reduce the
`queue-limit` to 1000 packets or less. In rates like 10Mbit, you may
want to set it to 600 packets.
If you are using FQ-CoDel embedded into Shaper_ and you have large rates
(100Mbit and above), you may consider increasing `quantum` to 8000 or
higher so that the scheduler saves CPU.
On low rates (below 40Mbit) you may want to tune `quantum` down to
something like 300 bytes.
At very low rates (below 3Mbit), besides tuning `quantum` (300 keeps
being ok) you may also want to increase `target` to something like 15ms
and increase `interval` to something around 150 ms.
.. cfgcmd:: set traffic-policy fq-codel <policy name> codel-quantum <bytes>
Use this command to configure an fq-codel policy, set its name and
the maximum number of bytes (default: 1514) to be dequeued from a
queue at once.
.. cfgcmd:: set traffic-policy fq-codel <policy name> flows <number-of-flows>
Use this command to configure an fq-codel policy, set its name and
the number of sub-queues (default: 1024) into which packets are
classified.
.. cfgcmd:: set traffic-policy fq-codel <policy name> interval <miliseconds>
Use this command to configure an fq-codel policy, set its name and
the time period used by the control loop of CoDel to detect when a
persistent queue is developing, ensuring that the measured minimum
delay does not become too stale (default: 100ms).
.. cfgcmd:: set traffic-policy fq-codel <policy-name> queue-limit <number-of-packets>`
Use this command to configure an fq-codel policy, set its name, and
define a hard limit on the real queue size. When this limit is
reached, new packets are dropped (default: 10240 packets).
.. cfgcmd:: set traffic-policy fq-codel <policy-name> target <miliseconds>`
Use this command to configure an fq-codel policy, set its name, and
define the acceptable minimum standing/persistent queue delay. This
minimum delay is identified by tracking the local minimum queue delay
that packets experience (default: 5ms).
Example
^^^^^^^
A simple example of an FQ-CoDel policy working inside a Shaper one.
.. code-block:: none
set traffic-policy shaper FQ-CODEL-SHAPER bandwidth 2gbit
set traffic-policy shaper FQ-CODEL-SHAPER 100%
set traffic-policy shaper FQ-CODEL-SHAPER fq-codel
Limiter
-------
| **Queueing discipline:** Ingress policer.
| **Applies to:** Inbound traffic.
Limiter is one of those policies that uses classes_ (Ingress qdisc is
actually classless policy but filters do work in it).
The limiter performs basic ingress policing of traffic flows. Multiple
classes of traffic can be defined and traffic limits can be applied to
each class. Although the policer uses a token bucket mechanism
internally, it does not have the capability to delay a packet as a
shaping mechanism does. Traffic exceeding the defined bandwidth limits
is directly dropped. A maximum allowed burst can be configured too.
You can configure classes (up to 4090) with different settings and a
default policy which will be applied to any traffic not matching any of
the configured classes.
.. note:: In the case you want to apply some kind of **shaping** to your
**inbound** traffic, check the ingress-shaping_ section.
.. cfgcmd:: set traffic-policy limiter <policy-name> class <class ID> match <match-name> description <description>
Use this command to configure an Ingress Policer, defining its name,
a class identifier (1-4090), a class matching rule name and its
description.
Once the matching rules are set for a class, you can start configuring
how you want matching traffic to behave.
.. cfgcmd:: set traffic-policy limiter <policy-name> class <class-ID> bandwidth <rate>
Use this command to configure an Ingress Policer, defining its name,
a class identifier (1-4090) and the maximum allowed bandwidth for
this class.
.. cfgcmd:: set traffic-policy limiter <policy-name> class <class-ID> burst <burst-size>
Use this command to configure an Ingress Policer, defining its name,
a class identifier (1-4090) and the burst size in bytes for this
class (default: 15).
.. cfgcmd:: set traffic-policy limiter <policy-name> default bandwidth <rate>
Use this command to configure an Ingress Policer, defining its name
and the maximum allowed bandwidth for its default policy.
