Guidelines for Adding
Congestion Notification to Protocols that Encapsulate IPBTB54/77, Adastral ParkMartlesham HeathIpswichIP5 3REUK+44 1473 645196bob.briscoe@bt.comhttp://bobbriscoe.net/
Transport
Transport Area Working GroupCongestion Control and ManagementCongestion NotificationInformation SecurityTunnellingEncapsulation & DecapsulationProtocolECNLayeringThe purpose of this document is to guide the design of congestion
notification in any lower layer or tunnelling protocol that encapsulates
IP. The aim is for explicit congestion signals to propagate consistently
from lower layer protocols into IP. Then the IP internetwork layer can
act as a portability layer to carry congestion notification from
non-IP-aware congested nodes up to the transport layer (L4). Following
these guidelines should assure interworking between new lower layer
congestion notification mechanisms, whether specified by the IETF or
other standards bodies.Explicit Congestion Notification (ECN )
is defined in the IP header (v4 & v6) to allow a resource to notify
the onset of queue build-up without having to drop packets, by
explicitly marking a proportion of packets with the congestion
experienced (CE) codepoint.ECN removes nearly all
congestion loss and it cuts delays for two main reasons: i) it avoids
the delays recovering from congestion losses, which particularly
benefits small flows, making their completion time predictably short
; and ii) as ECN is used more widely by
end-systems, it will gradually remove the need to configure a degree of
delay into buffers before they start to notify congestion (the cause of
bufferbloat). The latter delay is because drop involves a trade-off
between sending a timely signal and trying to avoid impairment, whereas
ECN is solely a signal so there is no harm triggering it earlier.Some lower layer technologies (e.g. MPLS, Ethernet) are used to form
large subnetworks with IP-aware nodes only at the edges. Particularly
now that end-system protocols are finally being deployed without their
earlier deficiencies, even the buffers of well-provisioned interior
switches will often need to signal episodes of queuing. However, the
above benefits of ECN can only be fully realised if the relevant
subnetwork technology supports it. Propagation of ECN is defined for
MPLS , and is being defined for TRILL
, but it remains to be
defined for a number of other subnetwork technologies.Similarly, ECN propagation is yet to be defined for many tunnelling
protocols. defines how ECN should be
propagated for IP-in-IP and IPsec tunnels. However, as Section 9.3 of RFC3168
pointed out, ECN support will need to be defined for other tunnelling
protocols, e.g. L2TP , GRE [, ], PPTP and GTP
[, , ].The purpose of this document is to guide the addition of congestion
notification to any subnet technology or tunnelling protocol, so that
lower layer equipment can signal congestion explicitly and it will
propagate consistently into encapsulated (higher layer) headers,
otherwise the signals will not reach their ultimate destination.Incremental deployment is the most tricky aspect when adding support
for ECN. The original ECN protocol in IP
was carefully designed so that a congested buffer would not mark a
packet (rather than drop it) unless both source and destination hosts
were ECN-capable. Otherwise its congestion markings would never be
detected and congestion would just deteriorate further. However, to
support congestion marking below the IP layer, it is not sufficient to
only check that the two end-points support ECN; correct operation also
depends on the decapsulator propagating congestion notifications
faithfully. Otherwise, a legacy decapsulator might silently fail to
propagate any ECN signals from the outer to the forwarded header. Then
the lost signals would never be detected and again congestion would
deteriorate further. The guidelines given later require protocol
designers to carefully consider incremental deployment, and suggest
various safe approaches for different circumstances.Of course, the IETF does not have standards authority over every link
layer protocol. So this document gives guidelines for designing
propagation of congestion notification across the interface between IP
and protocols that may encapsulate IP (i.e. that can be layered beneath
IP). Each lower layer technology will exhibit different issues and
compromises, so the IETF or the relevant standards body must be free to
define the specifics of each lower layer congestion notification scheme.
Nonetheless, if the guidelines are followed, congestion notification
should interwork between different technologies, using IP in its role as
a 'portability layer'.It has not been possible to give common guidelines for all lower
layer technologies, because they do not all fit a common pattern.
