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IETF RFC 8899



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Internet Engineering Task Force (IETF)                      G. Fairhurst
Request for Comments: 8899                                      T. Jones
Updates: 4821, 4960, 6951, 8085, 8261             University of Aberdeen
Category: Standards Track                                     M. Tüxen
ISSN: 2070-1721                                              I. Rüngeler
                                                               T. Völker
                                  Münster University of Applied Sciences
                                                          September 2020


     Packetization Layer Path MTU Discovery for Datagram Transports

 Abstract

   This document specifies Datagram Packetization Layer Path MTU
   Discovery (DPLPMTUD).  This is a robust method for Path MTU Discovery
   (PMTUD) for datagram Packetization Layers (PLs).  It allows a PL, or
   a datagram application that uses a PL, to discover whether a network
   path can support the current size of datagram.  This can be used to
   detect and reduce the message size when a sender encounters a packet
   black hole.  It can also probe a network path to discover whether the
   maximum packet size can be increased.  This provides functionality
   for datagram transports that is equivalent to the PLPMTUD
   specification for TCP, specified in RFC 4821, which it updates.  It
   also updates the UDP Usage Guidelines to refer to this method for use
   with UDP datagrams and updates SCTP.

   The document provides implementation notes for incorporating Datagram
   PMTUD into IETF datagram transports or applications that use datagram
   transports.

   This specification updates RFC 4960, RFC 4821, RFC 6951, RFC 8085,
   and RFC 8261.

 Status of This Memo

   This is an Internet Standards Track document.

   This document is a product of the Internet Engineering Task Force
   (IETF).  It represents the consensus of the IETF community.  It has
   received public review and has been approved for publication by the
   Internet Engineering Steering Group (IESG).  Further information on
   Internet Standards is available in Section 2 of RFC 7841.

   Information about the current status of this document, any errata,
   and how to provide feedback on it may be obtained at
   https://www.rfc-editor.org/info/RFC 8899.

 Copyright Notice

   Copyright (c) 2020 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
   (https://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
   the Trust Legal Provisions and are provided without warranty as
   described in the Simplified BSD License.

 Table of Contents

   1.  Introduction
     1.1.  Classical Path MTU Discovery
     1.2.  Packetization Layer Path MTU Discovery
     1.3.  Path MTU Discovery for Datagram Services
   2.  Terminology
   3.  Features Required to Provide Datagram PLPMTUD
   4.  DPLPMTUD Mechanisms
     4.1.  PLPMTU Probe Packets
     4.2.  Confirmation of Probed Packet Size
     4.3.  Black Hole Detection and Reducing the PLPMTU
     4.4.  The Maximum Packet Size (MPS)
     4.5.  Disabling the Effect of PMTUD
     4.6.  Response to PTB Messages
       4.6.1.  Validation of PTB Messages
       4.6.2.  Use of PTB Messages
   5.  Datagram Packetization Layer PMTUD
     5.1.  DPLPMTUD Components
       5.1.1.  Timers
       5.1.2.  Constants
       5.1.3.  Variables
       5.1.4.  Overview of DPLPMTUD Phases
     5.2.  State Machine
     5.3.  Search to Increase the PLPMTU
       5.3.1.  Probing for a Larger PLPMTU
       5.3.2.  Selection of Probe Sizes
       5.3.3.  Resilience to Inconsistent Path Information
     5.4.  Robustness to Inconsistent Paths
   6.  Specification of Protocol-Specific Methods
     6.1.  Application Support for DPLPMTUD with UDP or UDP-Lite
       6.1.1.  Application Request
       6.1.2.  Application Response
       6.1.3.  Sending Application Probe Packets
       6.1.4.  Initial Connectivity
       6.1.5.  Validating the Path
       6.1.6.  Handling of PTB Messages
     6.2.  DPLPMTUD for SCTP
       6.2.1.  SCTP/IPv4 and SCTP/IPv6
         6.2.1.1.  Initial Connectivity
         6.2.1.2.  Sending SCTP Probe Packets
         6.2.1.3.  Validating the Path with SCTP
         6.2.1.4.  PTB Message Handling by SCTP
       6.2.2.  DPLPMTUD for SCTP/UDP
         6.2.2.1.  Initial Connectivity
         6.2.2.2.  Sending SCTP/UDP Probe Packets
         6.2.2.3.  Validating the Path with SCTP/UDP
         6.2.2.4.  Handling of PTB Messages by SCTP/UDP
       6.2.3.  DPLPMTUD for SCTP/DTLS
         6.2.3.1.  Initial Connectivity
         6.2.3.2.  Sending SCTP/DTLS Probe Packets
         6.2.3.3.  Validating the Path with SCTP/DTLS
         6.2.3.4.  Handling of PTB Messages by SCTP/DTLS
     6.3.  DPLPMTUD for QUIC
   7.  IANA Considerations
   8.  Security Considerations
   9.  References
     9.1.  Normative References
     9.2.  Informative References
   Acknowledgments
   Authors' Addresses

1.  Introduction

   The IETF has specified datagram transport using UDP, Stream Control
   Transmission Protocol (SCTP), and Datagram Congestion Control
   Protocol (DCCP), as well as protocols layered on top of these
   transports (e.g., SCTP/UDP, DCCP/UDP, QUIC/UDP) and direct datagram
   transport over the IP network layer.  This document describes a
   robust method for Path MTU Discovery (PMTUD) that can be used with
   these transport protocols (or the applications that use their
   transport service) to discover an appropriate size of packet to use
   across an Internet path.

1.1.  Classical Path MTU Discovery

   Classical Path Maximum Transmission Unit Discovery (PMTUD) can be
   used with any transport that is able to process ICMP Packet Too Big
   (PTB) messages (e.g., [RFC 1191] and [RFC 8201]).  In this document,
   the term PTB message is applied to both IPv4 ICMP Unreachable
   messages (Type 3) that carry the error Fragmentation Needed (Type 3,
   Code 4) [RFC 792] and ICMPv6 Packet Too Big messages (Type 2)
   [RFC 4443].  When a sender receives a PTB message, it reduces the
   effective MTU to the value reported as the link MTU in the PTB
   message.  Classical PMTUD specifies a method of periodically
   increasing the packet size in an attempt to discover an increase in
   the supported PMTU.  The packets sent with a size larger than the
   current effective PMTU are known as probe packets.

   Packets not intended as probe packets are either fragmented to the
   current effective PMTU, or the attempt to send fails with an error
   code.  Applications can be provided with a primitive to let them read
   the Maximum Packet Size (MPS), which is derived from the current
   effective PMTU.

   Classical PMTUD is subject to protocol failures.  One failure arises
   when traffic using a packet size larger than the actual PMTU is
   black-holed (all datagrams larger than the actual PMTU are
   discarded).  This could arise when the PTB messages are not sent back
   to the sender for some reason (for example, see [RFC 2923]).

   Examples of where PTB messages are not delivered include the
   following:

   *  The generation of ICMP messages is usually rate limited.  This
      could result in no PTB messages being generated to the sender (see
      Section 2.4 of [RFC 4443]).

   *  ICMP messages can be filtered by middleboxes, including firewalls
      [RFC 4890].  A firewall could be configured with a policy to block
      incoming ICMP messages, which would prevent reception of PTB
      messages by a sending endpoint behind this firewall.

   *  When the router issuing the ICMP message drops a tunneled packet,
      the resulting ICMP message is directed to the tunnel ingress.
      This tunnel endpoint is responsible for forwarding the ICMP
      message, processing the quoted packet within the payload field to
      remove the effect of the tunnel and returning a correctly
      formatted ICMP message to the sender [TUNNELS].  Failure to do
      this prevents the PTB message from reaching the original sender.

   *  Asymmetry in forwarding can result in there being no return route
      to the original sender, which would prevent an ICMP message from
      being delivered to the sender.  This issue can also arise when
      either policy-based or Equal-Cost Multipath (ECMP) routing is used
      or when a middlebox acts as an application load balancer.  An
      example of which is an ECMP router choosing a path toward the
      server based on the bytes in the IP payload.  In this case, if a
      packet sent by the server encounters a problem after the ECMP
      router, then the ECMP router needs to direct any resulting ICMP
      message toward the original sender.

   *  There are additional cases where the next-hop destination fails to
      receive a packet because of its size.  This could be due to
      misconfiguration of the layer 2 path between nodes, for instance
      the MTU configured in a layer 2 switch, or misconfiguration of the
      Maximum Receive Unit (MRU).  If a packet is dropped by the link,
      this will not cause a PTB message to be sent to the original
      sender.

   Another failure could result if a node that is not on the network
   path sends a PTB message that attempts to force a sender to change
   the effective PMTU [RFC 8201].  A sender can protect itself from
   reacting to such messages by utilizing the quoted packet within a PTB
   message payload to validate that the received PTB message was
   generated in response to a packet that had actually originated from
   the sender.  However, there are situations where a sender would be
   unable to provide this validation.  Examples where the validation of
   the PTB message is not possible include the following:

   *  When a router issuing the ICMP message implements RFC 792
      [RFC 792], it is only required to include the first 64 bits of the
      IP payload of the packet within the quoted payload.  There could
      be insufficient bytes remaining for the sender to interpret the
      quoted transport information.

      Note: The recommendation in RFC 1812 [RFC 1812] is that IPv4
      routers return a quoted packet with as much of the original
      datagram as possible without the length of the ICMP datagram
      exceeding 576 bytes.  IPv6 routers include as much of the invoking
      packet as possible without the ICMPv6 packet exceeding 1280 bytes
      [RFC 4443].

   *  The use of tunnels and/or encryption can reduce the size of the
      quoted packet returned to the original source address, increasing
      the risk that there could be insufficient bytes remaining for the
      sender to interpret the quoted transport information.

   *  Even when the PTB message includes sufficient bytes of the quoted
      packet, the network layer could lack sufficient context to
      validate the message because validation depends on information
      about the active transport flows at an endpoint node (e.g., the
      socket/address pairs being used and other protocol header
      information).