.. cfgcmd:: set traffic-policy limiter <policy-name> default burst <burst-size>
Use this command to configure an Ingress Policer, defining its name
and the burst size in bytes (default: 15) for its default policy.
.. cfgcmd:: set traffic-policy limiter <policy-name> class <class ID> priority <value>
Use this command to configure an Ingress Policer, defining its name,
a class identifier (1-4090), and the priority (0-20, default 20) in
which the rule is evaluated (the lower the number, the higher the
priority).
Network emulator
----------------
| **Queueing discipline:** netem (Network Emulator) + TBF (Token Bucket Filter).
| **Applies to:** Outbound traffic.
VyOS Network Emulator policy emulates the conditions you can suffer in a
real network. You will be able to configure things like rate, burst,
delay, packet loss, packet corruption or packet reordering.
This could be helpful if you want to test how an application behaves
under certain network conditions.
.. cfgcmd:: set traffic-policy network-emulator <policy-name> bandwidth <rate>
Use this command to configure the maximum rate at which traffic will
be shaped in a Network Emulator policy. Define the name of the policy
and the rate.
.. cfgcmd:: set traffic-policy network-emulator <policy-name> burst <burst-size>
Use this command to configure the burst size of the traffic in a
Network Emulator policy. Define the name of the Network Emulator
policy and its traffic burst size. It will only take effect if you
have configured its bandwidth too.
.. cfgcmd:: set traffic-policy network-emulator <policy-name> network-delay <delay>
Use this command to configure a Network Emulator policy defining its
name and the fixed amount of time you want to add to all packet going
out of the interface. You can use secs, ms and us.
.. cfgcmd:: set traffic-policy network-emulator <policy-name> packet-corruption <percent>
Use this command to emulate noise in a Network Emulator policy. Set
the policy name and the percentage of corrupted packets you want. A
random error will be introduced in a random position for the chosen
percent of packets.
.. cfgcmd:: set traffic-policy network-emulator <policy-name> packet-loss <percent>`
Use this command to emulate packet-loss conditions in a Network
Emulator policy. Set the policy name and the percentage of loss
packets your traffic will suffer.
.. cfgcmd:: set traffic-policy network-emulator <policy-name> packet-reordering <percent>`
Use this command to emulate packet-reordering conditions in a Network
Emulator policy. Set the policy name and the percentage of reordered
packets your traffic will suffer.
.. cfgcmd:: set traffic-policy network-emulator <policy-name> queue-limit <limit>
Use this command to define the length of the queue of your Network
Emulator policy. Set the policy name and the maximum number of
packets (1-4294967295) the queue may hold queued at a time.
Priority queue
--------------
| **Queueing discipline:** PRIO.
| **Applies to:** Outbound traffic.
The Priority Queue is a classful scheduling policy. It does not delay
packets, it simply dequeues packets according to their priority.
.. note:: Priority Queue, as other non-shaping policies, is only useful
if your outgoing interface is really full. If it is not, VyOS will
not own the queue and Priority Queue will have no effect. If there is
bandwidth available on the physical link, you can embed_ Priority
Queue into a classful shaping policy to make sure it owns the queue.
In that case packets can be prioritized based on DSCP.
Up to seven queues -defined as classes_ with different priorities- can
be configured. Packets are placed into queues based on associated match
criteria. Packets are transmitted from the queues in priority order. If
classes with a higher priority are being filled with packets
continuously, packets from lower priority classes will only be
transmitted after traffic volume from higher priority classes decreases.
.. note:: In Priority Queue we do not define clases with a meaningless
class ID number but with a class priority number (1-7). The lower the
number, the higher the priority.