Instead they have been divided into a few distinct modes of operation:
Feed-Forward-and-Upward, Feed-Upward-and-Forward, Feed-Backward and
Null. These are described in , then
in the following sections separate guidelines are given for each
mode.This document updates the advice to subnetwork designers about ECN in
Section 13 of .This document only concerns wire protocol processing of explicit
notification of congestion and makes no changes or recommendations
concerning algorithms for congestion marking or congestion
response.This document focuses on the congestion notification interface
between IP (v4 or v6) and lower layer protocols that can encapsulate
IP. However, it is likely that the guidelines will also be useful when
a lower layer protocol or tunnel encapsulates itself (e.g. Ethernet
MAC in MAC ) or when it
encapsulates other protocols.The key words "MUST", "MUST NOT", "REQUIRED", "SHALL", "SHALL NOT",
"SHOULD", "SHOULD NOT", "RECOMMENDED", "MAY", and "OPTIONAL" in this
document are to be interpreted as described in RFC 2119 .Further terminology used within this document:Information that is
delivered as a unit among peer entities of a layered network
consisting of protocol control information (typically a header) and
possibly user data (payload) of that layer. The scope of this
document includes layer 2 and layer 3 networks, where the PDU is
respectively termed a frame or a packet (or a cell in ATM). PDU is a
general term for any of these. This definition also includes a
payload with a shim header lying somewhere between layer 2 &
3.The end-to-end transmission control
function, conventionally considered at layer-4 in the OSI reference
model. Given the audience for this document will often use the word
transport to mean low level bit carriage, whenever the term is used
it will be qualified, e.g. 'L4 transport'.The link or tunnel endpoint function
that adds an outer header to a PDU (also termed the 'link ingress',
the 'subnet ingress', the 'ingress tunnel endpoint' or just the
'ingress' where the context is clear).The link or tunnel endpoint function
that removes an outer header from a PDU (also termed the 'link
egress', the 'subnet egress', the 'egress tunnel endpoint' or just
the 'egress' where the context is clear).The header of an arriving PDU before
encapsulation.The header added to encapsulate a
PDU.The header encapsulated by the outer
header.The header forwarded by the
decapsulator.Congestion Experienced ECN-Capable Transport Not ECN-Capable Transport A PDU that is part of a feedback loop within
which the nodes necessary to propagate explicit congestion
notifications back to the load regulator are ECN-capable. This is
intended to be a general term for a PDU at any layer, not just an IP
PDU. An IP packet with a non-zero ECN field would be an ECN-PDU, but
the term is intended to also be used to describe PDUs of protocols
that encapsulate IP packets, where it has been checked that the
necessary egress nodes and endpoints in the feedback loop for that
PDU will propagate congestion notification.A PDU that is part of a feedback-loop
within which some nodes necessary to propagate explicit congestion
notifications back to the load regulator are not ECN-capable.For each flow of PDUs, the transport
function that is capable of controlling the data rate. Typically
located at the data source, but in-path nodes can regulate load in
some congestion control arrangements (e.g. admission control or
policing nodes). Note the term "a function capable of controlling
the load" deliberately includes a transport that doesn't actually
control the load but ought to (e.g. an application without
congestion control that uses UDP).The location of the function on
the path that initialised the values of all congestion notification
fields in a sequence of packets, before any are set to the
congestion experienced (CE) codepoint if they experience congestion
further downstream. Typically the original data source at
layer-4.This section sets down the different modes by which information is
passed between the lower layer and the higher one. It acts as a
reference framework for the following sections, which give normative
guidelines for designers of explicit congestion notification protocols,
taking each mode separately in turn:Nodes feed forward congestion
notification towards the destination within the lower layer then up
the layers (like IP does). The following local optimisation is
possible:A lower layer switch feeds-up
congestion notification directly into the ECN field in the
higher layer (IP) header, irrespective of whether it is at the
egress of a subnet.Nodes feed back congestion signals
towards the ingress of the lower layer and (optionally) attempt to
control congestion within their own layer.Nodes cannot experience congestion at the lower
layer except at ingress nodes that are also IP-aware (or
equivalently higher-layer-aware).Many subnet technologies are based on self-contained protocol data
units (PDUs) or frames sent unreliably. They provide no feedback
channel at the subnetwork layer, instead relying on higher layers
(e.g. TCP) to feed back loss signals.In these cases, ECN may best be supported by standardising explicit
notification of congestion into the specific link layer protocol. It
will then also be necessary to define how the egress of the lower
layer subnet propagates this explicit signal into the forwarded upper
layer (IP) header. It can then continue forwards until it finally
reaches the destination transport (at L4). Then typically the
destination will feed this congestion notification back to the source
transport using an end-to-end protocol (e.g. TCP).This mode is illustrated in . Along the middle of
the figure, layers 2, 3 & 4 of the protocol stack are shown, and
one packet is shown along the bottom as it progresses across the
network from source to destination, crossing two subnets connected by
a router, and crossing two switches on the path across each subnet.
