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Versions: (draft-fairhurst-tsvwg-circuit-breaker) 00 01 02 03 04 05 06 07 08 09 10 11 12 13 14 15 RFC 8084

TSVWG Working Group                                         G. Fairhurst
Internet-Draft                                    University of Aberdeen
Intended status: Best Current Practice                  October 07, 2015
Expires: April 9, 2016


                   Network Transport Circuit Breakers
                  draft-ietf-tsvwg-circuit-breaker-05

Abstract

   This document explains what is meant by the term "network transport
   Circuit Breaker" (CB).  It describes the need for circuit breakers
   when using network tunnels, and other non-congestion controlled
   applications, and explains where circuit breakers are, and are not,
   needed.  It also defines requirements for building a circuit breaker
   and the expected outcomes of using a circuit breaker within the
   Internet.

Status of This Memo

   This Internet-Draft is submitted in full conformance with the
   provisions of BCP 78 and BCP 79.

   Internet-Drafts are working documents of the Internet Engineering
   Task Force (IETF).  Note that other groups may also distribute
   working documents as Internet-Drafts.  The list of current Internet-
   Drafts is at http://datatracker.ietf.org/drafts/current/.

   Internet-Drafts are draft documents valid for a maximum of six months
   and may be updated, replaced, or obsoleted by other documents at any
   time.  It is inappropriate to use Internet-Drafts as reference
   material or to cite them other than as "work in progress."

   This Internet-Draft will expire on April 9, 2016.

Copyright Notice

   Copyright (c) 2015 IETF Trust and the persons identified as the
   document authors.  All rights reserved.

   This document is subject to BCP 78 and the IETF Trust's Legal
   Provisions Relating to IETF Documents
   (http://trustee.ietf.org/license-info) in effect on the date of
   publication of this document.  Please review these documents
   carefully, as they describe your rights and restrictions with respect
   to this document.  Code Components extracted from this document must
   include Simplified BSD License text as described in Section 4.e of



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   the Trust Legal Provisions and are provided without warranty as
   described in the Simplified BSD License.

Table of Contents

   1.  Introduction  . . . . . . . . . . . . . . . . . . . . . . . .   2
     1.1.  Types of Circuit-Breaker  . . . . . . . . . . . . . . . .   4
   2.  Terminology . . . . . . . . . . . . . . . . . . . . . . . . .   5
   3.  Design of a Circuit-Breaker (What makes a good circuit
       breaker?) . . . . . . . . . . . . . . . . . . . . . . . . . .   5
     3.1.  Functional Components . . . . . . . . . . . . . . . . . .   5
   4.  Requirements for a Network Transport Circuit Breaker  . . . .   8
     4.1.  Unidirectional Circuit Breakers over Controlled Paths . .  10
       4.1.1.  Use with a multicast control/routing protocol . . . .  10
       4.1.2.  Use with control protocols supporting pre-
               prosvisioned capacity . . . . . . . . . . . . . . . .  12
   5.  Examples of Circuit Breakers  . . . . . . . . . . . . . . . .  12
     5.1.  A Fast-Trip Circuit Breaker . . . . . . . . . . . . . . .  12
       5.1.1.  A Fast-Trip Circuit Breaker for RTP . . . . . . . . .  13
     5.2.  A Slow-trip Circuit Breaker . . . . . . . . . . . . . . .  13
     5.3.  A Managed Circuit Breaker . . . . . . . . . . . . . . . .  14
       5.3.1.  A Managed Circuit Breaker for SAToP Pseudo-Wires  . .  14
       5.3.2.  A Managed Circuit Breaker for Pseudowires (PWs) . . .  15
   6.  Examples where circuit breakers may not be needed.  . . . . .  15
     6.1.  CBs over pre-provisioned Capacity . . . . . . . . . . . .  15
     6.2.  CBs with tunnels carrying Congestion-Controlled Traffic .  16
     6.3.  CBs with Uni-directional Traffic and no Control Path  . .  16
   7.  Security Considerations . . . . . . . . . . . . . . . . . . .  17
   8.  IANA Considerations . . . . . . . . . . . . . . . . . . . . .  18
   9.  Acknowledgments . . . . . . . . . . . . . . . . . . . . . . .  18
   10. Revision Notes  . . . . . . . . . . . . . . . . . . . . . . .  18
   11. References  . . . . . . . . . . . . . . . . . . . . . . . . .  19
     11.1.  Normative References . . . . . . . . . . . . . . . . . .  19
     11.2.  Informative References . . . . . . . . . . . . . . . . .  19
   Author's Address  . . . . . . . . . . . . . . . . . . . . . . . .  21

1.  Introduction

   A network transport Circuit Breaker (CB) is an automatic mechanism
   that is used to estimate congestion caused by a flow, and to
   terminate (or significantly reduce the rate of) the flow when
   persistent congestion is detected.  This is a safety measure to
   prevent congestion collapse (starvation of network resources denying
   other flows from access to the Internet), essential for an Internet
   that is heterogeneous and for traffic that is hard to predict in
   advance.