As with other policies, you can define different type of matching rules
for your classes:
.. code-block:: none
vyos@vyos# set traffic-policy priority-queue MY-PRIO class 3 match MY-MATCH-RULE
Possible completions:
description Description for this match
> ether Ethernet header match
interface Interface name for this match
> ip Match IP protocol header
> ipv6 Match IPV6 header
mark Match on mark applied by firewall
vif Virtual Local Area Network (VLAN) ID for this match
As with other policies, you can embed_ other policies into the classes
(and default) of your Priority Queue policy through the ``queue-type``
setting:
.. code-block:: none
vyos@vyos# set traffic-policy priority-queue MY-PRIO class 3 queue-type
Possible completions:
fq-codel Fair Queue Codel
fair-queue Stochastic Fair Queue (SFQ)
drop-tail First-In-First-Out (FIFO)
priority Priority queueing based on DSCP
random-detect
Random Early Detection (RED)
.. cfgcmd:: set traffic-policy priority-queue <policy-name> class <class-ID> queue-limit <limit>`
Use this command to configure a Priority Queue policy, set its name,
set a class with a priority from 1 to 7 and define a hard limit on
the real queue size. When this limit is reached, new packets are
dropped.
.. _Random-Detect:
Random-Detect
-------------
| **Queueing discipline:** Generalized Random Early Drop.
| **Applies to:** Outbound traffic.
A simple Random Early Detection (RED) policy would start randomly
dropping packets from a queue before it reaches its queue limit thus
avoiding congestion. That is good for TCP connections as the gradual
dropping of packets acts as a signal for the sender to decrease its
transmission rate.
In contrast to simple RED, VyOS' Random-Detect uses a Weighted Random
Early Detect policy that prvides different virtual queues based on the
IP Precedence value so that some virtual queues can drop more packets
than others.
This is achieved by using the first three bits of the ToS (Type of
Service) field to categorize data streams and, in accordance with the
defined precedence parameters, a decision is made.
IP precedence as defined in :rfc:`791`:
+------------+----------------------+
| Precedence | Priority |
+============+======================+
| 7 | Network Control |
+------------+----------------------+
| 6 | Internetwork Control |
+------------+----------------------+
| 5 | CRITIC/ECP |
+------------+----------------------+
| 4 | Flash Override |
+------------+----------------------+
| 3 | Flash |
+------------+----------------------+
| 2 | Immediate |
+------------+----------------------+
| 1 | Priority |
+------------+----------------------+
| 0 | Routine |
+------------+----------------------+
.. cfgcmd:: set traffic-policy random-detect <policy-name> bandwidth <bandwidth>
Use this command to configure a Random-Detect policy, set its name
and set the available bandwidth for this policy.
.. cfgcmd:: set traffic-policy random-detect <policy-name> precedence <IP-precedence-value> average-packet <bytes>
Use this command to configure a Random-Detect policy and set its
name, then state the IP Precedence for the virtual queue you are
configuring and what the size of its average-packet should be
(in bytes, default: 1024).
.. note:: When configuring a Random-Detect policy: **the higher the
precedence number, the higher the priority**.
.. cfgcmd:: set traffic-policy random-detect <policy-name> precedence <IP-precedence-value> mark-probability <value>
Use this command to configure a Random-Detect policy and set its
name, then state the IP Precedence for the virtual queue you are
configuring and what its mark (drop) probability will be. Set the
probability by giving the N value of the fraction 1/N (default: 10).
.. cfgcmd:: set traffic-policy random-detect <policy-name> precedence <IP-precedence-value> maximum-threshold <packets>
Use this command to configure a Random-Detect policy and set its
name, then state the IP Precedence for the virtual queue you are
configuring and what its maximum threshold for random detection will
be (from 0 to 4096 packets, default: 18). At this size, the marking
(drop) probability is maximal.
.. cfgcmd:: set traffic-policy random-detect <policy-name> precedence <IP-precedence-value> minimum-threshold <packets>
Use this command to configure a Random-Detect policy and set its
name, then state the IP Precedence for the virtual queue you are
configuring and what its minimum threshold for random detection will
be (from 0 to 4096 packets). If this value is exceeded, packets
start being eligible for being dropped.