Congestion at the output of the first switch (shown as *) leads to a
congestion marking in the L2 header (shown as C in the illustration of
the packet). The chevrons show the progress of the resulting
congestion indication. It is propagated from link to link across the
subnet in the L2 header, then when the router removes the marked L2
header, it propagates the marking up into the L3 (IP) header. The
router forwards the marked L3 header into subnet 2, and when it adds a
new L2 header it copies the L3 marking into the L2 header as well, as
shown by the 'C's in both layers (assuming the technology of subnet 2
also supports explicit congestion marking).Note that there is no implication that each 'C' marking is encoded
the same; a different encoding might be used for the 'C' marking in
each protocol.Finally, for completeness, we show the L3 marking arriving at the
destination, where the host transport protocol (e.g. TCP) feeds it
back to the source in the L4 acknowledgement (the 'C' at L4 in the
packet at the top of the diagram).Of course, modern networks are rarely as simple as this text-book
example, often involving multiple nested layers. Nonetheless, the
example illustrates the general idea of feeding congestion
notification forward then upward whenever a header is removed at the
egress of a subnet.Note that the FECN (forward ECN) bit in Frame Relay and the
explicit forward congestion indication (EFCI ) bit in ATM user data cells follow a
feed-forward pattern. However, in ATM, this is only as part of a
feed-forward-and-backward pattern at the lower layer, not
feed-forward-and-up out of the lower layer—the intention was
never to interface to IP ECN at the subnet egress. To our knowledge,
Frame Relay FECN is solely used to detect where more capacity should
be provisioned .Ethernet is particularly difficult to extend incrementally to
support explicit congestion notification. One way to support ECN in
such cases has been to use so called 'layer-3 switches'. These are
Ethernet switches that bury into the Ethernet payload to find an IP
header and manipulate or act on certain IP fields (specifically
Diffserv & ECN). For instance, in Data Center TCP , layer-3 switches are configured to mark the
ECN field of the IP header within the Ethernet payload when their
output buffer becomes congested. With respect to switching, a layer-3
switch acts solely on the addresses in the Ethernet header; it doesn't
use IP addresses, and it doesn't decrement the TTL field in the IP
header.By comparing with , it can be seen that
subnet E (perhaps a subnet of layer-3 Ethernet switches) works in
feed-up-and-forward mode by notifying congestion directly into L3 at
the point of congestion, even though the congested switch does not
otherwise act at L3. In this example, the technology in subnet F (e.g.
MPLS) does support ECN natively, so when the router adds the layer-2
header it copies the ECN marking from L3 to L2 as well.In some layer 2 technologies, explicit congestion notification has
been defined for use internally within the subnet with its own
feedback and load regulation, but typically the interface with IP for
ECN has not been defined.For instance, for the available bit-rate (ABR) service in ATM, the
relative rate mechanism was one of the more popular mechanisms for
managing traffic, tending to supersede earlier designs. In this
approach ATM switches send special resource management (RM) cells in
both the forward and backward directions to control the ingress rate
of user data into a virtual circuit. If a switch buffer is approaching
congestion or congested it sends an RM cell back towards the ingress
with respectively the No Increase (NI) or Congestion Indication (CI)
bit set in its message type field .
