CAKE

Section: Linux (8)
Updated: 19 July 2018
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NAME

CAKE - Common Applications Kept Enhanced (CAKE)  

SYNOPSIS

tc qdisc ... cake
[ bandwidth RATE | unlimited* | autorate-ingress ]
[ rtt TIME | datacentre | lan | metro | regional | internet* | oceanic | satellite | interplanetary ]
[ besteffort | diffserv8 | diffserv4 | diffserv3* ]
[ flowblind | srchost | dsthost | hosts | flows | dual-srchost | dual-dsthost | triple-isolate* ]
[ nat | nonat* ]
[ wash | nowash* ]
[ split-gso* | no-split-gso ]
[ ack-filter | ack-filter-aggressive | no-ack-filter* ]
[ memlimit LIMIT ]
[ ptm | atm | noatm* ]
[ overhead N | conservative | raw* ]
[ mpu N ]
[ ingress | egress* ]
(* marks defaults)

 

DESCRIPTION

CAKE (Common Applications Kept Enhanced) is a shaping-capable queue discipline which uses both AQM and FQ. It combines COBALT, which is an AQM algorithm combining Codel and BLUE, a shaper which operates in deficit mode, and a variant of DRR++ for flow isolation. 8-way set-associative hashing is used to virtually eliminate hash collisions. Priority queuing is available through a simplified diffserv implementation. Overhead compensation for various encapsulation schemes is tightly integrated.

All settings are optional; the default settings are chosen to be sensible in most common deployments. Most people will only need to set the bandwidth parameter to get useful results, but reading the Overhead Compensation and Round Trip Time sections is strongly encouraged.

 

SHAPER PARAMETERS

CAKE uses a deficit-mode shaper, which does not exhibit the initial burst typical of token-bucket shapers. It will automatically burst precisely as much as required to maintain the configured throughput. As such, it is very straightforward to configure.

unlimited (default)
       No limit on the bandwidth.

bandwidth RATE
       Set the shaper bandwidth. See
tc(8) or examples below for details of the RATE value.

autorate-ingress
       Automatic capacity estimation based on traffic arriving at this qdisc.
This is most likely to be useful with cellular links, which tend to change quality randomly. A bandwidth parameter can be used in conjunction to specify an initial estimate. The shaper will periodically be set to a bandwidth slightly below the estimated rate. This estimator cannot estimate the bandwidth of links downstream of itself.

 

OVERHEAD COMPENSATION PARAMETERS

The size of each packet on the wire may differ from that seen by Linux. The following parameters allow CAKE to compensate for this difference by internally considering each packet to be bigger than Linux informs it. To assist users who are not expert network engineers, keywords have been provided to represent a number of common link technologies.

 

Manual Overhead Specification

overhead BYTES
       Adds BYTES to the size of each packet. BYTES may be negative; values
between -64 and 256 (inclusive) are accepted.

mpu BYTES
       Rounds each packet (including overhead) up to a minimum length
BYTES. BYTES may not be negative; values between 0 and 256 (inclusive) are accepted.

atm
       Compensates for ATM cell framing, which is normally found on ADSL links.
This is performed after the overhead parameter above. ATM uses fixed 53-byte cells, each of which can carry 48 bytes payload.

ptm
       Compensates for PTM encoding, which is normally found on VDSL2 links and
uses a 64b/65b encoding scheme. It is even more efficient to simply derate the specified shaper bandwidth by a factor of 64/65 or 0.984. See ITU G.992.3 Annex N and IEEE 802.3 Section 61.3 for details.

noatm
       Disables ATM and PTM compensation.

 

Failsafe Overhead Keywords

These two keywords are provided for quick-and-dirty setup. Use them if you can't be bothered to read the rest of this section.

raw (default)
       Turns off all overhead compensation in CAKE. The packet size reported
by Linux will be used directly.