The default values for the minimum-threshold depend on IP precedence:
+------------+-----------------------+
| Precedence | default min-threshold |
+============+=======================+
| 7 | 16 |
+------------+-----------------------+
| 6 | 15 |
+------------+-----------------------+
| 5 | 14 |
+------------+-----------------------+
| 4 | 13 |
+------------+-----------------------+
| 3 | 12 |
+------------+-----------------------+
| 2 | 11 |
+------------+-----------------------+
| 1 | 10 |
+------------+-----------------------+
| 0 | 9 |
+------------+-----------------------+
.. cfgcmd:: set traffic-policy random-detect <policy-name> precedence <IP-precedence-value> queue-limit <packets>
Use this command to configure a Random-Detect policy and set its
name, then name the IP Precedence for the virtual queue you are
configuring and what the maximum size of its queue will be (from 1 to
1-4294967295 packets). Packets are dropped when the current queue
length reaches this value.
If the average queue size is lower than the :code:`min-threshold`, an
arriving packet will be placed in the queue. In the case the average
queue size is between :code:`min-threshold` and :code:`max-threshold`,
then an arriving packet would be either dropped or placed in the queue,
it will depend on the defined :code:`mark-probability`. If the current
queue size is larger than :code:`queue-limit`, then packets will be
dropped. The average queue size depends on its former average size and
its current one. If :code:`max-threshold` is set but
:code:`min-threshold` is not, then :code:`min-threshold` is scaled to
50% of :code:`max-threshold`. In principle, values must be
:code:`min-threshold` < :code:`max-threshold` < :code:`queue-limit`.
One use of this algorithm might be to prevent a backbone overload.
Rate control
------------
| **Queueing discipline:** Tocken Bucket Filter.
| **Applies to:** Outbound traffic.
Rate-Control is a classless policy that limits the packet flow to a set
rate. It is a pure shaper, it does not schedule traffic. Traffic is
filtered based on the expenditure of tokens. Tokens roughly correspond
to bytes.
Short bursts can be allowed to exceed the limit. On creation, the
Rate-Control traffic is stocked with tokens which correspond to the
amount of traffic that can be burst in one go. Tokens arrive at a steady
rate, until the bucket is full.
.. cfgcmd:: set traffic-policy rate-control <policy-name> bandwidth <rate>
Use this command to configure a Rate-Control policy, set its name
and the rate limit you want to have.
.. cfgcmd:: set traffic-policy rate-control <policy-name> burst <burst-size>
Use this command to configure a Rate-Control policy, set its name
and the size of the bucket in bytes which will be available for
burst.
As a reference: for 10mbit/s on Intel, you might need at least 10kbyte
buffer if you want to reach your configured rate.
A very small buffer will soon start dropping packets.
.. cfgcmd:: set traffic-policy rate-control <policy-name> latency
Use this command to configure a Rate-Control policy, set its name
and the maximum amount of time a packet can be queued (default: 50
ms).
Rate-Control is a CPU-friendly policy. You might consider using it when
you just simply want to slow traffic down.
.. _DRR:
Round robin (DRR)
-----------------
| **Queueing discipline:** Deficit Round Robin.
| **Applies to:** Outbound traffic.
The round-robin policy is a classful scheduler that divides traffic in
different classes_ you can configure (up to 4096). You can embed_ a
new policy into each of those classes (default included).
Each class is assigned a deficit counter (the number of bytes that a
flow is allowed to transmit when it is its turn) initialized to quantum.
Quantum is a parameter you configure which acts like a credit of fix
bytes the counter receives on each round. Then the Round-Robin policy
starts moving its Round Robin pointer through the queues. If the deficit
counter is greater than the packet's size at the head of the queue, this
packet will be sent and the value of the counter will be decremented by
the packet size. Then, the size of the next packet will be compared to
the counter value again, repeating the process. Once the queue is empty
or the value of the counter is insufficient, the Round-Robin pointer
will move to the next queue. If the queue is empty, the value of the
deficit counter is reset to 0.