The ingress then holds or decreases its sending bit-rate
accordingly.ATM's feed-backward approach doesn't fit well when layered beneath
IP's feed-forward approach—unless the initial data source is the
same node as the ATM ingress. shows the feed-backward
approach being used in subnet H. If the final switch on the path is
congested (*), it doesn't feed-forward any congestion indications on
packet (U). Instead it sends a control cell (V) back to the router at
the ATM ingress.However, the backward feedback doesn't reach the original data
source directly because IP doesn't support backward feedback (and
subnet G is independent of subnet H). Instead, the router in the
middle throttles down its sending rate but the original data source
doesn't reduce its rate. The resulting rate mismatch causes the middle
router's buffer at layer 3 to back up until it becomes congested,
which it signals forwards on later data packets at layer 3 (e.g.
packet W). Note that the forward signal from the middle router is not
triggered directly by the backward signal. Rather, it is triggered by
congestion resulting from the middle router's mismatched rate response
to the backward signal.In response to this later forward signalling, end-to-end feedback
at layer-4 finally completes the tortuous path of congestion
indications back to the origin data source, as before.Often link and physical layer resources are 'non-blocking' by
design. In these cases congestion notification may be implemented but
it does not need to be deployed at the lower layer; ECN in IP would be
sufficient.A degenerate example is a point-to-point Ethernet link. Excess
loading of the link merely causes the queue from the higher layer to
back up, while the lower layer remains immune to congestion. Even a
whole meshed subnetwork can be made immune to interior congestion by
limiting ingress capacity and careful sizing of links, particularly if
multi-path routing is used to ensure even worst-case patterns of load
cannot congest any link.These guidelines are consistent with the guidelines on the design of
alternate schemes for IP tunnelling of the ECN field and the more general best current practice for
the design of alternate ECN schemes given in .The capitalised term 'SHOULD (NOT)' has often been used in preference
to 'MUST (NOT)' because it is difficult to know the compromises that
will be necessary in each protocol design. If a particular protocol
design chooses to contradict a 'SHOULD (NOT)' given in the advice below,
it MUST include a sound justification.A lower layer (or subnet) congestion notification protocolSHOULD NOT apply explicit congestion notifications to PDUs that
are destined for legacy layer-4 transport implementations that
will not understand ECN, andSHOULD NOT apply explicit congestion notifications to PDUs that
are destined for a legacy subnet egress that will fail to
propagate them onward into the higher layer.We use the term ECN-PDUs for a PDU on a feedback
loop that will propagate congestion notification properly because
it meets both these criteria. And a Not-ECN-PDU is a PDU on a
feedback loop that does not meet both criteria, and will therefore
not propagate congestion notification properly. A corollary of the
above is that a lower layer congestion notification protocol:SHOULD be able to distinguish ECN-PDUs from Not-ECN-PDUs.In IP, if the ECN field in each PDU is cleared to the Not-ECT (not
ECN-capable transport) codepoint, it indicates that the L4 transport
will not understand congestion markings. A congested buffer must not
mark these Not-ECT PDUs, and therefore has to drop some. The mechanism
a lower layer uses to distinguish the ECN-capability of PDUs need not
mimic that of IP, but it should achieve the same outcome. For
instance, ECN-capable feedback loops might use PDUs that are
identified by a particular set of labels or tags. Alternatively,
logical link protocols that use flow state might determine whether a
PDU can be congestion marked by checking for ECN-support in the flow
state.The per-domain checking of ECN support in MPLS is a good example of a way to avoid sending
congestion markings to transports that will not understand
them—without using any header space in the subnet protocol.In MPLS, header space is extremely limited, therefore RFC5129 does
not provide a field in the MPLS header to indicate whether the PDU is
an ECN-PDU or a Not-ECN-PDU. Instead, interior nodes in a domain are
allowed to set explicit congestion indications without checking
whether the PDU is destined for a transport that will understand them.