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   The term "Circuit Breaker" originates in electricity supply, and has
   nothing to do with network circuits or virtual circuits.  In
   electricity supply, a Circuit Breaker is intended as a protection
   mechanism of last resort.  Under normal circumstances, a Circuit
   Breaker ought not to be triggered; it is designed to protect the
   supply network and attached equipment when there is overload.  Just
   as people do not expect the electrical circuit-breaker (or fuse) in
   their home to be triggered, except when there is a wiring fault or a
   problem with an electrical appliance.

   In networking, the Circuit Breaker principle can be used as a
   protection mechanism of last resort to avoid persistent congestion.
   Persistent congestion (also known as "congestion collapse") was a
   feature of the early Internet of the 1980s.  This resulted in excess
   traffic starving other connection from access to the Internet.  It
   was countered by the requirement to use congestion control (CC) by
   the Transmission Control Protocol (TCP) [Jacobsen88] [RFC1112].
   These mechanisms operate in Internet hosts to cause TCP connections
   to "back off" during congestion.  The introduction of a Congestion
   Controller in TCP (currently documented in [RFC5681] ensured the
   stability of the Internet, because it was able to detect congestion
   and promptly react.  This worked well while TCP was by far the
   dominant traffic in the Internet, and most TCP flows were long-lived
   (ensuring that they could detect and respond to congestion before the
   flows terminated).  This is no longer the case, and non-congestion
   controlled traffic, including many applications of the User Datagram
   Protocol (UDP) can form a significant proportion of the total traffic
   traversing a link.  The current Internet therefore requires that non-
   congestion controlled traffic needs to be considered to avoid
   congestion collapse.

   There are important differences between a transport circuit-breaker
   and a congestion-control method.  Specifically, congestion control
   (as implemented in TCP, SCTP, and DCCP) operates on the timescale on
   the order of a packet round-trip-time (RTT), the time from sender to
   destination and return.  Congestion control methods are able to react
   to a single packet loss/marking and reduce the transmission rate for
   each loss or congestion event.  The goal is usually to limit the
   maximum transmission rate to a rate that reflects the available
   capacity across a network path.  These methods typically operate on
   individual traffic flows (e.g., a 5-tuple).

   In contrast, Circuit Breakers are recommended for non-congestion-
   controlled Internet flows and for traffic aggregates, e.g., traffic
   sent using a network tunnel.  People have been implementing what this
   draft characterizes as circuit breakers on an ad hoc basis to protect
   Internet traffic, this draft therefore provides guidance on how to




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   deploy and use these mechanisms.  Later sections provide examples of
   cases where circuit-breakers may or may not be desirable.

   A Circuit Breaker needs to measure (meter) the traffic to determine
   if the network is experiencing congestion and needs to be designed to
   trigger robustly when there is persistent congestion.  This means the
   trigger needs to operate on a timescale much longer than the path
   round trip time (e.g., seconds to possibly many tens of seconds).
   This longer period is needed to provide sufficient time for
   transports (or applications) to adjust their rate following
   congestion, and for the network load to stabilize after any
   adjustment.

   A Circuit Breaker trigger will often utilize a series of successive
   sample measurements metered at an ingress point and an egress point
   (either of which could be a transport endpoint).  These measurements
   need to be taken over a reasonably long period of time.  This is to
   ensure that a Circuit Breaker does not accidentally trigger following
   a single (or even successive) congestion events (congestion events
   are what triggers congestion control, and are to be regarded as
   normal on a network link operating near its capacity).  Once
   triggered, a control function needs to remove traffic from the
   network, either by disabling the flow or by significantly reducing
   the level of traffic.  This reaction provides the required protection
   to prevent persistent congestion being experienced by other flows
   that share the congested part of the network path.

   Section 4 defines requirements for building a Circuit Breaker.

1.1.  Types of Circuit-Breaker

   There are various forms of network transport circuit breaker.  These
   are differentiated mainly on the timescale over which they are
   triggered, but also in the intended protection they offer:

   o  Fast-Trip Circuit Breakers: The relatively short timescale used by
      this form of circuit breaker is intended to protect a flow or
      related group of flows.

   o  Slow-Trip Circuit Breakers: This circuit breaker utilizes a longer
      timescale and is designed to protect traffic aggregates.

   o  Managed Circuit Breakers: Utilize the operations and management
      functions that might be present in a managed service to implement
      a circuit breaker.

   Examples of each type of circuit breaker are provided in section 4.




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2.  Terminology

   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 [RFC2119].

3.  Design of a Circuit-Breaker (What makes a good circuit breaker?)

   Although circuit breakers have been talked about in the IETF for many
   years, there has not yet been guidance on the cases where circuit
   breakers are needed or upon the design of circuit breaker mechanisms.
   This document seeks to offer advice on these two topics.

   Circuit Breakers are RECOMMENDED for IETF protocols and tunnels that
   carry non-congestion-controlled Internet flows and for traffic
   aggregates, e.g., traffic sent using a network tunnel.  Designers of
   other protocols and tunnel encapsulations also ought to consider the
   use of these techniques to provide last resort protection to the
   network paths that these are used.

   This document defines the requirements for design of a Circuit
   Breaker and provides examples of how a Circuit Breaker can be
   constructed.  The specifications of individual protocols and tunnels
   encapsulations need to detail the protocol mechanisms needed to
   implement a Circuit Breaker.