       Other overhead keywords may be added after "raw". The effect of this is
to make the overhead compensation operate relative to the reported packet size, not the underlying IP packet size.

conservative
       Compensates for more overhead than is likely to occur on any
widely-deployed link technology.
       Equivalent to
overhead 48 atm.

 

ADSL Overhead Keywords

Most ADSL modems have a way to check which framing scheme is in use. Often this is also specified in the settings document provided by the ISP. The keywords in this section are intended to correspond with these sources of information. All of them implicitly set the atm flag.

pppoa-vcmux
       Equivalent to
overhead 10 atm

pppoa-llc
       Equivalent to
overhead 14 atm

pppoe-vcmux
       Equivalent to
overhead 32 atm

pppoe-llcsnap
       Equivalent to
overhead 40 atm

bridged-vcmux
       Equivalent to
overhead 24 atm

bridged-llcsnap
       Equivalent to
overhead 32 atm

ipoa-vcmux
       Equivalent to
overhead 8 atm

ipoa-llcsnap
       Equivalent to
overhead 16 atm

See also the Ethernet Correction Factors section below.

 

VDSL2 Overhead Keywords

ATM was dropped from VDSL2 in favour of PTM, which is a much more straightforward framing scheme. Some ISPs retained PPPoE for compatibility with their existing back-end systems.

pppoe-ptm
       Equivalent to
overhead 30 ptm


       PPPoE: 2B PPP + 6B PPPoE +

       ETHERNET: 6B dest MAC + 6B src MAC + 2B ethertype + 4B Frame Check Sequence +

       PTM: 1B Start of Frame (S) + 1B End of Frame (Ck) + 2B TC-CRC (PTM-FCS)

bridged-ptm
       Equivalent to
overhead 22 ptm
       ETHERNET: 6B dest MAC + 6B src MAC + 2B ethertype + 4B Frame Check Sequence +

       PTM: 1B Start of Frame (S) + 1B End of Frame (Ck) + 2B TC-CRC (PTM-FCS)

See also the Ethernet Correction Factors section below.

 

DOCSIS Cable Overhead Keyword

DOCSIS is the universal standard for providing Internet service over cable-TV infrastructure.

In this case, the actual on-wire overhead is less important than the packet size the head-end equipment uses for shaping and metering. This is specified to be an Ethernet frame including the CRC (aka FCS).

docsis
       Equivalent to
overhead 18 mpu 64 noatm

 

Ethernet Overhead Keywords

ethernet
       Accounts for Ethernet's preamble, inter-frame gap, and Frame Check
Sequence. Use this keyword when the bottleneck being shaped for is an actual Ethernet cable.
       Equivalent to
overhead 38 mpu 84 noatm

ether-vlan
       Adds 4 bytes to the overhead compensation, accounting for an IEEE 802.1Q
VLAN header appended to the Ethernet frame header. NB: Some ISPs use one or even two of these within PPPoE; this keyword may be repeated as necessary to express this.

 

ROUND TRIP TIME PARAMETERS

Active Queue Management (AQM) consists of embedding congestion signals in the packet flow, which receivers use to instruct senders to slow down when the queue is persistently occupied. CAKE uses ECN signalling when available, and packet drops otherwise, according to a combination of the Codel and BLUE AQM algorithms called COBALT.

Very short latencies require a very rapid AQM response to adequately control latency. However, such a rapid response tends to impair throughput when the actual RTT is relatively long. CAKE allows specifying the RTT it assumes for tuning various parameters. Actual RTTs within an order of magnitude of this will generally work well for both throughput and latency management.