Nonetheless, this is made safe by requiring that the network operator
upgrades all decapsulating edges of a whole domain at once, if any
switch within the domain is configured to mark rather than drop during
congestion. Therefore, there will be an implementation of an
ECN-capable decapsulator on any edge node that might decapsulate a
packet, which will check whether the higher layer transport is
ECN-capable. When decapsulating a CE-marked packet, if the
decapsulator discovers that the higher layer (inner header) indicates
the transport is not ECN-capable, it drops the packet on behalf of the
earlier congested node (see Decapsulation Guideline in ).Note that it was only appropriate to define such an incremental
deployment strategy because MPLS is targeted solely at professional
operators, who can be expected to ensure that a whole subnetwork is
consistently configured. This strategy might not be appropriate for
other link technologies targeted at zero-configuration deployment or
deployment by the general public (e.g. Ethernet). For such
'plug-and-play' environments it will be necessary to invent a failsafe
approach that ensures congestion markings will never fall into black
holes, no matter how inconsistently a system is put together.
Alternatively, congestion notification relying on correct system
configuration could be confined to flavours of Ethernet intended only
for professional network operators, such as IEEE 802.1ah Provider
Backbone Bridges (PBB).Note that these guidelines do not require the subnet wire protocol
to be changed at all to accommodate congestion notification. Another
way to add congestion notification without consuming header space in
the subnet protocol might be to use a control plane protocol in
parallel.Egress Capability Check: A subnet ingress needs to be sure that
the corresponding egress of a subnet will propagate any congestion
notification added to the outer header across the subnet. This is
necessary in addition to checking that an incoming PDU indicates
an ECN-capable (L4) transport. Examples of how this guarantee
might be provided include:by configuration (e.g. if any label switches in a domain
support ECN marking, requires
all egress nodes to have been configured to propagate ECN)by the ingress explicitly checking that the egress
propagates ECN (e.g. TRILL uses IS-IS to check path
capabilities before using critical options )by inherent design of the protocol (e.g. by encoding ECN
marking on the outer header in such a way that a legacy egress
that does not understand ECN will consider the PDU corrupt and
discard it, thus at least propagating a form of congestion
signal).If the ingress cannot guarantee that the egress will
propagate congestion notification, the ingress SHOULD disable ECN
when it forwards the PDU at the lower layer. An example of how the
ingress might disable ECN at the lower layer would be by setting
the outer header of the PDU to identify it as a Not-ECN-PDU.Standard Congestion Monitoring
Baseline: Once the ingress to a subnet has established that the
egress will correctly propagate ECN, on encapsulation it SHOULD
encode the same level of congestion in outer headers as is
arriving in incoming headers. For example it could copy any
incoming congestion notification into the outer header of the
lower layer protocol.This ensures that
all outer headers reflect congestion accumulated along the whole
upstream path, not just since the ingress of the subnet. More
precisely, congestion notifications in outer headers SHOULD
reflect congestion experienced along the whole path since the node
that regulates the load for that path (the Load Regulator,
typically the data source) and no other node should re-initialise
the amount of CE markings to zero along the way. This guideline is intended to ensure that any
bulk congestion monitoring of outer headers (e.g. by a network
management node monitoring ECN in passing frames) is most
meaningful. For instance, if an operator measures CE in 0.4% of
passing packets, this information is only useful if the operator
knows where the proportion of CE markings was last initialised to
0% (the Congestion Baseline). Such monitoring information will not
be useful if some subnet ingress nodes reset all outer CE markings
while others copy incoming CE markings into the outer.Most information can be extracted if the
Congestion Baseline is standardised at the node that is regulating
the load (the Load Regulator—typically the data source).