   Section 3.1 describes the functional components of a circuit breaker
   and section 3.2 defines requirements for implementing a Circuit
   Breaker.

3.1.  Functional Components

   The basic design of a transport circuit breaker involves
   communication between an ingress point (a sender) and an egress point
   (a receiver) of a network flow.  A simple picture of Circuit Breaker
   operation is provided in figure 1.  This shows a set of routers (each
   labelled R) connecting a set of endpoints.  A Circuit Breaker is used
   to control traffic passing through a subset of these routers, acting
   between the ingress and a egress point network devices.  The path
   between the ingress and egress could be provided by a tunnel or other
   network-layer technique.  One expected use would be at the ingress
   and egress of a service.









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 +--------+                                                   +--------+
 |Endpoint|                                                   |Endpoint|
 +--+-----+          >>> circuit breaker traffic >>>          +--+-----+
    |                                                            |
    | +-+  +-+  +---------+  +-+  +-+  +-+  +--------+  +-+  +-+ |
    +-+R+--+R+->+ Ingress +--+R+--+R+--+R+--+ Egress |--+R+--+R+-+
      +++  +-+  +------+--+  +-+  +-+  +-+  +-----+--+  +++  +-+
       |         ^     |                          |      |
       |         |  +--+------+            +------+--+   |
       |         |  | Ingress |            | Egress  |   |
       |         |  | Meter   |            | Meter   |   |
       |         |  +----+----+            +----+----+   |
       |         |       |                      |        |
  +-+  |         |  +----+----+                 |        |  +-+
  |R+--+         |  | Measure +<----------------+        +--+R|
  +++            |  +----+----+      Reported               +++
   |             |      |            Egress                  |
   |             |  +----+----+      Measurement             |
+--+-----+       |  | Trigger +                           +--+-----+
|Endpoint|       |  +----+----+                           |Endpoint|
+--------+       |       |                                +--------+
                 +---<---+
                  Reaction


   Figure 1: A CB controlling the part of the end-to-end path between an
   ingress point and an egress point.  (Note: In some cases, the trigger
   and measure functions could alternatively be located at other
   locations (e.g., at a network operations centre.)

   In the context of a Circuit Breaker, the ingress and egress functions
   could be implemented in different places.  For exmaple, they could be
   located in network devices at a tunnel ingress and at the tunnel
   egresss.  In some cases, they could be located at one or both network
   endpoints (see figure 2), implemented as components within a
   transport protocol.















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    +----------+                 +----------+
    | Ingress  |  +-+  +-+  +-+  | Egress   |
    | Endpoint +->+R+--+R+--+R+--+ Endpoint |
    +--+----+--+  +-+  +-+  +-+  +----+-----+
       ^    |                         |
       | +--+------+             +----+----+
       | | Ingress |             | Egress  |
       | | Meter   |             | Meter   |
       | +----+----+             +----+----+
       |      |                       |
       | +--- +----+                  |
       | | Measure +<-----------------+
       | +----+----+      Reported
       |      |           Egress
       | +----+----+      Measurement
       | | Trigger |
       | +----+----+
       |      |
       +---<--+
       Reaction


   Figure 2: An endpoint CB implemented at the sender (ingress) and
   receiver (egress).

   The set of components needed to implement a Circuit Breaker are:

   1.  An ingress meter (at the sender or tunnel ingress) records the
       number of packets/bytes sent in each measurement interval.  This
       measures the offered network load.  For example, the measurement
       interval could be every few seconds.

   2.  An egress meter (at the receiver or tunnel egress) records the
       number/bytes received in each measurement interval.  This
       measures the supported load and could utilize other signals to
       detect the effect of congestion (e.g., loss/marking experienced
       over the path).

   3.  The measured values at the ingress and egress are communicated to
       the Circuit Breaker Measurement function.  This could use several
       methods including: Sending return measurement packets from a
       receiver to a trigger function at the sender; An implementation
       using Operations, Administration and Management (OAM); or be
       sending another in-band signalling datagram to the trigger
       function.  This could also be implemented purely as a control
       plane function, e.g., using a software-defined network
       controller.




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   4.  The measurement function combines the ingress and egress
       measurements to assess the present level of network congestion.
       (For example, the loss rate for each measurement interval could
       be deduced from calculating the difference between ingress and
       egress counter values.  Note the method does not require high
       accuracy for the period of the measurement interval (or therefore
       the measured value, since isolated and/or infrequent loss events
       need to be disregarded.)

   5.  A trigger function determines if the measurements indicate
       persistent congestion.  This function defines an appropriate
       threshold for determining there is persistent congestion between
       the ingress and egress.  This preferably consider rate or ratio,
       rather than an absolute value (e.g., more than 10% loss, but
       other methods could also be based on the rate of transmission as
       well as the loss rate).  The transport Circuit Breaker is
       triggered when the threshold is exceeded in multiple measurement
       intervals (e.g., 3 successive measurements).  Designs need to be
       robust so that single or spurious events do not trigger a
       reaction.

   6.  A reaction that is applied that the Ingress when the Circuit
       Breaker is triggered.  This seeks to automatically remove the
       traffic causing persistent congestion.

   7.  A feedback mechanism that triggers when either the receive or
       ingress and egress measurements are not available, since this
       also could indicate a loss of control packets (also a symptom of
       heavy congestion or inability to control the load).