   *  When a packet is encapsulated/tunneled over an encrypted
      transport, the tunnel/encapsulation ingress might have
      insufficient context, or computational power, to reconstruct the
      transport header that would be needed to perform validation.

   *  When an ICMP message is generated by a router in a network segment
      that has inserted a header into a packet, the quoted packet could
      contain additional protocol header information that was not
      included in the original sent packet and that the PL sender does
      not process or may not know how to process.  This could disrupt
      the ability of the sender to validate this PTB message.

   *  A Network Address Translation (NAT) device that translates a
      packet header ought to also translate ICMP messages and update the
      ICMP-quoted packet [RFC 5508] in that message.  If this is not
      correctly translated, then the sender would not be able to
      associate the message with the PL that originated the packet, and
      hence this ICMP message cannot be validated.

1.2.  Packetization Layer Path MTU Discovery

   The term Packetization Layer (PL) has been introduced to describe the
   layer that is responsible for placing data blocks into the payload of
   IP packets and selecting an appropriate MPS.  This function is often
   performed by a transport protocol (e.g., DCCP, RTP, SCTP, QUIC) but
   can also be performed by other encapsulation methods working above
   the transport layer.

   In contrast to PMTUD, Packetization Layer Path MTU Discovery
   (PLPMTUD) [RFC 4821] introduces a method that does not rely upon
   reception and validation of PTB messages.  It is therefore more
   robust than Classical PMTUD.  This has become the recommended
   approach for implementing discovery of the PMTU [BCP145].

   This document updates [RFC 4821] to specify the PLPMTUD method for
   datagram PLs and also updates [BCP145] to refer to the method
   specified in this document for use with UDP datagrams instead of the
   method in [RFC 4821].

   It uses a general strategy in which the PL sends probe packets to
   search for the largest size of unfragmented datagram that can be sent
   over a network path.  Probe packets are sent to explore using a
   larger packet size.  If a probe packet is successfully delivered (as
   determined by the PL), then the PLPMTU is raised to the size of the
   successful probe.  If a black hole is detected (e.g., where packets
   of size PLPMTU are consistently not received), the method reduces the
   PLPMTU.

   Datagram PLPMTUD introduces flexibility in implementation.  At one
   extreme, it can be configured to only perform black hole detection
   and recovery with increased robustness compared to Classical PMTUD.
   At the other extreme, all PTB processing can be disabled, and PLPMTUD
   replaces Classical PMTUD.

   PLPMTUD can also include additional consistency checks without
   increasing the risk that data is lost when probing to discover the
   Path MTU.  For example, information available at the PL, or higher
   layers, enables received PTB messages to be validated before being
   utilized.

1.3.  Path MTU Discovery for Datagram Services

   Section 5 of this document presents a set of algorithms for datagram
   protocols to discover the largest size of unfragmented datagram that
   can be sent over a network path.  The method relies upon features of
   the PL described in Section 3 and applies to transport protocols
   operating over IPv4 and IPv6.  It does not require cooperation from
   the lower layers, although it can utilize PTB messages when these
   received messages are made available to the PL.

   The message size guidelines in Section 3.2 of the UDP Usage
   Guidelines [BCP145] state that "an application SHOULD either use the
   Path MTU information provided by the IP layer or implement Path MTU
   Discovery (PMTUD)" but do not provide a mechanism for discovering the
   largest size of unfragmented datagram that can be used on a network
   path.  The present document updates RFC 8085 to specify this method
   in place of PLPMTUD [RFC 4821] and provides a mechanism for sharing
   the discovered largest size as the MPS (see Section 4.4).

   Section 10.2 of [RFC 4821] recommended a PLPMTUD probing method for
   the Stream Control Transport Protocol (SCTP).  SCTP utilizes probe
   packets consisting of a minimal-sized HEARTBEAT chunk bundled with a
   PAD chunk as defined in [RFC 4820].  However, RFC 4821 did not provide
   a complete specification.  The present document replaces that
   description by providing a complete specification.

   The Datagram Congestion Control Protocol (DCCP) [RFC 4340] requires
   implementations to support Classical PMTUD and states that a DCCP
   sender "MUST maintain the MPS allowed for each active DCCP session".
   It also defines the current congestion control MPS (CCMPS) supported
   by a network path.  This recommends use of PMTUD and suggests use of
   control packets (DCCP-Sync) as path probe packets because they do not
   risk application data loss.  The method defined in this specification
   can be used with DCCP.

   Section 4 and Section 5 define the protocol mechanisms and
   specification for Datagram Packetization Layer Path MTU Discovery
   (DPLPMTUD).

   Section 6 specifies the method for datagram transports and provides
   information to enable the implementation of PLPMTUD with other
   datagram transports and applications that use datagram transports.

   Section 6 also provides recommendations for SCTP endpoints, updating
   [RFC 4960], [RFC 6951], and [RFC 8261] to use the method specified in
   this document instead of the method in [RFC 4821].

2.  Terminology

   The key words "MUST", "MUST NOT", "REQUIRED", "SHALL", "SHALL NOT",
   "SHOULD", "SHOULD NOT", "RECOMMENDED", "NOT RECOMMENDED", "MAY", and
   "OPTIONAL" in this document are to be interpreted as described in
   BCP 14 [RFC 2119] [RFC 8174] when, and only when, they appear in all
   capitals, as shown here.

   The following terminology is defined.  Relevant terms are directly
   copied from [RFC 4821], and the definitions in [RFC 1122] apply.

   Acknowledged PL:  A PL that includes a mechanism that can confirm
      successful delivery of datagrams to the remote PL endpoint (e.g.,
      SCTP).  Typically, the PL receiver returns acknowledgments
      corresponding to the received datagrams, which can be utilized to
      detect black-holing of packets (c.f., Unacknowledged PL).

   Actual PMTU:  The actual PMTU is the PMTU of a network path between a
      sender PL and a destination PL, which the DPLPMTUD algorithm seeks
      to determine.

   Black Hole:  A black hole is encountered when a sender is unaware
      that packets are not being delivered to the destination endpoint.
      Two types of black hole are relevant to DPLPMTUD:

      *  Packets encounter a packet black hole when packets are not
         delivered to the destination endpoint (e.g., when the sender
         transmits packets of a particular size with a previously known
         effective PMTU, and they are discarded by the network).

      *  An ICMP black hole is encountered when the sender is unaware
         that packets are not delivered to the destination endpoint
         because PTB messages are not received by the originating PL
         sender.

   Classical Path MTU Discovery:  Classical PMTUD is a process described
      in [RFC 1191] and [RFC 8201] in which nodes rely on PTB messages to
      learn the largest size of unfragmented packet that can be used
      across a network path.

   Datagram:  A datagram is a transport-layer protocol data unit,
      transmitted in the payload of an IP packet.

   DPLPMTUD:  Datagram Packetization Layer Path MTU Discovery
      (DPLPMTUD), PLPMTUD performed using a datagram transport protocol.

   Effective PMTU:  The effective PMTU is the current estimated value
      for PMTU that is used by a PMTUD.  This is equivalent to the
      PLPMTU derived by PLPMTUD plus the size of any headers added below
      the PL, including the IP layer headers.

   EMTU_S:  The effective MTU for sending (EMTU_S) is defined in
      [RFC 1122] as "the maximum IP datagram size that may be sent, for a
      particular combination of IP source and destination addresses...".

   EMTU_R:  The effective MTU for receiving (EMTU_R) is designated in
      [RFC 1122] as "the largest datagram size that can be reassembled".

   Link:  A link is a communication facility or medium over which nodes
      can communicate at the link layer, i.e., a layer below the IP
      layer.  Examples are Ethernet LANs and Internet (or higher) layer
      tunnels.

   Link MTU:  The link Maximum Transmission Unit (MTU) is the size in
      bytes of the largest IP packet, including the IP header and
      payload, that can be transmitted over a link.  Note that this
      could more properly be called the IP MTU, to be consistent with
      how other standards organizations use the acronym.  This includes
      the IP header but excludes link layer headers and other framing
      that is not part of IP or the IP payload.  Other standards
      organizations generally define the link MTU to include the link
      layer headers.  This specification continues the requirement in
      [RFC 4821] that states, "All links MUST enforce their MTU: links
      that might non-deterministically deliver packets that are larger
      than their rated MTU MUST consistently discard such packets."

   MAX_PLPMTU:  The MAX_PLPMTU is the largest size of PLPMTU that
      DPLPMTUD will attempt to use (see the constants defined in
      Section 5.1.2).

   MIN_PLPMTU:  The MIN_PLPMTU is the smallest size of PLPMTU that
      DPLPMTUD will attempt to use (see the constants defined in
      Section 5.1.2).

   MPS:  The Maximum Packet Size (MPS) is the largest size of
      application data block that can be sent across a network path by a
      PL using a single datagram (see Section 4.4).

   MSL:  The Maximum Segment Lifetime (MSL) is the maximum delay a
      packet is expected to experience across a path, taken as 2 minutes
      [BCP145].

   Packet:  A packet is the IP header(s) and any extension headers/
      options plus the IP payload.

   Packetization Layer (PL):  The PL is a layer of the network stack
      that places data into packets and performs transport protocol
      functions.  Examples of a PL include TCP, SCTP, SCTP over UDP,
      SCTP over DTLS, or QUIC.

   Path:  The path is the set of links and routers traversed by a packet
      between a source node and a destination node by a particular flow.

   Path MTU (PMTU):  The Path MTU (PMTU) is the minimum of the link MTU
      of all the links forming a network path between a source node and
      a destination node, as used by PMTUD.

   PTB:  In this document, the term PTB message is applied to both IPv4
      ICMP Unreachable messages (Type 3) that carry the error
      Fragmentation Needed (Type 3, Code 4) [RFC 792] and ICMPv6 Packet
      Too Big messages (Type 2) [RFC 4443].