Then the operator can measure both congestion since the Load
Regulator, and congestion since the subnet ingress. The latter can
be measured by subtracting the level of CE markings on inner
headers from that on outer headers.A subnet egress SHOULD NOT simply copy congestion notification from
outer headers to the forwarded header. It SHOULD calculate the
outgoing congestion notification field from the inner and outer
headers, using the following rules. If there is any conflict, rules
earlier in the list take precedence over rules later in the list:If the arriving inner
header is a Not-ECN-PDU it implies the L4 transport will not
understand explicit congestion markings. Then:If the outer header carries an explicit congestion marking,
the packet SHOULD be dropped—the only indication of
congestion that the L4 transport will understand.If the outer is an ECN-PDU that carries no indication of
congestion or a Not-ECN-PDU the PDU SHOULD be forwarded, but
still as a Not-ECN-PDU.If the outer header does not support explicit congestion
notification (a Not-ECN-PDU), but the inner header does (an
ECN-PDU), the inner header SHOULD be forwarded unchanged.In some lower layer protocols congestion may be signalled as a
numerical level, such as in the control frames of quantised
congestion notification . If
such an encoding encapsulates an ECN-capable IP packet, a function
will be needed to convert the quantised congestion level into the
frequency of congestion markings in outgoing IP packets.Congestion indications may be encoded by a severity level. For
instance increasing levels of congestion might be encoded by
numerically increasing indications, e.g. pre-congestion
notification (PCN) can be encoded in each PDU at three severity
levels in IP or MPLS .If the arriving inner header is an ECN-PDU, where
the inner and outer headers carry indications of congestion of
different severity, the more severe indication SHOULD be forwarded
in preference to the less severe. Obviously, if the severities in
both inner and outer are the same, the same severity should be
forwarded.The inner and outer headers might carry a combination of
congestion notification fields that should not be possible given
any currently used protocol transitions. For instance, if
Encapsulation Guideline
in had been
followed, it should not be possible to have a less severe
indication of congestion in the outer than in the inner. It MAY be
appropriate to log unexpected combinations of headers and possibly
raise an alarm. If a safe outgoing codepoint can be defined for
such a PDU, the PDU SHOULD be forwarded rather than dropped.
Some implementers discard PDUs with
currently unused combinations of headers just in case they
represent an attack. However, an approach using alarms and
policy-mediated drop is preferable to hard-coded drop, so that
operators can keep track of possible attacks but currently unused
combinations are not precluded from future use through new
standards actions.Where framing boundaries are different between two layers,
congestion indications SHOULD be propagated on the basis that a
congestion indication on a PDU applies to all the octets in the PDU.
On average, an encapsulator or decapsulator SHOULD approximately
preserve the number of marked octets arriving and leaving (counting
the size of inner headers, but not added encapsulating headers).The next departing frame SHOULD be immediately marked even if only
enough incoming marked octets have arrived for part of the departing
frame. This ensures that any outstanding congestion marked octets are
propagated immediately, rather than held back waiting for a frame no
bigger than the outstanding marked octets—which might involve a
long wait.For instance, an algorithm for marking departing frames could
maintain a counter representing the balance of arriving marked octets
minus departing marked octets. It adds the size of every marked frame
that arrives and if the counter is positive it marks the next frame to
depart and subtracts its size from the counter. This will often leave
a negative remainder in the counter, which is deliberate.Marking the IP header while switching at layer-2 (by using a layer-3
switch) seems to represent a layering violation. However, it can be
considered as a benign optimisation if the guidelines below are
followed. Feed-up-and-forward is certainly not a general alternative to
implementing feed-forward congestion notification in the lower layer,
because:IPv4 and IPv6 are not the only layer-3 protocols that might be
encapsulated by lower layer protocolsLink-layer encryption might be in use, making the layer-2 payload
inaccessibleMany Ethernet switches do not have 'layer-3 switch' capabilities
so they cannot read and modify an IP payloadIt might be costly to find an IP header (v4 or v6) when it may be
encapsulated by more than one Ethernet header (e.g. when using
multiple encapsulations of MAC in MAC ).Nonetheless, configuring a layer-3 switch to look for an ECN field in
an encapsulated IP header is a useful optimisation. If the
implementation follows the guidelines below, this optimisation does not
have to be confined to a controlled environment such as within a data