4.  Requirements for a Network Transport Circuit Breaker

   The requirements for implementing a Circuit Breaker are:

   o  There MUST be a control path from the ingress meter and the egress
      meter to the point of measurement.  The Circuit Breaker MUST
      trigger if this control path fails.  That is, the feedback
      indicating a congested period needs to be designed so that the
      Circuit Breaker is triggered when it fails to receive measurement
      reports that indicate an absence of congestion, rather than
      relying on the successful transmission of a "congested" signal
      back to the sender.  (The feedback signal could itself be lost
      under congestion).

   o  A Circuit Breaker MUST define a measurement period over which the
      receiver measures the level of congestion or loss.  This method
      does not have to detect individual packet loss, but MUST have a
      way to know that packets have been lost/marked from the traffic



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      flow.  If Explicit Congestion Notification (ECN) is enabled
      [RFC3168], an egress meter MAY also count the number of ECN
      congestion marks/event per measurement interval, but even if ECN
      is used, loss MUST still be measured, since this better reflects
      the impact of persistent congestion.  In this context, loss
      represents a reliable indication of congestion, as opposed to the
      finer-grain marking of incipient congestion that can be provided
      via ECN.  The type of Circuit Breaker will determine how long this
      measurement period needs to be.

   o  The measurement period MUST be longer than the time that current
      Congestion Control algorithms need to reduce their rate following
      detection of congestion.  This is important because end-to-end
      Congestion Control algorithms require at least one RTT to notify
      and adjust to experienced congestion, and congestion bottlenecks
      can share traffic with a diverse range of RTTs and Circuit
      Breakers hence need to perform measurements over a sufficiently
      long period to avoid additionally penalizing flows with a long
      path RTT (e.g., many path RTTs).  In some implementations, this
      may require a measurement to combine multiple meter samples to
      achieve a sufficiently long measurement period.  In most cases,
      the measurement period is expected to be significantly longer than
      the RTT experience by the Circuit Breaker itself.

   o  A Circuit Breaker is REQUIRED to define a threshold to determine
      whether the measured congestion is considered excessive.

   o  A Circuit Breaker is REQUIRED to define the triggering interval,
      defining the period over which the trigger uses the collected
      measurements.

   o  A Circuit Breaker MUST be robust to multiple congestion events.
      This usually will define a number of measured persistent
      congestion events per triggering period.  For example, a Circuit
      Breaker MAY combine the results of several measurement periods to
      determine if the Circuit Breaker is triggered. (e.g., triggered
      when persistent congestion is detected in 3 of the measurements
      within the triggering interval).

   o  A Circuit Breaker SHOULD be constructed so that it does not
      trigger under light or intermittent congestion, with a default
      response to a trigger that disables all traffic that contributed
      to congestion.

   o  Once triggered, the Circuit Breaker MUST react decisively by
      disabling or significantly reducing traffic at the source (e.g.,
      ingress).  A reaction that results in a reduction SHOULD result in
      reducing the traffic by at least a factor of ten, each time the



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      Circuit Breaker is triggered.  This response needs to be much more
      severe than that of a Congestion Controller algorithm (such as
      TCP's congestion control [RFC5681] or TFRC [RFC5348]), because the
      Circuit Breaker reacts to more persistent congestion and operates
      over longer timescales (i.e., the overload condition will have
      persisted for a longer time before the Circuit Breaker is
      triggered).

   o  A Circuit Breaker that reduces the rate of a flow, MUST continue
      to monitor the level congestion and MUST further reduce the rate
      if the Circuit Breaker is again triggered.

   o  The reaction to a triggered Circuit Breaker MUST continue for a
      period that is at least the triggering interval.  Manual operator
      intervention will usually be required to restore a flow.  If an
      automated response is needed to reset the trigger, then this needs
      to not be immediate.  The design of an automated reset mechanism
      needs to be sufficiently conservative that it does not adversely
      interact with other mechanisms (including other Circuit Breaker
      algorithms that control traffic over a common path).  It SHOULD
      NOT perform an automated reset when there is evidence of continued
      congestion.

   o  When a Circuit Breaker is triggered, it SHOULD be regarded as an
      abnormal network event.  As such, this event SHOULD be logged.
      The measurements that lead to triggering of the Circuit Breaker
      SHOULD also be logged.

4.1.  Unidirectional Circuit Breakers over Controlled Paths

   A Circuit Breaker can be used to control uni-directional UDP traffic,
   providing that there is a control path to connect the functional
   components at the Ingress and Egress.  This control path can exist in
   networks for which the traffic flow is purely unidirectional.  For
   example, a multicast stream that sends packets across an Internet
   path and can use multicast routing to prune flows to shed network
   load.  Some other types of subnetwork also utilize control protocols
   that can be used to control traffic flows.