At every round, the deficit counter adds the quantum so that even large
packets will have their opportunity to be dequeued.
.. cfgcmd:: set traffic-policy round-robin <policy name> class
<class-ID> quantum <packets>
Use this command to configure a Round-Robin policy, set its name, set
a class ID, and the quantum for that class. The deficit counter will
add that value each round.
.. cfgcmd:: set traffic-policy round-robin <policy name> class
<class ID> queue-limit <packets>
Use this command to configure a Round-Robin policy, set its name, set
a class ID, and the queue size in packets.
As with other policies, Round-Robin can embed_ another policy into a
class through the ``queue-type`` setting.
.. code-block:: none
vyos@vyos# set traffic-policy round-robin DRR class 10 queue-type
Possible completions:
fq-codel Fair Queue Codel
fair-queue Stochastic Fair Queue (SFQ)
drop-tail First-In-First-Out (FIFO)
priority Priority queueing based on DSCP
.. _Shaper:
Shaper
------
| **Queueing discipline:** Hierarchical Token Bucket.
| **Applies to:** Outbound traffic.
The Shaper policy does not guarantee a low delay, but it does guarantee
bandwidth to different traffic classes and also lets you decide how to
allocate more traffic once the guarantees are met.
Each class can have a guaranteed part of the total bandwidth defined for
the whole policy, so all those shares together should not be higher
than the policy's whole bandwidth.
If guaranteed traffic for a class is met and there is room for more
traffic, the ceiling parameter can be used to set how much more
bandwidth could be used. If guaranteed traffic is met and there are
several classes willing to use their ceilings, the priority parameter
will establish the order in which that additional traffic will be
allocated. Priority can be any number from 0 to 7. The lower the number,
the higher the priority.
.. cfgcmd:: set traffic-policy shaper <policy-name> bandwidth <rate>
Use this command to configure a Shaper policy, set its name
and the maximum bandwidth for all combined traffic.
.. cfgcmd:: set traffic-policy shaper <policy-name> class <class-ID> bandwidth <rate>
Use this command to configure a Shaper policy, set its name, define
a class and set the guaranteed traffic you want to allocate to that
class.
.. cfgcmd:: set traffic-policy shaper <policy-name> class <class-ID> burst <bytes>
Use this command to configure a Shaper policy, set its name, define
a class and set the size of the `tocken bucket`_ in bytes, which will
be available to be sent at maximum speed (default: 15Kb).
.. cfgcmd:: set traffic-policy shaper <policy-name> class <class-ID> ceiling <bandwidth>
Use this command to configure a Shaper policy, set its name, define
a class and set the maximum speed possible for this class. The
default ceiling value is the bandwidth value.
.. cfgcmd:: set traffic-policy shaper <policy-name> class <class-ID> priority <0-7>
Use this command to configure a Shaper policy, set its name, define
a class and set the priority for usage of available bandwidth once
guarantees have been met. The lower the priority number, the higher
the priority. The default priority value is 0, the highest priority.
As with other policies, Shaper can embed_ other policies into its
classes through the ``queue-type`` setting and then configure their
parameters.
.. code-block:: none
vyos@vyos# set traffic-policy shaper HTB class 10 queue-type
Possible completions:
fq-codel Fair Queue Codel
fair-queue Stochastic Fair Queue (SFQ)
drop-tail First-In-First-Out (FIFO)
priority Priority queueing based on DSCP
random-detect
Random Early Detection (RED)
.. code-block:: none
vyos@vyos# set traffic-policy shaper HTB class 10
Possible completions:
bandwidth Bandwidth used for this class
burst Burst size for this class (default: 15kb)
ceiling Bandwidth limit for this class
codel-quantum
fq-codel - Number of bytes used as 'deficit' (default 1514)
description Description for this traffic class
flows fq-codel - Number of flows (default 1024)
interval fq-codel - Interval (milliseconds) used to measure the delay (default 100)
+> match Class matching rule name
priority Priority for usage of excess bandwidth
queue-limit Maximum queue size (packets)
queue-type Queue type for this class
set-dscp Change the Differentiated Services (DiffServ) field in the IP header
target fq-codel - Acceptable minimum queue delay (milliseconds)
Example
^^^^^^^
A simple example of Shaper using priorities.