At the 'lan' setting and below, the time constants are similar in magnitude to the jitter in the Linux kernel itself, so congestion might be signalled prematurely. The flows will then become sparse and total throughput reduced, leaving little or no back-pressure for the fairness logic to work against. Use the "metro" setting for local lans unless you have a custom kernel.

rtt TIME
       Manually specify an RTT.

datacentre
       For extremely high-performance 10GigE+ networks only. Equivalent to
rtt 100us.

lan
       For pure Ethernet (not Wi-Fi) networks, at home or in the office. Don't
use this when shaping for an Internet access link. Equivalent to rtt 1ms.

metro
       For traffic mostly within a single city. Equivalent to
rtt 10ms.

regional
       For traffic mostly within a European-sized country. Equivalent to
rtt 30ms.

internet (default)
       This is suitable for most Internet traffic. Equivalent to
rtt 100ms.

oceanic
       For Internet traffic with generally above-average latency, such as that
suffered by Australasian residents. Equivalent to rtt 300ms.

satellite
       For traffic via geostationary satellites. Equivalent to
rtt 1000ms.

interplanetary
       So named because Jupiter is about 1 light-hour from Earth. Use this to
(almost) completely disable AQM actions. Equivalent to rtt 3600s.

 

FLOW ISOLATION PARAMETERS

With flow isolation enabled, CAKE places packets from different flows into different queues, each of which carries its own AQM state. Packets from each queue are then delivered fairly, according to a DRR++ algorithm which minimises latency for "sparse" flows. CAKE uses a set-associative hashing algorithm to minimise flow collisions.

These keywords specify whether fairness based on source address, destination address, individual flows, or any combination of those is desired.

flowblind
       Disables flow isolation; all traffic passes through a single queue for
each tin.

srchost
       Flows are defined only by source address. Could be useful on the egress
path of an ISP backhaul.

dsthost
       Flows are defined only by destination address. Could be useful on the
ingress path of an ISP backhaul.

hosts
       Flows are defined by source-destination host pairs. This is host
isolation, rather than flow isolation.

flows
       Flows are defined by the entire 5-tuple of source address, destination
address, transport protocol, source port and destination port. This is the type of flow isolation performed by SFQ and fq_codel.

dual-srchost
       Flows are defined by the 5-tuple, and fairness is applied first over
source addresses, then over individual flows. Good for use on egress traffic from a LAN to the internet, where it'll prevent any one LAN host from monopolising the uplink, regardless of the number of flows they use.

dual-dsthost
       Flows are defined by the 5-tuple, and fairness is applied first over
destination addresses, then over individual flows. Good for use on ingress traffic to a LAN from the internet, where it'll prevent any one LAN host from monopolising the downlink, regardless of the number of flows they use.

triple-isolate (default)
       Flows are defined by the 5-tuple, and fairness is applied over source
*and* destination addresses intelligently (ie. not merely by host-pairs), and also over individual flows. Use this if you're not certain whether to use dual-srchost or dual-dsthost; it'll do both jobs at once, preventing any one host on *either* side of the link from monopolising it with a large number of flows.

nat
       Instructs Cake to perform a NAT lookup before applying flow-isolation
rules, to determine the true addresses and port numbers of the packet, to improve fairness between hosts "inside" the NAT. This has no practical effect in "flowblind" or "flows" modes, or if NAT is performed on a different host.

nonat (default)
       Cake will not perform a NAT lookup. Flow isolation will be performed
using the addresses and port numbers directly visible to the interface Cake is attached to.

 

PRIORITY QUEUE PARAMETERS

CAKE can divide traffic into "tins" based on the Diffserv field. Each tin has its own independent set of flow-isolation queues, and is serviced based on a WRR algorithm. To avoid perverse Diffserv marking incentives, tin weights have a "priority sharing" value when bandwidth used by that tin is below a threshold, and a lower "bandwidth sharing" value when above. Bandwidth is compared against the threshold using the same algorithm as the deficit-mode shaper.

Detailed customisation of tin parameters is not provided. The following presets perform all necessary tuning, relative to the current shaper bandwidth and RTT settings.

besteffort
       Disables priority queuing by placing all traffic in one tin.

precedence
       Enables legacy interpretation of TOS "Precedence" field. Use of this
preset on the modern Internet is firmly discouraged.

diffserv4
       Provides a general-purpose Diffserv implementation with four tins:

               Bulk (CS1), 6.25% threshold, generally low priority.