4.1.1.  Use with a multicast control/routing protocol











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    +----------+                 +--------+  +----------+
    | Ingress  |  +-+  +-+  +-+  | Egress |  |  Egress  |
    | Endpoint +->+R+--+R+--+R+--+ Router |--+ Endpoint +->+
    +----+-----+  +-+  +-+  +-+  +---+--+-+  +----+-----+  |
         ^         ^    ^    ^       |  ^         |        |
         |         |    |    |       |  |         |        |
    +----+----+    + - - - < - - - - +  |    +----+----+   | Reported
    | Ingress |      multicast Prune    |    | Egress  |   | Ingress
    | Meter   |                         |    | Meter   |   | Measurement
    +---------+                         |    +----+----+   |
                                        |         |        |
                                        |    +----+----+   |
                                        |    | Measure +<--+
                                        |    +----+----+
                                        |         |
                                        |    +----+----+
                              multicast |    | Trigger |
                              Leave     |    +----+----+
                              Message   |         |
                                        +----<----+


   Figure 3: An example of a multicast CB controlling the end-to-end
   path between an ingress endpoint and an egress endpoint.

   Figure 3 shows one example of how a multicast circuit breaker could
   be implemented at a pair of multicast endpoints (e.g. to implement a
   Section 5.1).  The ingress endpoint (the sender that sources the
   multicast traffic) meters the ingress load, generating an ingress
   measurement (e.g., recording timestamped packet counts), and sends
   this measurement to the multicast group together with the traffic it
   has measured.

   Routers along a multicast path forward the multicast traffic
   (including the ingress measurement) to all active endpoint receivers.
   Each last hop (egress) router forwards the traffic to one or more
   egress endpoint(s).

   In this figure, each endpoint includes a meter that performs a local
   egress load measurement.  An endpoint also extracts the received
   ingress measurement from the traffic, and compares the ingress and
   egress measurements to determine if the Circuit Breaker ought to be
   triggered.  This measurement has to be robust to loss (see previous
   section).  If the Circuit Breaker is triggered, it generates a
   multicast leave message for the egress (e.g., an IGMP or MLD message
   sent to the last hop router), which causes the upstream router to
   cease forwarding traffic to the egress endpoint.




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   Any multicast router that has no active receivers for a particular
   multicast group will prune traffic for that group, sending a prune
   message to its upstream router.  This starts the process of releasing
   the capacity used by the traffic and is a standard multicast routing
   function (e.g., using the PIM-SM routing protocol).  Each egress
   operates autonomously, and the circuit breaker "reaction" is executed
   by the multicast control plane (e.g., PIM l), requiring no explicit
   signalling by the circuit breaker along the control path.  Note:
   there is no direct communication with the Ingress, and hence a
   triggered Circuit Breaker only controls traffic downstream of the
   first hop router.  It does not stop traffic flowing from the sender
   to the first hop router; this is however the common practice for
   multicast deployment.

   The method could also be used with a multicast tunnel or subnetwork
   (e.g., Section 5.2, Section 5.3), where a meter at the ingress
   generates additional control messages to carry the measurement data
   towards the egress where the egress metering is implemented.

4.1.2.  Use with control protocols supporting pre-prosvisioned capacity

   Some paths are provisioned using a control protocol, e.g., flows
   provisioned using the Multi-Protocol Label Switching (MPLS) services,
   path provisioned using the Resource reservation protocol (RSVP),
   networks utilizing Software Defined Network (SDN) functions, or
   admission-controlled Differentiated Services.

   Figure 1 shows one expected use case, where in this usage a separate
   device could be used to perform the measurement and trigger
   functions.  The reaction generated by the trigger could take the form
   of a network control message sent to the ingress and/or other network
   elements causing these elements to react to the Circuit Breaker.
   Examples of this type of use are provided in section Section 5.3.

5.  Examples of Circuit Breakers

   There are multiple types of Circuit Breaker that could be defined for
   use in different deployment cases.  This section provides examples of
   different types of circuit breaker:

5.1.  A Fast-Trip Circuit Breaker

   A fast-trip circuit breaker is the most responsive form of Circuit
   Breaker.  It has a response time that is only slightly larger than
   that of the traffic that it controls.  It is suited to traffic with
   well-understood characteristics (and could include one or more
   trigger functions specifically tailored the type of traffic for which
   it is designed).  It is not suited to arbitrary network traffic,



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   since it could prematurely trigger (e.g., when multiple congestion-
   controlled flows lead to short-term overload).

5.1.1.  A Fast-Trip Circuit Breaker for RTP

   A set of fast-trip Circuit Breaker methods have been specified for
   use together by a Real-time Transport Protocol (RTP) flow using the
   RTP/AVP Profile [RTP-CB].  It is expected that, in the absence of
   severe congestion, all RTP applications running on best-effort IP
   networks will be able to run without triggering these circuit
   breakers.  A fast-trip RTP Circuit Breaker is therefore implemented
   as a fail-safe that when triggred will terminate RTP traffic.

   The sender monitors reception of RTCP reception report blocks, as
   contained in SR or RR packets, that convey reception quality feedback
   information.  This is used to measure (congestion) loss, possibly in
   combination with ECN [RFC6679].

   The Circuit Breaker action (shutdown of the flow) is triggered when
   any of the following trigger conditions are true:

   1.  An RTP Circuit Breaker triggers on reported lack of progress.

   2.  An RTP Circuit Breaker triggers when no receiver reports messages
       are received.

   3.  An RTP Circuit Breaker uses a TFRC-style check and sets a hard
       upper limit to the long-term RTP throughput (over many RTTs).