   PTB_SIZE:  The PTB_SIZE is a value reported in a validated PTB
      message that indicates next-hop link MTU of a router along the
      path.

   PL_PTB_SIZE:  The size reported in a validated PTB message, reduced
      by the size of all headers added by layers below the PL.

   PLPMTU:  The Packetization Layer PMTU is an estimate of the largest
      size of PL datagram that can be sent by a path, controlled by
      PLPMTUD.

   PLPMTUD:  Packetization Layer Path MTU Discovery (PLPMTUD), the
      method described in this document for datagram PLs, which is an
      extension to Classical PMTU Discovery.

   Probe packet:  A probe packet is a datagram sent with a purposely
      chosen size (typically the current PLPMTU or larger) to detect if
      packets of this size can be successfully sent end-to-end across
      the network path.

   Unacknowledged PL:  A PL that does not itself provide a mechanism to
      confirm delivery of datagrams to the remote PL endpoint (e.g.,
      UDP), and therefore requires DPLPMTUD to provide a mechanism to
      detect black-holing of packets (c.f., Acknowledged PL).

3.  Features Required to Provide Datagram PLPMTUD

   The principles expressed in [RFC 4821] apply to the use of the
   technique with any PL.  TCP PLPMTUD has been defined using standard
   TCP protocol mechanisms.  Unlike TCP, a datagram PL requires
   additional mechanisms and considerations to implement PLPMTUD.

   The requirements for datagram PLPMTUD are:

   1.  Managing the PLPMTU: For datagram PLs, the PLPMTU is managed by
       DPLPMTUD.  A PL MUST NOT send a datagram (other than a probe
       packet) with a size at the PL that is larger than the current
       PLPMTU.

   2.  Probe packets: The network interface below the PL is REQUIRED to
       provide a way to transmit a probe packet that is larger than the
       PLPMTU.  In IPv4, a probe packet MUST be sent with the Don't
       Fragment (DF) bit set in the IP header and without network layer
       endpoint fragmentation.  In IPv6, a probe packet is always sent
       without source fragmentation (as specified in Section 5.4 of
       [RFC 8201]).

   3.  Reception feedback: The destination PL endpoint is REQUIRED to
       provide a feedback method that indicates to the DPLPMTUD sender
       when a probe packet has been received by the destination PL
       endpoint.  Section 6 provides examples of how a PL can provide
       this acknowledgment of received probe packets.

   4.  Probe loss recovery: It is RECOMMENDED to use probe packets that
       do not carry any user data that would require retransmission if
       lost.  Most datagram transports permit this.  If a probe packet
       contains user data requiring retransmission in case of loss, the
       PL (or layers above) is REQUIRED to arrange any retransmission
       and/or repair of any resulting loss.  The PL is REQUIRED to be
       robust in the case where probe packets are lost due to other
       reasons (including link transmission error, congestion).

   5.  PMTU parameters: A DPLPMTUD sender is RECOMMENDED to utilize
       information about the maximum size of packet that can be
       transmitted by the sender on the local link (e.g., the local link
       MTU).  A PL sender MAY utilize similar information about the
       maximum size of network-layer packet that a receiver can accept
       when this is supplied (note this could be less than EMTU_R).
       This avoids implementations trying to send probe packets that
       cannot be transferred by the local link.  Too high of a value
       could reduce the efficiency of the search algorithm.  Some
       applications also have a maximum transport protocol data unit
       (PDU) size, in which case there is no benefit from probing for a
       size larger than this (unless a transport allows multiplexing
       multiple applications' PDUs into the same datagram).

   6.  Processing PTB messages: A DPLPMTUD sender MAY optionally utilize
       PTB messages received from the network layer to help identify
       when a network path does not support the current size of probe
       packet.  Any received PTB message MUST be validated before it is
       used to update the PLPMTU discovery information [RFC 8201].  This
       validation confirms that the PTB message was sent in response to
       a packet originated by the sender and needs to be performed
       before the PLPMTU discovery method reacts to the PTB message.  A
       PTB message MUST NOT be used to increase the PLPMTU [RFC 8201] but
       could trigger a probe to test for a larger PLPMTU.  A valid
       PTB_SIZE is converted to a PL_PTB_SIZE before it is to be used in
       the DPLPMTUD state machine.  A PL_PTB_SIZE that is greater than
       that currently probed SHOULD be ignored.  (This PTB message ought
       to be discarded without further processing but could be utilized
       as an input that enables a resilience mode).

   7.  Probing and congestion control: A PL MAY use a congestion
       controller to decide when to send a probe packet.  If
       transmission of probe packets is limited by the congestion
       controller, this could result in transmission of probe packets
       being delayed or suspended during congestion.  When the
       transmission of probe packets is not controlled by the congestion
       controller, the interval between probe packets MUST be at least
       one RTT.  Loss of a probe packet SHOULD NOT be treated as an
       indication of congestion and SHOULD NOT trigger a congestion
       control reaction [RFC 4821] because this could result in
       unnecessary reduction of the sending rate.  An update to the
       PLPMTU (or MPS) MUST NOT increase the congestion window measured
       in bytes [RFC 4821].  Therefore, an increase in the packet size
       does not cause an increase in the data rate in bytes per second.
       A PL that maintains the congestion window in terms of a limit to
       the number of outstanding fixed-size packets SHOULD adapt this
       limit to compensate for the size of the actual packets.  The
       transmission of probe packets can interact with the operation of
       a PL that performs burst mitigation or pacing, and the PL could
       need transmission of probe packets to be regulated by these
       methods.

   8.  Probing and flow control: Flow control at the PL concerns the
       end-to-end flow of data using the PL service.  Flow control
       SHOULD NOT apply to DPLPMTU when probe packets use a design that
       does not carry user data to the remote application.

   9.  Shared PLPMTU state: The PMTU value calculated from the PLPMTU
       MAY also be stored with the corresponding entry associated with
       the destination in the IP layer cache and used by other PL
       instances.  The specification of PLPMTUD [RFC 4821] states, "If
       PLPMTUD updates the MTU for a particular path, all Packetization
       Layer sessions that share the path representation (as described
       in Section 5.2) SHOULD be notified to make use of the new MTU".
       Such methods MUST be robust to the wide variety of underlying
       network forwarding behaviors.  Section 5.2 of [RFC 8201] provides
       guidance on the caching of PMTU information and also the relation
       to IPv6 flow labels.

   In addition, the following principles are stated for design of a
   DPLPMTUD method:

   *  A PL MAY be designed to segment data blocks larger than the MPS
      into multiple datagrams.  However, not all datagram PLs support
      segmentation of data blocks.  It is RECOMMENDED that methods avoid
      forcing an application to use an arbitrary small MPS for
      transmission while the method is searching for the currently
      supported PLPMTU.  A reduced MPS can adversely impact the
      performance of an application.

   *  To assist applications in choosing a suitable data block size, the
      PL is RECOMMENDED to provide a primitive that returns the MPS
      derived from the PLPMTU to the higher layer using the PL.  The
      value of the MPS can change following a change in the path or loss
      of probe packets.

   *  Path validation: It is RECOMMENDED that methods are robust to path
      changes that could have occurred since the path characteristics
      were last confirmed and to the possibility of inconsistent path
      information being received.

   *  Datagram reordering: A method is REQUIRED to be robust to the
      possibility that a flow encounters reordering or that the traffic
      (including probe packets) is divided over more than one network
      path.

   *  Datagram delay and duplication: The feedback mechanism is REQUIRED
      to be robust to the possibility that packets could be
      significantly delayed or duplicated along a network path.

   *  When to probe: It is RECOMMENDED that methods determine whether
      the path has changed since it last measured the path.  This can
      help determine when to probe the path again.

4.  DPLPMTUD Mechanisms

   This section lists the protocol mechanisms used in this
   specification.

4.1.  PLPMTU Probe Packets

   The DPLPMTUD method relies upon the PL sender being able to generate
   probe packets with a specific size.  TCP is able to generate these
   probe packets by choosing to appropriately segment data being sent
   [RFC 4821].  In contrast, a datagram PL that constructs a probe packet
   has to either request an application to send a data block that is
   larger than that generated by an application, or to utilize padding
   functions to extend a datagram beyond the size of the application
   data block.  Protocols that permit exchange of control messages
   (without an application data block) can generate a probe packet by
   extending a control message with padding data.  The total size of a
   probe packet includes all headers and padding added to the payload
   data being sent (e.g., including protocol option fields, security-
   related fields such as an Authenticated Encryption with Associated
   Data (AEAD) tag, and TLS record layer padding).

   A receiver is REQUIRED to be able to distinguish an in-band data
   block from any added padding.  This is needed to ensure that any
   added padding is not passed on to an application at the receiver.

   This results in three possible ways that a sender can create a probe
   packet:

   Probing using padding data:  A probe packet that contains only
      control information together with any padding, which is needed to
      inflate to the size of the probe packet.  Since these probe
      packets do not carry an application-supplied data block, they do
      not typically require retransmission, although they do still
      consume network capacity and incur endpoint processing.

   Probing using application data and padding data:  A probe packet that
      contains a data block supplied by an application that is combined
      with padding to inflate the length of the datagram to the size of
      the probe packet.

   Probing using application data:  A probe packet that contains a data
      block supplied by an application that matches the size of the
      probe packet.  This method requests the application to issue a
      data block of the desired probe size.

   A PL that uses a probe packet carrying application data and that
   needs protection from the loss of this probe packet could perform
   transport-layer retransmission/repair of the data block (e.g., by
   retransmitting after loss is detected or by duplicating the data
   block in a datagram without the padding data).  This retransmitted
   data block might possibly need to be sent using a smaller PLPMTU,
   which could force the PL to use a smaller packet size to traverse the
   end-to-end path.  (This could utilize endpoint network-layer
   fragmentation or a PL that can resegment the data block into multiple
   datagrams).