               Best Effort (general), 100% threshold.

               Video (AF4x, AF3x, CS3, AF2x, CS2, TOS4, TOS1), 50% threshold.

               Voice (CS7, CS6, EF, VA, CS5, CS4), 25% threshold.

diffserv3 (default)
       Provides a simple, general-purpose Diffserv implementation with three tins:

               Bulk (CS1), 6.25% threshold, generally low priority.

               Best Effort (general), 100% threshold.

               Voice (CS7, CS6, EF, VA, TOS4), 25% threshold, reduced Codel interval.

 

OTHER PARAMETERS

memlimit LIMIT
       Limit the memory consumed by Cake to LIMIT bytes. Note that this does
not translate directly to queue size (so do not size this based on bandwidth delay product considerations, but rather on worst case acceptable memory consumption), as there is some overhead in the data structures containing the packets, especially for small packets.

        By default, the limit is calculated based on the bandwidth and RTT
settings.

wash


       Traffic entering your diffserv domain is frequently mis-marked in
transit from the perspective of your network, and traffic exiting yours may be mis-marked from the perspective of the transiting provider.

Apply the wash option to clear all extra diffserv (but not ECN bits), after priority queuing has taken place.

If you are shaping inbound, and cannot trust the diffserv markings (as is the case for Comcast Cable, among others), it is best to use a single queue "besteffort" mode with wash.

split-gso


       This option controls whether CAKE will split General Segmentation
Offload (GSO) super-packets into their on-the-wire components and dequeue them individually.


Super-packets are created by the networking stack to improve efficiency. However, because they are larger they take longer to dequeue, which translates to higher latency for competing flows, especially at lower bandwidths. CAKE defaults to splitting GSO packets to achieve the lowest possible latency. At link speeds higher than 10 Gbps, setting the no-split-gso parameter can increase the maximum achievable throughput by retaining the full GSO packets.

 

OVERRIDING CLASSIFICATION WITH TC FILTERS

CAKE supports overriding of its internal classification of packets through the tc filter mechanism. Packets can be assigned to different priority tins by setting the priority field on the skb, and the flow hashing can be overridden by setting the classid parameter.

Tin override



        To assign a priority tin, the major number of the priority field needs to match the qdisc handle of the cake instance; if it does, the minor number will be interpreted as the tin index. For example, to classify all ICMP packets as 'bulk', the following filter can be used:



        # tc qdisc replace dev eth0 handle 1: root cake diffserv3
        # tc filter add dev eth0 parent 1: protocol ip prio 1 \
          u32 match icmp type 0 0 action skbedit priority 1:1

Flow hash override



        To override flow hashing, the classid can be set. CAKE will interpret the major number of the classid as the host hash used in host isolation mode, and the minor number as the flow hash used for flow-based queueing. One or both of those can be set, and will be used if the relevant flow isolation parameter is set (i.e., the major number will be ignored if CAKE is not configured in hosts mode, and the minor number will be ignored if CAKE is not configured in flows mode).


This example will assign all ICMP packets to the first queue:



        # tc qdisc replace dev eth0 handle 1: root cake
        # tc filter add dev eth0 parent 1: protocol ip prio 1 \
          u32 match icmp type 0 0 classid 0:1


If only one of the host and flow overrides is set, CAKE will compute the other hash from the packet as normal. Note, however, that the host isolation mode works by assigning a host ID to the flow queue; so if overriding both host and flow, the same flow cannot have more than one host assigned. In addition, it is not possible to assign different source and destination host IDs through the override mechanism; if a host ID is assigned, it will be used as both source and destination host.