   4.  An RTP Circuit Breaker includes the notion of Media Usability.
       This circuit breaker is triggered when the quality of the
       transported media falls below some required minimum acceptable
       quality.

5.2.  A Slow-trip Circuit Breaker

   A slow-trip Circuit Breaker could be implemented in an endpoint or
   network device.  This type of Circuit Breaker is much slower at
   responding to congestion than a fast-trip Circuit Breaker and is
   expected to be more common.

   One example where a slow-trip Circuit Breaker is needed is where
   flows or traffic-aggregates use a tunnel or encapsulation and the
   flows within the tunnel do not all support TCP-style congestion
   control (e.g., TCP, SCTP, TFRC), see [RFC5405] section 3.1.3.  A use
   case is where tunnels are deployed in the general Internet (rather
   than "controlled environments" within an ISP or Enterprise),




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   especially when the tunnel could need to cross a customer access
   router.

5.3.  A Managed Circuit Breaker

   A managed Circuit Breaker is implemented in the signalling protocol
   or management plane that relates to the traffic aggregate being
   controlled.  This type of circuit breaker is typically applicable
   when the deployment is within a "controlled environment".

   A Circuit Breaker requires more than the ability to determine that a
   network path is forwarding data, or to measure the rate of a path -
   which are often normal network operational functions.  There is an
   additional need to determine a metric for congestion on the path and
   to trigger a reaction when a threshold is crossed that indicates
   persistent congestion.

5.3.1.  A Managed Circuit Breaker for SAToP Pseudo-Wires

   [RFC4553], SAToP Pseudo-Wires (PWE3), section 8 describes an example
   of a managed circuit breaker for isochronous flows.

   If such flows were to run over a pre-provisioned (e.g., MPLS)
   infrastructure, then it could be expected that the Pseudo-Wire (PW)
   would not experience congestion, because a flow is not expected to
   either increase (or decrease) their rate.  If instead Pseudo-Wire
   traffic is multiplexed with other traffic over the general Internet,
   it could experience congestion.  [RFC4553] states: "If SAToP PWs run
   over a PSN providing best-effort service, they SHOULD monitor packet
   loss in order to detect "severe congestion".  The currently
   recommended measurement period is 1 second, and the trigger operates
   when there are more than three measured Severely Errored Seconds
   (SES) within a period.  If such a condition is detected, a SAToP PW
   ought to shut down bidirectionally for some period of time...".

   The concept was that when the packet loss ratio (congestion) level
   increased above a threshold, the PW was by default disabled.  This
   use case considered fixed-rate transmission, where the PW had no
   reasonable way to shed load.

   The trigger needs to be set at the rate that the PW was likely to
   experience a serious problem, possibly making the service non-
   compliant.  At this point, triggering the Circuit Breaker would
   remove the traffic preventing undue impact on congestion-responsive
   traffic (e.g., TCP).  Part of the rationale, was that high loss
   ratios typically indicated that something was "broken" and ought to
   have already resulted in operator intervention, and therefore need to
   trigger this intervention.



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   An operator-based response provides opportunity for other action to
   restore the service quality, e.g., by shedding other loads or
   assigning additional capacity, or to consciously avoid reacting to
   the trigger while engineering a solution to the problem.  This could
   require the trigger to be sent to a third location (e.g., a network
   operations centre, NOC) responsible for operation of the tunnel
   ingress, rather than the tunnel ingress itself.

5.3.2.  A Managed Circuit Breaker for Pseudowires (PWs)

   Pseudowires (PWs) [RFC3985] have become a common mechanism for
   tunneling traffic, and may compete for network resources both with
   other PWs and with non-PW traffic, such as TCP/IP flows.

   [ID-ietf-pals-congcons] discusses congestion conditions that can
   arise when PWs compete with elastic (i.e., congestion responsive)
   network traffic (e.g, TCP traffic).  Elastic PWs carrying IP traffic
   (see [RFC4488]) do not raise major concerns because all of the
   traffic involved responds, reducing the transmission rate when
   network congestion is detected.

   In contrast, inelastic PWs (e.g., fixed (e.g., fixed bandwidth Time
   Division Multiplex (TDM) [RFC4553] [RFC5086] [RFC5087]) have the
   potential to harm congestion responsive traffic or to contribute to
   excessive congestion because inelastic PWs do not adjust their
   transmission rate in response to congestion.  [ID-ietf-pals-congcons]
   analyses TDM PWs, with an initial conclusion that a TDM PW operating
   with a degree of loss that may result in congestion-related problems
   is also operating with a degree of loss that results in an
   unacceptable TDM service.  For that reason, the draft suggests that a
   managed circuit breaker that shuts down a PW when it persistently
   fails to deliver acceptable TDM service is a useful means for
   addressing these congestion concerns.

6.  Examples where circuit breakers may not be needed.

   A Circuit Breaker is not required for a single Congestion Controller-
   controlled flow using TCP, SCTP, TFRC, etc.  In these cases, the
   Congestion Control methods are already designed to prevent congestion
   collapse.

6.1.  CBs over pre-provisioned Capacity

   One common question is whether a Circuit Breaker is needed when a
   tunnel is deployed in a private network with pre-provisioned
   capacity?