   DPLPMTUD MAY choose to use only one of these methods to simplify the
   implementation.

   Probe messages sent by a PL MUST contain enough information to
   uniquely identify the probe within the Maximum Segment Lifetime
   (e.g., including a unique identifier from the PL or the DPLPMTUD
   implementation), while being robust to reordering and replay of probe
   response and PTB messages.

4.2.  Confirmation of Probed Packet Size

   The PL needs a method to determine (confirm) when probe packets have
   been successfully received end-to-end across a network path.

   Transport protocols can include end-to-end methods that detect and
   report reception of specific datagrams that they send (e.g., DCCP,
   SCTP, and QUIC provide keep-alive/heartbeat features).  When
   supported, this mechanism MAY also be used by DPLPMTUD to acknowledge
   reception of a probe packet.

   A PL that does not acknowledge data reception (e.g., UDP and UDP-
   Lite) is unable itself to detect when the packets that it sends are
   discarded because their size is greater than the actual PMTU.  These
   PLs need to rely on an application protocol to detect this loss.

   Section 6 specifies this function for a set of IETF-specified
   protocols.

4.3.  Black Hole Detection and Reducing the PLPMTU

   The description that follows uses the set of constants defined in
   Section 5.1.2 and variables defined in Section 5.1.3.

   Black hole detection is triggered by an indication that the network
   path could be unable to support the current PLPMTU size.

   There are three indicators that can be used to detect black holes:

   *  A validated PTB message can be received that indicates a
      PL_PTB_SIZE less than the current PLPMTU.  A DPLPMTUD method MUST
      NOT rely solely on this method.

   *  A PL can use the DPLPMTUD probing mechanism to periodically
      generate probe packets of the size of the current PLPMTU (e.g.,
      using the CONFIRMATION_TIMER, Section 5.1.1).  A timer tracks
      whether acknowledgments are received.  Successive loss of probes
      is an indication that the current path no longer supports the
      PLPMTU (e.g., when the number of probe packets sent without
      receiving an acknowledgment, PROBE_COUNT, becomes greater than
      MAX_PROBES).

   *  A PL can utilize an event that indicates the network path no
      longer sustains the sender's PLPMTU size.  This could use a
      mechanism implemented within the PL to detect excessive loss of
      data sent with a specific packet size and then conclude that this
      excessive loss could be a result of an invalid PLPMTU (as in
      PLPMTUD for TCP [RFC 4821]).

   The three methods can result in different transmission patterns for
   packet probes and are expected to result in different responsiveness
   following a change in the actual PMTU.

   A PL MAY inhibit sending probe packets when no application data has
   been sent since the previous probe packet.  A PL that resumes sending
   user data MAY continue PLPMTU discovery for each path.  This allows
   it to use an up-to-date PLPMTU.  However, this could result in
   additional packets being sent.

   When the method detects that the current PLPMTU is not supported,
   DPLPMTUD sets a lower PLPMTU and a lower MPS.  The PL then confirms
   that the new PLPMTU can be successfully used across the path.  A
   probe packet could need to be smaller than the size of the data block
   generated by the application.

4.4.  The Maximum Packet Size (MPS)

   The result of probing determines a usable PLPMTU, which is used to
   set the MPS used by the application.  The MPS is smaller than the
   PLPMTU because it is reduced by the size of PL headers (including the
   overhead of security-related fields such as an AEAD tag and TLS
   record layer padding).  The relationship between the MPS and the
   PLPMTUD is illustrated in Figure 1.

   Any additional
     headers         .--- MPS -----.
            |        |             |
            v        v             v
     +------------------------------+
     | IP | ** | PL | protocol data |
     +------------------------------+

                <----- PLPMTU ----->
     <---------- PMTU -------------->

               Figure 1: Relationship between MPS and PLPMTU

   A PL is unable to send a packet (other than a probe packet) with a
   size larger than the current PLPMTU at the network layer.  To avoid
   this, a PL MAY be designed to segment data blocks larger than the MPS
   into multiple datagrams.

   DPLPMTUD seeks to avoid IP fragmentation.  An attempt to send a data
   block larger than the MPS will therefore fail if a PL is unable to
   segment data.  To determine the largest data block that can be sent,
   a PL SHOULD provide applications with a primitive that returns the
   MPS, derived from the current PLPMTU.

   If DPLPMTUD results in a change to the MPS, the application needs to
   adapt to the new MPS.  A particular case can arise when packets have
   been sent with a size less than the MPS and the PLPMTU was
   subsequently reduced.  If these packets are lost, the PL MAY segment
   the data using the new MPS.  If a PL is unable to resegment a
   previously sent datagram (e.g., [RFC 4960]), then the sender either
   discards the datagram or could perform retransmission using network-
   layer fragmentation to form multiple IP packets not larger than the
   PLPMTU.  For IPv4, the use of endpoint fragmentation by the sender is
   preferred over clearing the DF bit in the IPv4 header.  Operational
   experience reveals that IP fragmentation can reduce the reliability
   of Internet communication [RFC 8900], which may reduce the probability
   of successful retransmission.

4.5.  Disabling the Effect of PMTUD

   A PL implementing this specification MUST suspend network layer
   processing of outgoing packets that enforces a PMTU
   [RFC 1191][RFC 8201] for each flow utilizing DPLPMTUD and instead use
   DPLPMTUD to control the size of packets that are sent by a flow.
   This removes the need for the network layer to drop or to fragment
   sent packets that have a size greater than the PMTU.

4.6.  Response to PTB Messages

   This method requires the DPLPMTUD sender to validate any received PTB
   message before using the PTB information.  The response to a PTB
   message depends on the PL_PTB_SIZE calculated from the PTB_SIZE in
   the PTB message, the state of the PLPMTUD state machine, and the IP
   protocol being used.

   Section 4.6.1 describes validation for both IPv4 ICMP Unreachable
   messages (Type 3) and ICMPv6 Packet Too Big messages, both of which
   are referred to as PTB messages in this document.

4.6.1.  Validation of PTB Messages

   This section specifies utilization and validation of PTB messages.

   *  A simple implementation MAY ignore received PTB messages, and in
      this case, the PLPMTU is not updated when a PTB message is
      received.

   *  A PL that supports PTB messages MUST validate these messages
      before they are further processed.

   A PL that receives a PTB message from a router or middlebox performs
   ICMP validation (see Section 4 of [RFC 8201] and Section 5.2 of
   [BCP145]).  Because DPLPMTUD operates at the PL, the PL needs to
   check that each received PTB message is received in response to a
   packet transmitted by the endpoint PL performing DPLPMTUD.

   The PL MUST check the protocol information in the quoted packet
   carried in an ICMP PTB message payload to validate the message
   originated from the sending node.  This validation includes
   determining that the combination of the IP addresses, the protocol,
   the source port, and destination port match those returned in the
   quoted packet -- this is also necessary for the PTB message to be
   passed to the corresponding PL.

   The validation SHOULD utilize information that is not simple for an
   off-path attacker to determine [BCP145].  For example, it could check
   the value of a protocol header field known only to the two PL
   endpoints.  A datagram application that uses well-known source and
   destination ports ought to also rely on other information to complete
   this validation.

   These checks are intended to provide protection from packets that
   originate from a node that is not on the network path.  A PTB message
   that does not complete the validation MUST NOT be further utilized by
   the DPLPMTUD method, as discussed in the Security Considerations
   section (Section 8).

   Section 4.6.2 describes this processing of PTB messages.

4.6.2.  Use of PTB Messages

   PTB messages that have been validated MAY be utilized by the DPLPMTUD
   algorithm but MUST NOT be used directly to set the PLPMTU.

   Before using the size reported in the PTB message, it must first be
   converted to a PL_PTB_SIZE.  The PL_PTB_SIZE is smaller than the
   PTB_SIZE because it is reduced by headers below the PL, including any
   IP options or extensions added to the PL packet.

   A method that utilizes these PTB messages can improve the speed at
   which the algorithm detects an appropriate PLPMTU by triggering an
   immediate probe for the PL_PTB_SIZE (resulting in a network-layer
   packet of size PTB_SIZE), compared to one that relies solely on
   probing using a timer-based search algorithm.

   A set of checks are intended to provide protection from a router that
   reports an unexpected PTB_SIZE.  The PL also needs to check that the
   indicated PL_PTB_SIZE is less than the size used by probe packets and
   at least the minimum size accepted.

   This section provides a summary of how PTB messages can be utilized,
   using the set of constants defined in Section 5.1.2.  This processing
   depends on the PL_PTB_SIZE and the current value of a set of
   variables:

   PL_PTB_SIZE < MIN_PLPMTU
      *  Invalid PL_PTB_SIZE, see Section 4.6.1.

      *  PTB message ought to be discarded without further processing
         (i.e., PLPMTU is not modified).

      *  The information could be utilized as an input that triggers the
         enabling of a resilience mode (see Section 5.3.3).

   MIN_PLPMTU < PL_PTB_SIZE < BASE_PLPMTU
      *  A robust PL MAY enter an error state (see Section 5.2) for an
         IPv4 path when the PL_PTB_SIZE reported in the PTB message is
         larger than or equal to 68 bytes [RFC 791] and when this is
         less than the BASE_PLPMTU.

      *  A robust PL MAY enter an error state (see Section 5.2) for an
         IPv6 path when the PL_PTB_SIZE reported in the PTB message is
         larger than or equal to 1280 bytes [RFC 8200] and when this is
         less than the BASE_PLPMTU.

   BASE_PLPMTU <= PL_PTB_SIZE < PLPMTU
      *  This could be an indication of a black hole.  The PLPMTU SHOULD
         be set to BASE_PLPMTU (the PLPMTU is reduced to the BASE_PLPMTU
         to avoid unnecessary packet loss when a black hole is
         encountered).