centre; it could usefully be applied on any network—even if the
operator is not sure whether the above issues will never apply:If a native lower-layer congestion notification mechanism exists
for a subnet technology, it is safe to mix feed-up-and-forward with
feed-forward-and-up on other switches in the same subnet. However,
it will generally be more efficient to use the native mechanism.The depth of search for an IP header SHOULD be limited. If an IP
header is not found soon enough, or an unrecognised or unreadable
header is encountered, the switch SHOULD resort to an alternative
means of signalling congestion (e.g. drop, or the native lower layer
mechanism if available).It is sufficient to use the first IP header found in the stack;
the egress of the relevant tunnel can propagate congestion
notification upwards to any more deeply encapsulated IP headers
later.It can be seen from that
congestion notification in a subnet using feed-backward mode has
generally not been designed to directly coupled with IP layer congestion
notification. The subnet attempts to minimise congestion internally, and
if the incoming load at the ingress exceeds capacity through the subnet,
the layer 3 buffer into the ingress backs up. Thus, a feed-backward mode
subnet is in some sense similar to a null mode subnet, in that there is
no need for any direct interaction between the subnet and higher layer
congestion notification. Therefore no detailed protocol design
guidelines are appropriate. Nonetheless, a more general guideline is
appropriate: A subnetwork technology intended to eventually interface to IP
SHOULD NOT be designed using only the feed-backward mode, which is
certainly best for a stand-alone subnet, but would need to be
modified to work efficiently as part of the wider Internet, because
IP uses feed-forward-and-up mode.The feed-backward approach does at least work beneath IP, but it can
result in very inefficient and sluggish congestion control—except
if it is confined to the subnet directly connected to the original data
source, when it is faster than feed-forward. It would be possible to
design a protocol that could work in feed-backward mode for paths that
only cross one subnet, and in feed-forward-and-up mode for paths that
cross subnets.In the early days of TCP/IP, a similar feed-backward approach was
tried for explicit congestion signalling, using source-quench (SQ) ICMP
control packets. However, SQ fell out of favour and is now formally
deprecated . The main problem was that it
is hard for a data source to tell the difference between a spoofed SQ
message and a quench request from a genuine buffer on the path. It is
also hard for a lower layer buffer to address an SQ message to the
original source, which may be buried within many layers of headers, and
possibly encrypted.Quantised congestion notification (QCN—also known as backward
congestion notification or BCN) uses
a feed-backward mode very similar to ATM. However, QCN confines its
applicability to scenarios where all endpoints are directly attached by
the same Ethernet technology, and is used for example in server area
networks (SANs). If a QCN subnet were connected into a wider IP-based
internetwork (e.g. when attempting to interconnect SANs within multiple
data centres) it would suffer the same inefficiency as shown in .This memo includes no request to IANA.{TBA}`{TBA}Thanks to Gorry Fairhurst for extensive initial review.Bob Briscoe produced early drafts while partly funded by Trilogy, a
research project (ICT-216372) supported by the European Community under
its Seventh Framework Programme. The views expressed here are those of
the author only.Comments and questions are encouraged and very welcome. They can be
addressed to the IETF Transport Area working group mailing list
<tsvwg@ietf.org>, and/or to the authors.GPRS Tunnelling Protocol (GTP) across the Gn and Gp
interface3GPPGeneral Packet Radio System (GPRS) Tunnelling Protocol User
Plane (GTPv1-U)3GPPEvolved General Packet Radio Service (GPRS) Tunnelling
Protocol for Control plane (GTPv2-C)3GPPUnderstanding the Available Bit Rate (ABR) Service Category
for ATM VCsCisco[GF] Concern that certain guidelines warrant a MUST (NOT) rather
than a SHOULD (NOT). Given the guidelines say that if any SHOULD
(NOT)s are not followed, a strong justification will be needed, they
have been left as SHOULD (NOT) pending further list discussion. In
particular:If inner is a Not-ECN-PDU and Outer is CE (or highest
severity congestion level), MUST (not SHOULD) drop?[GF] Impact of Diffserv on alternate marking schemes (referring
to RFC3168, RFC4774 & RFC2983)Security ConsiderationsIntended status: BCP (was Informational) & updates 3819
added.Briefer Introduction: Introductory para justifying benefits
of ECN. Moved all but a brief enumeration of modes of operation
to their own new section (from both Intro & Scope).
Introduced incr. deployment as most tricky part.Tightened & added to terminology sectionStructured with Modes of Operation, then Guidelines section
for each mode.Tightened up guideline text to remove vagueness / passive
voice / ambiguity and highlight main guidelines as numbered
items.Added Outstanding Document Issues AppendixUpdated references