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   In this case, compliant traffic that does not exceed the provisioned
   capacity ought not to result in congestion collapse.  A Circuit
   Breaker will hence only be triggered when there is non-compliant
   traffic.  It could be argued that this event ought never to happen -
   but it could also be argued that the Circuit Breaker equally ought
   never to be triggered.  If a Circuit Breaker were to be implemented,
   it will provide an appropriate response if persistent congestion
   occurs in an operational network.

   Implementing a Circuit Breaker will not reduce the performance of the
   flows, but offers protection in the event that persistent congestion
   occurs.  This also could be used to protect from a failure that
   causes traffic to be routed over a non-pre-provisioned path.

6.2.  CBs with tunnels carrying Congestion-Controlled Traffic

   IP-based traffic is generally assumed to be congestion-controlled,
   i.e., it is assumed that the transport protocols generating IP-based
   traffic at the sender already employ mechanisms that are sufficient
   to address congestion on the path [RFC5405].  A question therefore
   arises when people deploy a tunnel that is thought to only carry an
   aggregate of TCP (or some other Congestion Controller-controlled)
   traffic: Is there advantage in this case in using a Circuit Breaker?

   For sure, traffic in a such a tunnel will respond to congestion.
   However, the answer to the question is not always obvious, because
   the overall traffic formed by an aggregate of flows that implement a
   Congestion Controller mechanism does not necessarily prevent
   congestion collapse.  For instance, most Congestion Controller
   mechanisms require long-lived flows to react to reduce the rate of a
   flow, an aggregate of many short flows could result in many
   terminating before they experience congestion.  It is also often
   impossible for a tunnel service provider to know that the tunnel only
   contains CC-controlled traffic (e.g., Inspecting packet headers could
   not be possible).  The important thing to note is that if the
   aggregate of the traffic does not result in persistent congestion
   (impacting other flows), then the Circuit Breaker will not trigger.
   This is the expected case in this context - so implementing a Circuit
   Breaker will not reduce performance of the tunnel, but offers
   protection in the event that persistent congestion occur.

6.3.  CBs with Uni-directional Traffic and no Control Path

   A one-way forwarding path could have no associated control path, and
   therefore cannot be controlled using an automated process.  This
   service could be provided using a path that has dedicated capacity
   and does not share this capacity with other elastic Internet flows
   (i.e., flows that vary their rate).



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   A way to mitigate the impact on other flows when capacity could be
   shared is to manage the traffic envelope by using ingress policing.

   Supporting this type of traffic in the general Internet requires
   operator monitoring to detect and respond to persistent congestion.

7.  Security Considerations

   All Circuit Breaker mechanisms rely upon coordination between the
   ingress and egress meters and communication with the trigger
   function.  This is usually achieved by passing network control
   information (or protocol messages) across the network.  Timely
   operation of a circuit breaker depends on the choice of measurement
   period.  If the receiver has an interval that is overly long, then
   the responsiveness of the circuit breaker decreases.  This impacts
   the ability of the circuit breaker to detect and react to congestion.

   Mechanisms need to be implemented to prevent attacks on the network
   control information that would result in Denial of Service (DoS).
   The source and integrity of control information (measurements and
   triggers) MUST be protected from off-path attacks.  Without
   protection, it could be trivial for an attacker to inject packets
   with values that could prematurely trigger a circuit breaker
   resulting in DoS.  Simple protection can be provided by using a
   randomized source port, or equivalent field in the packet header
   (such as the RTP SSRC value and the RTP sequence number) expected not
   to be known to an off-path attacker.  Stronger protection can be
   achieved using a secure authentication protocol.

   Transmission of network control information consumes network
   capacity.  This control traffic needs to be considered in the design
   of a circuit breaker and could potentially add to network congestion.
   If this traffic is sent over a shared path, it is RECOMMENDED that
   this control traffic is prioritized to reduce the probability of loss
   under congestion.  Control traffic also needs to be considered when
   provisioning a network that uses a circuit breaker.

   The circuit breaker MUST be designed to be robust to packet loss that
   can also be experienced during congestion/overload.  Loss of control
   traffic could be a side-effect of a congested network, but also could
   arise from other causes.

   The security implications depend on the design of the mechanisms, the
   type of traffic being congtrolled and the intended deployment
   scenario.  Each design of a Circuit Breaker MUST therefore evaluate
   whether the particular circuit breaker mechanism has new security
   implications.




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8.  IANA Considerations

   This document makes no request from IANA.

9.  Acknowledgments

   There are many people who have discussed and described the issues
   that have motivated this draft.  Contributions and comments included:
   Lars Eggert, Colin Perkins, David Black, Matt Mathis and Andrew
   McGregor.  This work was part-funded by the European Community under
   its Seventh Framework Programme through the Reducing Internet
   Transport Latency (RITE) project (ICT-317700).

10.  Revision Notes

   XXX RFC-Editor: Please remove this section prior to publication XXX

   Draft 00

   This was the first revision.  Help and comments are greatly
   appreciated.

   Draft 01

   Contained clarifications and changes in response to received
   comments, plus addition of diagram and definitions.  Comments are
   welcome.

   WG Draft 00

   Approved as a WG work item on 28th Aug 2014.

   WG Draft 01

   Incorporates feedback after Dallas IETF TSVWG meeting.  This version
   is thought ready for WGLC comments.