      *  The PL ought to start a search to quickly discover the new
         PLPMTU.  The PL_PTB_SIZE reported in the PTB message can be
         used to initialize a search algorithm.

   PLPMTU < PL_PTB_SIZE < PROBED_SIZE
      *  The PLPMTU continues to be valid, but the size of a packet used
         to search (PROBED_SIZE) was larger than the actual PMTU.

      *  The PLPMTU is not updated.

      *  The PL can use the reported PL_PTB_SIZE from the PTB message as
         the next search point when it resumes the search algorithm.

   PL_PTB_SIZE >= PROBED_SIZE
      *  Inconsistent network signal.

      *  PTB message ought to be discarded without further processing
         (i.e., PLPMTU is not modified).

      *  The information could be utilized as an input to trigger the
         enabling of a resilience mode.

5.  Datagram Packetization Layer PMTUD

   This section specifies Datagram PLPMTUD (DPLPMTUD).  The method can
   be introduced at various points (as indicated with * in Figure 2) in
   the IP protocol stack to discover the PLPMTU so that an application
   can utilize an appropriate MPS for the current network path.

   DPLPMTUD SHOULD only be performed at one layer between a pair of
   endpoints.  Therefore, an upper PL or application should avoid using
   DPLPMTUD when this is already enabled in a lower layer.  A PL MUST
   adjust the MPS indicated by DPLPMTUD to account for any additional
   overhead introduced by the PL.

   +----------------------+
   |     Application*     |
   +-----+------------+---+
         |            |
     +---+--+      +--+--+
     | QUIC*|      |SCTP*|
     +---+--+      +-+-+-+
         |           | |
         +---+  +----+ |
             |  |      |
           +-+--+-+    |
           | UDP  |    |
           +---+--+    |
               |       |
   +-----------+-------+--+
   |  Network Interface   |
   +----------------------+

            Figure 2: Examples Where DPLPMTUD Can Be Implemented

   The central idea of DPLPMTUD is probing by a sender.  Probe packets
   are sent to find the maximum size of user message that can be
   completely transferred across the network path from the sender to the
   destination.

   The following sections identify the components needed for
   implementation, provide an overview of the phases of operation, and
   specify the state machine and search algorithm.

5.1.  DPLPMTUD Components

   This section describes the timers, constants, and variables of
   DPLPMTUD.

5.1.1.  Timers

   The method utilizes up to three timers:

   PROBE_TIMER:  The PROBE_TIMER is configured to expire after a period
      longer than the maximum time to receive an acknowledgment to a
      probe packet.  This value MUST NOT be smaller than 1 second and
      SHOULD be larger than 15 seconds.  Guidance on the selection of
      the timer value is provided in Section 3.1.1 of the UDP Usage
      Guidelines [BCP145].

   PMTU_RAISE_TIMER:  The PMTU_RAISE_TIMER is configured to the period a
      sender will continue to use the current PLPMTU, after which it
      reenters the Search Phase.  This timer has a period of 600
      seconds, as recommended by PLPMTUD [RFC 4821].

      DPLPMTUD MAY inhibit sending probe packets when no application
      data has been sent since the previous probe packet.  A PL
      preferring to use an up-to-date PMTU once user data is sent again
      can choose to continue PMTU discovery for each path.  However,
      this will result in sending additional packets.

   CONFIRMATION_TIMER:  When an acknowledged PL is used, this timer MUST
      NOT be used.  For other PLs, the CONFIRMATION_TIMER is configured
      to the period a PL sender waits before confirming the current
      PLPMTU is still supported.  This is less than the PMTU_RAISE_TIMER
      and used to decrease the PLPMTU (e.g., when a black hole is
      encountered).  Confirmation needs to be frequent enough when data
      is flowing that the sending PL does not black hole extensive
      amounts of traffic.  Guidance on selection of the timer value are
      provided in Section 3.1.1 of the UDP Usage Guidelines [BCP145].

      DPLPMTUD MAY inhibit sending probe packets when no application
      data has been sent since the previous probe packet.  A PL
      preferring to use an up-to-date PMTU once user data is sent again,
      can choose to continue PMTU discovery for each path.  However,
      this could result in sending additional packets.

   DPLPMTUD specifies various timers; however, an implementation could
   choose to realize these timer functions using a single timer.

5.1.2.  Constants

   The following constants are defined:

   MAX_PROBES:  The MAX_PROBES is the maximum value of the PROBE_COUNT
      counter (see Section 5.1.3).  MAX_PROBES represents the limit for
      the number of consecutive probe attempts of any size.  Search
      algorithms benefit from a MAX_PROBES value greater than 1 because
      this can provide robustness to isolated packet loss.  The default
      value of MAX_PROBES is 3.

   MIN_PLPMTU:  The MIN_PLPMTU is the smallest size of PLPMTU that
      DPLPMTUD will attempt to use.  An endpoint could need to configure
      the MIN_PLPMTU to provide space for extension headers and other
      encapsulations at layers below the PL.  This value can be
      interface and path dependent.  For IPv6, this size is greater than
      or equal to the size at the PL that results in an 1280-byte IPv6
      packet, as specified in [RFC 8200].  For IPv4, this size is greater
      than or equal to the size at the PL that results in an 68-byte
      IPv4 packet.  Note: An IPv4 router is required to be able to
      forward a datagram of 68 bytes without further fragmentation.
      This is the combined size of an IPv4 header and the minimum
      fragment size of 8 bytes.  In addition, receivers are required to
      be able to reassemble fragmented datagrams at least up to 576
      bytes, as stated in Section 3.3.3 of [RFC 1122].

   MAX_PLPMTU:  The MAX_PLPMTU is the largest size of PLPMTU.  This has
      to be less than or equal to the maximum size of the PL packet that
      can be sent on the outgoing interface (constrained by the local
      interface MTU).  When known, this also ought to be less than the
      maximum size of PL packet that can be received by the remote
      endpoint (constrained by EMTU_R).  It can be limited by the design
      or configuration of the PL being used.  An application, or PL, MAY
      choose a smaller MAX_PLPMTU when there is no need to send packets
      larger than a specific size.

   BASE_PLPMTU:  The BASE_PLPMTU is a configured size expected to work
      for most paths.  The size is equal to or larger than the
      MIN_PLPMTU and smaller than the MAX_PLPMTU.  For most PLs, a
      suitable BASE_PLPMTU will be larger than 1200 bytes.  When using
      IPv4, there is no currently equivalent size specified, and a
      default BASE_PLPMTU of 1200 bytes is RECOMMENDED.

5.1.3.  Variables

   This method utilizes a set of variables:

   PROBED_SIZE:  The PROBED_SIZE is the size of the current probe packet
      as determined at the PL.  This is a tentative value for the
      PLPMTU, which is awaiting confirmation by an acknowledgment.

   PROBE_COUNT:  The PROBE_COUNT is a count of the number of successive
      unsuccessful probe packets that have been sent.  Each time a probe
      packet is acknowledged, the value is set to zero.  (Some probe
      loss is expected while searching, therefore loss of a single probe
      is not an indication of a PMTU problem.)

   Figure 3 illustrates the relationship between the packet size
   constants and variables at a point of time when the DPLPMTUD
   algorithm performs path probing to increase the size of the PLPMTU.
   A probe packet has been sent of size PROBED_SIZE.  Once this is
   acknowledged, the PLPMTU will raise to PROBED_SIZE, allowing the
   DPLPMTUD algorithm to further increase PROBED_SIZE toward sending a
   probe with the size of the actual PMTU.

        MIN_PLPMTU                                MAX_PLPMTU
          <------------------------------------------->
                         |        |     |
                         v        |     |
                   BASE_PLPMTU    |     v
                                  |  PROBED_SIZE
                                  v
                                PLPMTU

    Figure 3: Relationships between Packet Size Constants and Variables

5.1.4.  Overview of DPLPMTUD Phases

   This section provides a high-level, informative view of the DPLPMTUD
   method, by describing the movement of the method through several
   phases of operation.  More detail is available in the state machine,
   Section 5.2.

                       +------+
              +------->| Base |-----------------+ Connectivity
              |        +------+                 | or BASE_PLPMTU
              |           |                     | confirmation failed
              |           |                     v
              |           | Connectivity    +-------+
              |           | and BASE_PLPMTU | Error |
              |           | confirmed       +-------+
              |           |                     | Consistent
              |           v                     | connectivity
   Black Hole |       +--------+                | and BASE_PLPMTU
    detected  |       | Search |<---------------+ confirmed
              |       +--------+
              |          ^  |
              |          |  |
              |    Raise |  | Search
              |    timer |  | algorithm
              |  expired |  | completed
              |          |  |
              |          |  v
              |   +-----------------+
              +---| Search Complete |
                  +-----------------+

                         Figure 4: DPLPMTUD Phases

   Base:  The Base Phase confirms connectivity to the remote peer using
      packets of the BASE_PLPMTU.  The confirmation of connectivity is
      implicit for a connection-oriented PL (where it can be performed
      in a PL connection handshake).  A connectionless PL sends a probe
      packet and uses acknowledgment of this probe packet to confirm
      that the remote peer is reachable.

      The sender also confirms that BASE_PLPMTU is supported across the
      network path.  This may be achieved by using a PL mechanism (e.g.,
      using a handshake packet of size BASE_PLPMTU) or by sending a
      probe packet of size BASE_PLPMTU and confirming that this is
      received.

      A probe packet of size BASE_PLPMTU can be sent immediately on the
      initial entry to the Base Phase (following a connectivity check).
      A PL that does not wish to support a path with a PLPMTU less than
      BASE_PLPMTU can simplify the phase into a single step by
      performing the connectivity checks with a probe of the BASE_PLPMTU
      size.

      Once confirmed, DPLPMTUD enters the Search Phase.  If the Base
      Phase fails to confirm the BASE_PLPMTU, DPLPMTUD enters the Error
      Phase.