.. code-block:: none
set traffic-policy shaper MY-HTB bandwidth '50mbit'
set traffic-policy shaper MY-HTB class 10 bandwidth '10%'
set traffic-policy shaper MY-HTB class 10 ceiling '15%'
set traffic-policy shaper MY-HTB class 10 match ADDRESS10 ip source address '192.168.10.0/24'
set traffic-policy shaper MY-HTB class 10 priority '0'
set traffic-policy shaper MY-HTB class 10 queue-type 'fair-queue'
set traffic-policy shaper MY-HTB class 20 bandwidth '10%'
set traffic-policy shaper MY-HTB class 20 ceiling '50%'
set traffic-policy shaper MY-HTB class 20 match ADDRESS20 ip source address '192.168.20.0/24'
set traffic-policy shaper MY-HTB class 20 priority '3'
set traffic-policy shaper MY-HTB class 20 queue-type 'fair-queue'
set traffic-policy shaper MY-HTB class 30 bandwidth '10%'
set traffic-policy shaper MY-HTB class 30 ceiling '50%'
set traffic-policy shaper MY-HTB class 30 match ADDRESS30 ip source address '192.168.30.0/24'
set traffic-policy shaper MY-HTB class 30 priority '5'
set traffic-policy shaper MY-HTB class 30 queue-type 'fair-queue'
set traffic-policy shaper MY-HTB default bandwidth '10%'
set traffic-policy shaper MY-HTB default ceiling '100%'
set traffic-policy shaper MY-HTB default priority '7'
set traffic-policy shaper MY-HTB default queue-type 'fair-queue'
.. _ingress-shaping:
The case of ingress shaping
===========================
| **Applies to:** Inbound traffic.
For the ingress traffic of an interface, there is only one policy you
can directly apply, a **Limiter** policy. This workaround lets you
redirect every incoming traffic to an in-between virtual interface to
which you will be able to apply there an outbound policy. That
in-between virtual interface" is possible because of the configuration
of an Intermediate Functional Block IFB_. That is how it is possible to
do an "ingress shaping".
.. code-block:: none
set traffic-policy shaper MY-INGRESS-SHAPING bandwidth 1000kbit
set traffic-policy shaper MY-INGRESS-SHAPING default bandwidth 1000kbit
set traffic-policy shaper MY-INGRESS-SHAPING default queue-type fair-queue
set interfaces input ifb0 traffic-policy out MY-INGRESS-SHAPING
set interfaces ethernet eth0 redirect ifb0
Applying a traffic policy
=========================
Once a traffic-policy is created, you can apply it to an interface:
.. code-block:: none
set interfaces etherhet eth0 traffic-policy out WAN-OUT
You can only apply one policy per interface and direction, but you can
have several policies working at the same time:
.. code-block:: none
set interfaces ethernet eth0 traffic-policy in WAN-IN
set interfaces etherhet eth0 traffic-policy out WAN-OUT
set interfaces etherhet eth1 traffic-policy out WAN-OUT
set interfaces ethernet eth2 traffic-policy out LAN-IN
set interfaces ethernet eth2 traffic-policy out LAN-OUT
.. _that can give you a great deal of flexibility: https://blog.vyos.io/using-the-policy-route-and-packet-marking-for-custom-qos-matches
.. _tc: https://en.wikipedia.org/wiki/Tc_(Linux)
.. _tocken bucket: https://en.wikipedia.org/wiki/Token_bucket
.. _HFSC: https://en.wikipedia.org/wiki/Hierarchical_fair-service_curve
.. _IFB: https://www.linuxfoundation.org/collaborate/workgroups/networking/ifb
|