   WG Draft 02

   Minor fixes for typos.  Rewritten security considerations section.

   WG Draft 03

   Updates following WGLC comments (see TSV mailing list).  Comments
   from C Perkins; D Black and off-list feedback.

   A clear recommendation of intended scope.




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   Changes include: Improvement of language on timescales and minimum
   measurement period; clearer articulation of endpoint and multicast
   examples - with new diagrams; separation of the controlled network
   case; updated text on position of trigger function; corrections to
   RTP-CB text; clarification of loss v ECN metrics; checks against
   submission checklist 9use of keywords, added meters to diagrams).

   WG Draft 04

   Added section on PW CB for TDM - a newly adopted draft (D.  Black).

   WG Draft 05

   Added clarifications requested during AD review.

11.  References

11.1.  Normative References

   [RFC2119]  Bradner, S., "Key words for use in RFCs to Indicate
              Requirement Levels", BCP 14, RFC 2119,
              DOI 10.17487/RFC2119, March 1997,
              <http://www.rfc-editor.org/info/rfc2119>.

   [RFC3168]  Ramakrishnan, K., Floyd, S., and D. Black, "The Addition
              of Explicit Congestion Notification (ECN) to IP",
              RFC 3168, DOI 10.17487/RFC3168, September 2001,
              <http://www.rfc-editor.org/info/rfc3168>.

   [RFC5405]  Eggert, L. and G. Fairhurst, "Unicast UDP Usage Guidelines
              for Application Designers", BCP 145, RFC 5405,
              DOI 10.17487/RFC5405, November 2008,
              <http://www.rfc-editor.org/info/rfc5405>.

11.2.  Informative References

   [ID-ietf-pals-congcons]
              Stein, YJ., Black, D., and B. Briscoe, "Pseudowire
              Congestion Considerations (Work-in-Progress)", 2015.

   [Jacobsen88]
              European Telecommunication Standards, Institute (ETSI),
              "Congestion Avoidance and Control", SIGCOMM Symposium
              proceedings on Communications architectures and
              protocols", August 1998.






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   [RFC1112]  Deering, S., "Host extensions for IP multicasting", STD 5,
              RFC 1112, DOI 10.17487/RFC1112, August 1989,
              <http://www.rfc-editor.org/info/rfc1112>.

   [RFC3985]  Bryant, S., Ed. and P. Pate, Ed., "Pseudo Wire Emulation
              Edge-to-Edge (PWE3) Architecture", RFC 3985,
              DOI 10.17487/RFC3985, March 2005,
              <http://www.rfc-editor.org/info/rfc3985>.

   [RFC4488]  Levin, O., "Suppression of Session Initiation Protocol
              (SIP) REFER Method Implicit Subscription", RFC 4488,
              DOI 10.17487/RFC4488, May 2006,
              <http://www.rfc-editor.org/info/rfc4488>.

   [RFC4553]  Vainshtein, A., Ed. and YJ. Stein, Ed., "Structure-
              Agnostic Time Division Multiplexing (TDM) over Packet
              (SAToP)", RFC 4553, DOI 10.17487/RFC4553, June 2006,
              <http://www.rfc-editor.org/info/rfc4553>.

   [RFC5086]  Vainshtein, A., Ed., Sasson, I., Metz, E., Frost, T., and
              P. Pate, "Structure-Aware Time Division Multiplexed (TDM)
              Circuit Emulation Service over Packet Switched Network
              (CESoPSN)", RFC 5086, DOI 10.17487/RFC5086, December 2007,
              <http://www.rfc-editor.org/info/rfc5086>.

   [RFC5087]  Stein, Y(J)., Shashoua, R., Insler, R., and M. Anavi,
              "Time Division Multiplexing over IP (TDMoIP)", RFC 5087,
              DOI 10.17487/RFC5087, December 2007,
              <http://www.rfc-editor.org/info/rfc5087>.

   [RFC5348]  Floyd, S., Handley, M., Padhye, J., and J. Widmer, "TCP
              Friendly Rate Control (TFRC): Protocol Specification",
              RFC 5348, DOI 10.17487/RFC5348, September 2008,
              <http://www.rfc-editor.org/info/rfc5348>.

   [RFC5681]  Allman, M., Paxson, V., and E. Blanton, "TCP Congestion
              Control", RFC 5681, DOI 10.17487/RFC5681, September 2009,
              <http://www.rfc-editor.org/info/rfc5681>.

   [RFC6679]  Westerlund, M., Johansson, I., Perkins, C., O'Hanlon, P.,
              and K. Carlberg, "Explicit Congestion Notification (ECN)
              for RTP over UDP", RFC 6679, DOI 10.17487/RFC6679, August
              2012, <http://www.rfc-editor.org/info/rfc6679>.

   [RTP-CB]   Perkins, and Singh, "Multimedia Congestion Control:
              Circuit Breakers for Unicast RTP Sessions", February 2014.





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Author's Address

   Godred Fairhurst
   University of Aberdeen
   School of Engineering
   Fraser Noble Building
   Aberdeen, Scotland  AB24 3UE
   UK

   Email: gorry@erg.abdn.ac.uk
   URI:   http://www.erg.abdn.ac.uk








































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