   Search:  The Search Phase utilizes a search algorithm to send probe
      packets to seek to increase the PLPMTU.  The algorithm concludes
      when it has found a suitable PLPMTU by entering the Search
      Complete Phase.

      A PL could respond to PTB messages using the PTB to advance or
      terminate the search, see Section 4.6.

   Search Complete:  The Search Complete Phase is entered when the
      PLPMTU is supported across the network path.  A PL can use a
      CONFIRMATION_TIMER to periodically repeat a probe packet for the
      current PLPMTU size.  If the sender is unable to confirm
      reachability (e.g., if the CONFIRMATION_TIMER expires) or the PL
      signals a lack of reachability, a black hole has been detected and
      DPLPMTUD enters the Base Phase.

      The PMTU_RAISE_TIMER is used to periodically resume the Search
      Phase to discover if the PLPMTU can be raised.  Black hole
      detection causes the sender to enter the Base Phase.

   Error:  The Error Phase is entered when there is conflicting or
      invalid PLPMTU information for the path (e.g., a failure to
      support the BASE_PLPMTU) that causes DPLPMTUD to be unable to
      progress, and the PLPMTU is lowered.

      DPLPMTUD remains in the Error Phase until a consistent view of the
      path can be discovered and it has also been confirmed that the
      path supports the BASE_PLPMTU (or DPLPMTUD is suspended).

   A method that only reduces the PLPMTU to a suitable size would be
   sufficient to ensure reliable operation but can be very inefficient
   when the actual PMTU changes or when the method (for whatever reason)
   makes a suboptimal choice for the PLPMTU.

   A full implementation of DPLPMTUD provides an algorithm enabling the
   DPLPMTUD sender to increase the PLPMTU following a change in the
   characteristics of the path, such as when a link is reconfigured with
   a larger MTU, or when there is a change in the set of links traversed
   by an end-to-end flow (e.g., after a routing or path failover
   decision).

5.2.  State Machine

   A state machine for DPLPMTUD is depicted in Figure 5.  If multipath
   or multihoming is supported, a state machine is needed for each path.

   Note: Not all changes are shown to simplify the diagram.

      |         |
      | Start   | PL indicates loss
      |         |  of connectivity
      v         v
   +---------------+                                   +---------------+
   |    DISABLED   |                                   |     ERROR     |
   +---------------+               PROBE_TIMER expiry: +---------------+
           | PL indicates     PROBE_COUNT = MAX_PROBES or    ^      |
           | connectivity  PTB: PL_PTB_SIZE < BASE_PLPMTU    |      |
           +--------------------+         +------------------+      |
                                |         |                         |
                                v         |       BASE_PLPMTU Probe |
                             +---------------+          acked       |
                             |      BASE     |--------------------->+
                             +---------------+                      |
                                ^ |    ^  ^                         |
            Black hole detected | |    |  | Black hole detected     |
           +--------------------+ |    |  +--------------------+    |
           |                      +----+                       |    |
           |                PROBE_TIMER expiry:                |    |
           |             PROBE_COUNT < MAX_PROBES              |    |
           |                                                   |    |
           |               PMTU_RAISE_TIMER expiry             |    |
           |    +-----------------------------------------+    |    |
           |    |                                         |    |    |
           |    |                                         v    |    v
   +---------------+                                   +---------------+
   |SEARCH_COMPLETE|                                   |   SEARCHING   |
   +---------------+                                   +---------------+
      |    ^    ^                                         |    |    ^
      |    |    |                                         |    |    |
      |    |    +-----------------------------------------+    |    |
      |    |            MAX_PLPMTU Probe acked or              |    |
      |    |  PROBE_TIMER expiry: PROBE_COUNT = MAX_PROBES or  |    |
      +----+            PTB: PL_PTB_SIZE = PLPMTU              +----+
   CONFIRMATION_TIMER expiry:                        PROBE_TIMER expiry:
   PROBE_COUNT < MAX_PROBES or               PROBE_COUNT < MAX_PROBES or
        PLPMTU Probe acked                           Probe acked or PTB:
                                      PLPMTU < PL_PTB_SIZE < PROBED_SIZE

                Figure 5: State Machine for Datagram PLPMTUD


   The following states are defined:

   DISABLED:  The DISABLED state is the initial state before probing has
      started.  It is also entered from any other state, when the PL
      indicates loss of connectivity.  This state is left once the PL
      indicates connectivity to the remote PL.  When transitioning to
      the BASE state, a probe packet of size BASE_PLPMTU can be sent
      immediately.

   BASE:  The BASE state is used to confirm that the BASE_PLPMTU size is
      supported by the network path and is designed to allow an
      application to continue working when there are transient
      reductions in the actual PMTU.  It also seeks to avoid long
      periods when a sender searching for a larger PLPMTU is unaware
      that packets are not being delivered due to a packet or ICMP black
      hole.

      On entry, the PROBED_SIZE is set to the BASE_PLPMTU size, and the
      PROBE_COUNT is set to zero.

      Each time a probe packet is sent, the PROBE_TIMER is started.  The
      state is exited when the probe packet is acknowledged, and the PL
      sender enters the SEARCHING state.

      The state is also left when the PROBE_COUNT reaches MAX_PROBES or
      a received PTB message is validated.  This causes the PL sender to
      enter the ERROR state.

   SEARCHING:  The SEARCHING state is the main probing state.  This
      state is entered when probing for the BASE_PLPMTU completes.

      Each time a probe packet is acknowledged, the PROBE_COUNT is set
      to zero, the PLPMTU is set to the PROBED_SIZE, and then the
      PROBED_SIZE is increased using the search algorithm (as described
      in Section 5.3).

      When a probe packet is sent and not acknowledged within the period
      of the PROBE_TIMER, the PROBE_COUNT is incremented, and a new
      probe packet is transmitted.

      The state is exited to enter SEARCH_COMPLETE when the PROBE_COUNT
      reaches MAX_PROBES, a validated PTB is received that corresponds
      to the last successfully probed size (PL_PTB_SIZE = PLPMTU), or a
      probe of size MAX_PLPMTU is acknowledged (PLPMTU = MAX_PLPMTU).

      When a black hole is detected in the SEARCHING state, this causes
      the PL sender to enter the BASE state.

   SEARCH_COMPLETE:  The SEARCH_COMPLETE state indicates that a search
      has completed.  This is the normal maintenance state, where the PL
      is not probing to update the PLPMTU.  DPLPMTUD remains in this
      state until either the PMTU_RAISE_TIMER expires or a black hole is
      detected.

      When DPLPMTUD uses an unacknowledged PL and is in the
      SEARCH_COMPLETE state, a CONFIRMATION_TIMER periodically resets
      the PROBE_COUNT and schedules a probe packet with the size of the
      PLPMTU.  If MAX_PROBES successive PLPMTUD-sized probes fail to be
      acknowledged, the method enters the BASE state.  When used with an
      acknowledged PL (e.g., SCTP), DPLPMTUD SHOULD NOT continue to
      generate PLPMTU probes in this state.

   ERROR:  The ERROR state represents the case where either the network
      path is not known to support a PLPMTU of at least the BASE_PLPMTU
      size or when there is contradictory information about the network
      path that would otherwise result in excessive variation in the MPS
      signaled to the higher layer.  The state implements a method to
      mitigate oscillation in the state-event engine.  It signals a
      conservative value of the MPS to the higher layer by the PL.  The
      state is exited when packet probes no longer detect the error.
      The PL sender then enters the SEARCHING state.

      Implementations are permitted to enable endpoint fragmentation if
      the DPLPMTUD is unable to validate MIN_PLPMTU within PROBE_COUNT
      probes.  If DPLPMTUD is unable to validate MIN_PLPMTU, the
      implementation will transition to the DISABLED state.

      Note: MIN_PLPMTU could be identical to BASE_PLPMTU, simplifying
      the actions in this state.

5.3.  Search to Increase the PLPMTU

   This section describes the algorithms used by DPLPMTUD to search for
   a larger PLPMTU.

5.3.1.  Probing for a Larger PLPMTU

   Implementations use a search algorithm across the search range to
   determine whether a larger PLPMTU can be supported across a network
   path.

   The method discovers the search range by confirming the minimum
   PLPMTU and then using the probe method to select a PROBED_SIZE less
   than or equal to MAX_PLPMTU.  MAX_PLPMTU is the minimum of the local
   MTU and EMTU_R (when this is learned from the remote endpoint).  The
   MAX_PLPMTU MAY be reduced by an application that sets a maximum to
   the size of datagrams it will send.

   The PROBE_COUNT is initialized to zero when the first probe with a
   size greater than or equal to PLPMTU is sent.  Each probe packet
   successfully sent to the remote peer is confirmed by acknowledgment
   at the PL (see Section 4.1).

   Each time a probe packet is sent to the destination, the PROBE_TIMER
   is started.  The timer is canceled when the PL receives
   acknowledgment that the probe packet has been successfully sent
   across the path (Section 4.1).  This confirms that the PROBED_SIZE is
   supported, and the PROBED_SIZE value is then assigned to the PLPMTU.
   The search algorithm can continue to send subsequent probe packets of
   an increasing size.

   If the timer expires before a probe packet is acknowledged, the probe
   has failed to confirm the PROBED_SIZE.  Each time the PROBE_TIMER
   expires, the PROBE_COUNT is incremented, the PROBE_TIMER is
   reinitialized, and a new probe of the same size or any other size
   (determined by the search algorithm) can be sent.  The maximum number
   of consecutive failed probes is configured (MAX_PROBES).  If the
   value of the PROBE_COUNT reaches MAX_PROBES, probing will stop, and
   the PL sender enters the SEARCH_COMPLETE state.

5.3.2.  Selection of Probe Sizes

   The search algorithm determines a minimum useful gain in PLPMTU.  It
   would not be constructive for a PL sender to attempt to probe for all
   sizes.  This would incur unnecessary load on the path.
   Implementations SHOULD select the set of probe packet sizes to
   maximize the gain in PLPMTU from each search step.