 

EXAMPLES

# tc qdisc delete root dev eth0
# tc qdisc add root dev eth0 cake bandwidth 100Mbit ethernet
# tc -s qdisc show dev eth0
qdisc cake 1: root refcnt 2 bandwidth 100Mbit diffserv3 triple-isolate rtt 100.0ms noatm overhead 38 mpu 84
 Sent 0 bytes 0 pkt (dropped 0, overlimits 0 requeues 0)
 backlog 0b 0p requeues 0
 memory used: 0b of 5000000b
 capacity estimate: 100Mbit
 min/max network layer size:        65535 /       0
 min/max overhead-adjusted size:    65535 /       0
 average network hdr offset:            0


                   Bulk  Best Effort        Voice
  thresh       6250Kbit      100Mbit       25Mbit
  target          5.0ms        5.0ms        5.0ms
  interval      100.0ms      100.0ms      100.0ms
  pk_delay          0us          0us          0us
  av_delay          0us          0us          0us
  sp_delay          0us          0us          0us
  pkts                0            0            0
  bytes               0            0            0
  way_inds            0            0            0
  way_miss            0            0            0
  way_cols            0            0            0
  drops               0            0            0
  marks               0            0            0
  ack_drop            0            0            0
  sp_flows            0            0            0
  bk_flows            0            0            0
  un_flows            0            0            0
  max_len             0            0            0
  quantum           300         1514          762

After some use:
# tc -s qdisc show dev eth0

qdisc cake 1: root refcnt 2 bandwidth 100Mbit diffserv3 triple-isolate rtt 100.0ms noatm overhead 38 mpu 84
 Sent 44709231 bytes 31931 pkt (dropped 45, overlimits 93782 requeues 0)
 backlog 33308b 22p requeues 0
 memory used: 292352b of 5000000b
 capacity estimate: 100Mbit
 min/max network layer size:           28 /    1500
 min/max overhead-adjusted size:       84 /    1538
 average network hdr offset:           14


                   Bulk  Best Effort        Voice
  thresh       6250Kbit      100Mbit       25Mbit
  target          5.0ms        5.0ms        5.0ms
  interval      100.0ms      100.0ms      100.0ms
  pk_delay        8.7ms        6.9ms        5.0ms
  av_delay        4.9ms        5.3ms        3.8ms
  sp_delay        727us        1.4ms        511us
  pkts             2590        21271         8137
  bytes         3081804     30302659     11426206
  way_inds            0           46            0
  way_miss            3           17            4
  way_cols            0            0            0
  drops              20           15           10
  marks               0            0            0
  ack_drop            0            0            0
  sp_flows            2            4            1
  bk_flows            1            2            1
  un_flows            0            0            0
  max_len          1514         1514         1514
  quantum           300         1514          762

 

SEE ALSO

tc(8), tc-codel(8), tc-fq_codel(8), tc-htb(8)

 

AUTHORS

Cake's principal author is Jonathan Morton, with contributions from Tony Ambardar, Kevin Darbyshire-Bryant, Toke Høiland-Jørgensen, Sebastian Moeller, Ryan Mounce, Dean Scarff, Nils Andreas Svee, and Dave Täht.

This manual page was written by Loganaden Velvindron. Please report corrections to the Linux Networking mailing list <netdev@vger.kernel.org>.


 

Index

NAME
SYNOPSIS
DESCRIPTION
SHAPER PARAMETERS
OVERHEAD COMPENSATION PARAMETERS
Manual Overhead Specification
Failsafe Overhead Keywords
ADSL Overhead Keywords
VDSL2 Overhead Keywords
DOCSIS Cable Overhead Keyword
Ethernet Overhead Keywords
ROUND TRIP TIME PARAMETERS
FLOW ISOLATION PARAMETERS
PRIORITY QUEUE PARAMETERS
OTHER PARAMETERS
OVERRIDING CLASSIFICATION WITH TC FILTERS
EXAMPLES
SEE ALSO
AUTHORS

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Time: 07:41:30 GMT, March 19, 2024