   Implementations could optimize the search procedure by selecting step
   sizes from a table of common PMTU sizes.  When selecting the
   appropriate next size to search, an implementer ought to also
   consider that there can be common sizes of MPS that applications seek
   to use, and there could be common sizes of MTU used within the
   network.

5.3.3.  Resilience to Inconsistent Path Information

   A decision to increase the PLPMTU needs to be resilient to the
   possibility that information learned about the network path is
   inconsistent.  A path is inconsistent when, for example, probe
   packets are lost due to other reasons (i.e., not packet size) or due
   to frequent path changes.  Frequent path changes could occur by
   unexpected "flapping" -- where some packets from a flow pass along
   one path, but other packets follow a different path with different
   properties.

   A PL sender is able to detect inconsistency either from the sequence
   of PLPMTU probes that are acknowledged or from the sequence of PTB
   messages that it receives.  When inconsistent path information is
   detected, a PL sender could use an alternate search mode that clamps
   the offered MPS to a smaller value for a period of time.  This avoids
   unnecessary loss of packets.

5.4.  Robustness to Inconsistent Paths

   Some paths could be unable to sustain packets of the BASE_PLPMTU
   size.  The Error State could be implemented to provide robustness to
   such paths.  This allows fallback to a smaller than desired PLPMTU
   rather than suffer connectivity failure.  This could utilize methods
   such as endpoint IP fragmentation to enable the PL sender to
   communicate using packets smaller than the BASE_PLPMTU.

6.  Specification of Protocol-Specific Methods

   DPLPMTUD requires protocol-specific details to be specified for each
   PL that is used.

   The first subsection provides guidance on how to implement the
   DPLPMTUD method as a part of an application using UDP or UDP-Lite.
   The guidance also applies to other datagram services that do not
   include a specific transport protocol (such as a tunnel
   encapsulation).  The following subsections describe how DPLPMTUD can
   be implemented as a part of the transport service, allowing
   applications using the service to benefit from discovery of the
   PLPMTU without themselves needing to implement this method when using
   SCTP and QUIC.

6.1.  Application Support for DPLPMTUD with UDP or UDP-Lite

   The current specifications of UDP [RFC 768] and UDP-Lite [RFC 3828] do
   not define a method in the RFC series that supports PLPMTUD.  In
   particular, the UDP transport does not provide the transport features
   needed to implement datagram PLPMTUD.

   The DPLPMTUD method can be implemented as a part of an application
   built directly or indirectly on UDP or UDP-Lite but relies on higher-
   layer protocol features to implement the method [BCP145].

   Some primitives used by DPLPMTUD might not be available via the
   Datagram API (e.g., the ability to access the PLPMTU from the IP-
   layer cache or to interpret received PTB messages).

   In addition, it is recommended that PMTU discovery is not performed
   by multiple protocol layers.  An application SHOULD avoid using
   DPLPMTUD when the underlying transport system provides this
   capability.  A common method for managing the PLPMTU has benefits,
   both in the ability to share state between different processes and in
   opportunities to coordinate probing for different PL instances.

6.1.1.  Application Request

   An application needs an application-layer protocol mechanism (such as
   a message acknowledgment method) that solicits a response from a
   destination endpoint.  The method SHOULD allow the sender to check
   the value returned in the response to provide additional protection
   from off-path insertion of data [BCP145].  Suitable methods include a
   parameter known only to the two endpoints, such as a session ID or
   initialized sequence number.

6.1.2.  Application Response

   An application needs an application-layer protocol mechanism to
   communicate the response from the destination endpoint.  This
   response could indicate successful reception of the probe across the
   path but could also indicate that some (or all packets) have failed
   to reach the destination.

6.1.3.  Sending Application Probe Packets

   A probe packet can carry an application data block, but the
   successful transmission of this data is at risk when used for
   probing.  Some applications might prefer to use a probe packet that
   does not carry an application data block to avoid disruption of data
   transfer.

6.1.4.  Initial Connectivity

   An application that does not have other higher-layer information
   confirming connectivity with the remote peer SHOULD implement a
   connectivity mechanism using acknowledged probe packets before
   entering the BASE state.

6.1.5.  Validating the Path

   An application that does not have other higher-layer information
   confirming correct delivery of datagrams SHOULD implement the
   CONFIRMATION_TIMER to periodically send probe packets while in the
   SEARCH_COMPLETE state.

6.1.6.  Handling of PTB Messages

   An application that is able and wishes to receive PTB messages MUST
   perform ICMP validation as specified in Section 5.2 of [BCP145].
   This requires that the application checks each received PTB message
   to validate that it was is received in response to transmitted
   traffic and that the reported PL_PTB_SIZE is less than the current
   probed size (see Section 4.6.2).  A validated PTB message MAY be used
   as input to the DPLPMTUD algorithm but MUST NOT be used directly to
   set the PLPMTU.

6.2.  DPLPMTUD for SCTP

   Section 10.2 of [RFC 4821] specifies a recommended PLPMTUD probing
   method for SCTP, and Section 7.3 of [RFC 4960] recommends an endpoint
   apply the techniques in RFC 4821 on a per-destination-address basis.
   The specification for DPLPMTUD continues the practice of using the PL
   to discover the PMTU but updates RFC 4960 with a recommendation to use
   the method specified in this document: The RECOMMENDED method for
   generating probes is to add a chunk consisting only of padding to an
   SCTP message.  The PAD chunk defined in [RFC 4820] SHOULD be attached
   to a minimum-length HEARTBEAT (HB) chunk to build a probe packet.
   This enables probing without affecting the transfer of user messages
   and without being limited by congestion control or flow control.
   This is preferred to using DATA chunks (with padding as required) as
   path probes.

   Section 6.9 of [RFC 4960] describes dividing the user messages into
   DATA chunks sent by the PL when using SCTP.  This notes that once an
   SCTP message has been sent, it cannot be resegmented.  [RFC 4960]
   describes the method for retransmitting DATA chunks when the MPS has
   been reduced, and Section 6.9 of [RFC 4960] describes use of IP
   fragmentation for this case.  This is unchanged by this document.

6.2.1.  SCTP/IPv4 and SCTP/IPv6

6.2.1.1.  Initial Connectivity

   The base protocol is specified in [RFC 4960].  This provides an
   acknowledged PL.  A sender can therefore enter the BASE state as soon
   as connectivity has been confirmed.

6.2.1.2.  Sending SCTP Probe Packets

   Probe packets consist of an SCTP common header followed by a
   HEARTBEAT chunk and a PAD chunk.  The PAD chunk is used to control
   the length of the probe packet.  The HEARTBEAT chunk is used to
   trigger the sending of a HEARTBEAT ACK chunk.  The reception of the
   HEARTBEAT ACK chunk acknowledges reception of a successful probe.  A
   successful probe updates the association and path counters, but an
   unsuccessful probe is discounted (assumed to be a result of choosing
   too large a PLPMTU).

   The SCTP sender needs to be able to determine the total size of a
   probe packet.  The HEARTBEAT chunk could carry a Heartbeat
   Information parameter that includes, besides the information
   suggested in [RFC 4960], the probe size to help an implementation
   associate a HEARTBEAT ACK with the size of probe that was sent.  The
   sender could also use other methods, such as sending a nonce and
   verifying the information returned also contains the corresponding
   nonce.  The length of the PAD chunk is computed by reducing the
   probing size by the size of the SCTP common header and the HEARTBEAT
   chunk.  The payload of the PAD chunk contains arbitrary data.  When
   transmitted at the IP layer, the PMTU size also includes the IPv4 or
   IPv6 header(s).

   Probing can start directly after the PL handshake; this can be done
   before data is sent.  Assuming this behavior (i.e., the PMTU is
   smaller than or equal to the interface MTU), this process will take
   several round-trip time periods, dependent on the number of DPLPMTUD
   probes sent.  The Heartbeat timer can be used to implement the
   PROBE_TIMER.

6.2.1.3.  Validating the Path with SCTP

   Since SCTP provides an acknowledged PL, a sender MUST NOT implement
   the CONFIRMATION_TIMER while in the SEARCH_COMPLETE state.

6.2.1.4.  PTB Message Handling by SCTP

   Normal ICMP validation MUST be performed as specified in Appendix C
   of [RFC 4960].  This requires that the first 8 bytes of the SCTP
   common header are quoted in the payload of the PTB message, which can
   be the case for ICMPv4 and is normally the case for ICMPv6.

   When a PTB message has been validated, the PL_PTB_SIZE calculated
   from the PTB_SIZE reported in the PTB message SHOULD be used with the
   DPLPMTUD algorithm, provided that the reported PL_PTB_SIZE is less
   than the current probe size (see Section 4.6).

6.2.2.  DPLPMTUD for SCTP/UDP

   The UDP encapsulation of SCTP is specified in [RFC 6951].

   This specification updates the reference to RFC 4821 in Section 5.6
   of RFC 6951 to refer to this document (RFC 8899).  RFC 6951 is
   updated by the addition of the following sentence at the end of
   Section 5.6:

   |  The RECOMMENDED method for determining the MTU of the path is
   |  specified in RFC 8899.

6.2.2.1.  Initial Connectivity

   A sender can enter the BASE state as soon as SCTP connectivity has
   been confirmed.

6.2.2.2.  Sending SCTP/UDP Probe Packets

   Packet probing can be performed as specified in Section 6.2.1.2.  The
   size of the probe packet includes the 8 bytes of UDP header.  This
   has to be considered when filling the probe packet with the PAD
   chunk.

6.2.2.3.  Validating the Path with SCTP/UDP

   SCTP provides an acknowledged PL; therefore, a sender does not
   implement the CONFIRMATION_TIMER while in the SEARCH_COMPLETE state.

6.2.2.4.  Handling of PTB Messages by SCTP/UDP

   ICMP validation MUST be performed for PTB messages as specified in
   Appendix C of [RFC 4960].  This requires that the first 8 bytes of the
   SCTP common header are contained in the PTB message, which can be the
   case for ICMPv4 (but note the UDP header also consumes a part of the
   quoted packet header) and is normally the case for ICMPv6.  When the
   validation is completed, the PL_PTB_SIZE calculated from the PTB_SIZE
   in the PTB message SHOULD be used with the DPLPMTUD providing that
   the reported PL_PTB_SIZE is less than the current probe size.

6.2.3.  DPLPMTUD for SCTP/DTLS

   The Datagram Transport Layer Security (DTLS) encapsulation of SCTP is
   specified in [RFC 8261].  This is used for data channels in WebRTC
   implementations.  This specification updates the reference to RFC
   4821 in Section 5 of RFC 8261 to refer to this document (RFC 8899).

6.2.3.1.  Initial Connectivity

   A sender can enter the BASE state as soon as SCTP connectivity has
   been confirmed.

6.2.3.2.  Sending SCTP/DTLS Probe Packets

   Packet probing can be done as specified in Section 6.2.1.2.  The
   maximum payload is reduced by the size of the DTLS headers, which has
   to be considered when filling the PAD chunk.  The size of the probe
   packet includes the DTLS PL headers.  This has to be considered when
   filling the probe packet with the PAD chunk.

6.2.3.3.  Validating the Path with SCTP/DTLS

   Since SCTP provides an acknowledged PL, a sender MUST NOT implement
   the CONFIRMATION_TIMER while in the SEARCH_COMPLETE state.

6.2.3.4.  Handling of PTB Messages by SCTP/DTLS

   [RFC 4960] does not specify a way to validate SCTP/DTLS ICMP message
   payload and neither does this document.  This can prevent processing
   of PTB messages at the PL.

6.3.  DPLPMTUD for QUIC

   QUIC [QUIC] is a UDP-based PL that provides reception feedback.  The
   UDP payload includes a QUIC packet header, a protected payload, and
   any authentication fields.  It supports padding and packet
   coalescence that can be used to construct probe packets.  From the
   perspective of DPLPMTUD, QUIC can function as an acknowledged PL.
   [QUIC] describes the method for using DPLPMTUD with QUIC packets.

7.  IANA Considerations

   This document has no IANA actions.

8.  Security Considerations

   The security considerations for the use of UDP and SCTP are provided
   in the referenced RFCs.

   To avoid excessive load, the interval between individual probe
   packets MUST be at least one RTT, and the interval between rounds of
   probing is determined by the PMTU_RAISE_TIMER.

   A PL sender needs to ensure that the method used to confirm reception
   of probe packets protects from off-path attackers injecting packets
   into the path.  This protection is provided in IETF-defined protocols
   (e.g., TCP, SCTP) using a randomly initialized sequence number.  A
   description of one way to do this when using UDP is provided in
   Section 5.1 of [BCP145]).

   There are cases where ICMP Packet Too Big (PTB) messages are not
   delivered due to policy, configuration, or equipment design (see
   Section 1.1).  This method therefore does not rely upon PTB messages
   being received but is able to utilize these when they are received by
   the sender.  PTB messages could potentially be used to cause a node
   to inappropriately reduce the PLPMTU.  A node supporting DPLPMTUD
   MUST therefore appropriately validate the payload of PTB messages to
   ensure these are received in response to transmitted traffic (i.e., a
   reported error condition that corresponds to a datagram actually sent
   by the path layer, see Section 4.6.1).

   An on-path attacker able to create a PTB message could forge PTB
   messages that include a valid quoted IP packet.  Such an attack could
   be used to drive down the PLPMTU.  An on-path device could similarly
   force a reduction of the PLPMTU by implementing a policy that drops
   packets larger than a configured size.  There are two ways this
   method can be mitigated against such attacks: first, by ensuring that
   a PL sender never reduces the PLPMTU below the base size solely in
   response to receiving a PTB message.  This is achieved by first
   entering the BASE state when such a message is received.  Second, the
   design does not require processing of PTB messages; a PL sender could
   therefore suspend processing of PTB messages (e.g., in a robustness
   mode after detecting that subsequent probes actually confirm that a
   size larger than the PTB_SIZE is supported by a path).

   Parsing the quoted packet inside a PTB message can introduce
   additional per-packet processing at the PL sender.  This processing
   SHOULD be limited to avoid a denial-of-service attack when arbitrary
   headers are included.  Rate-limiting the processing could result in
   PTB messages not being received by a PL; however, the DPLPMTUD method
   is robust to such loss.

   The successful processing of an ICMP message can trigger a probe when
   the reported PTB size is valid, but this does not directly update the
   PLPMTU for the path.  This prevents a message attempting to black
   hole data by indicating a size larger than supported by the path.

   It is possible that the information about a path is not stable.  This
   could be a result of forwarding across more than one path that has a
   different actual PMTU or a single path presents a varying PMTU.  The
   design of a PLPMTUD implementation SHOULD consider how to mitigate
   the effects of varying path information.  One possible mitigation is
   to provide robustness (see Section 5.4) in the method that avoids
   oscillation in the MPS.

   DPLPMTUD methods can introduce padding data to inflate the length of
   the datagram to the total size required for a probe packet.  The
   total size of a probe packet includes all headers and padding added
   to the payload data being sent (e.g., including security-related
   fields such as an AEAD tag and TLS record layer padding).  The value
   of the padding data does not influence the DPLPMTUD search algorithm,
   and therefore needs to be set consistent with the policy of the PL.

   If a PL can make use of cryptographic confidentiality or data-
   integrity mechanisms, then the design ought to avoid adding anything
   (e.g., padding) to DPLPMTUD probe packets that is not also protected
   by those cryptographic mechanisms.

9.  References

9.1.  Normative References

   [BCP145]   Eggert, L., Fairhurst, G., and G. Shepherd, "UDP Usage
              Guidelines", BCP 145, RFC 8085, March 2017,
              <https://www.rfc-editor.org/info/bcp145>.

   [RFC 768]  Postel, J., "User Datagram Protocol", STD 6, RFC 768,
              DOI 10.17487/RFC 768, August 1980,
              <https://www.rfc-editor.org/info/RFC 768>.

   [RFC 791]  Postel, J., "Internet Protocol", STD 5, RFC 791,
              DOI 10.17487/RFC 791, September 1981,
              <https://www.rfc-editor.org/info/RFC 791>.

   [RFC 1191]  Mogul, J. and S. Deering, "Path MTU discovery", RFC 1191,
              DOI 10.17487/RFC 1191, November 1990,
              <https://www.rfc-editor.org/info/RFC 1191>.

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

   [RFC 3828]  Larzon, L-A., Degermark, M., Pink, S., Jonsson, L-E., Ed.,
              and G. Fairhurst, Ed., "The Lightweight User Datagram
              Protocol (UDP-Lite)", RFC 3828, DOI 10.17487/RFC 3828, July
              2004, <https://www.rfc-editor.org/info/RFC 3828>.

   [RFC 4820]  Tuexen, M., Stewart, R., and P. Lei, "Padding Chunk and
              Parameter for the Stream Control Transmission Protocol
              (SCTP)", RFC 4820, DOI 10.17487/RFC 4820, March 2007,
              <https://www.rfc-editor.org/info/RFC 4820>.

   [RFC 4960]  Stewart, R., Ed., "Stream Control Transmission Protocol",
              RFC 4960, DOI 10.17487/RFC 4960, September 2007,
              <https://www.rfc-editor.org/info/RFC 4960>.

   [RFC 6951]  Tuexen, M. and R. Stewart, "UDP Encapsulation of Stream
              Control Transmission Protocol (SCTP) Packets for End-Host
              to End-Host Communication", RFC 6951,
              DOI 10.17487/RFC 6951, May 2013,
              <https://www.rfc-editor.org/info/RFC 6951>.

   [RFC 8174]  Leiba, B., "Ambiguity of Uppercase vs Lowercase in RFC
              2119 Key Words", BCP 14, RFC 8174, DOI 10.17487/RFC 8174,
              May 2017, <https://www.rfc-editor.org/info/RFC 8174>.

   [RFC 8200]  Deering, S. and R. Hinden, "Internet Protocol, Version 6
              (IPv6) Specification", STD 86, RFC 8200,
              DOI 10.17487/RFC 8200, July 2017,
              <https://www.rfc-editor.org/info/RFC 8200>.

   [RFC 8201]  McCann, J., Deering, S., Mogul, J., and R. Hinden, Ed.,
              "Path MTU Discovery for IP version 6", STD 87, RFC 8201,
              DOI 10.17487/RFC 8201, July 2017,
              <https://www.rfc-editor.org/info/RFC 8201>.

   [RFC 8261]  Tuexen, M., Stewart, R., Jesup, R., and S. Loreto,
              "Datagram Transport Layer Security (DTLS) Encapsulation of
              SCTP Packets", RFC 8261, DOI 10.17487/RFC 8261, November
              2017, <https://www.rfc-editor.org/info/RFC 8261>.

9.2.  Informative References

   [QUIC]     Iyengar, J., Ed. and M. Thomson, Ed., "QUIC: A UDP-Based
              Multiplexed and Secure Transport", Work in Progress,
              Internet-Draft, draft-ietf-quic-transport-29, 10 June
              2020, <https://tools.ietf.org/html/draft-ietf-quic-
              transport-29>.

   [RFC 792]  Postel, J., "Internet Control Message Protocol", STD 5,
              RFC 792, DOI 10.17487/RFC 792, September 1981,
              <https://www.rfc-editor.org/info/RFC 792>.

   [RFC 1122]  Braden, R., Ed., "Requirements for Internet Hosts -
              Communication Layers", STD 3, RFC 1122,
              DOI 10.17487/RFC 1122, October 1989,
              <https://www.rfc-editor.org/info/RFC 1122>.

   [RFC 1812]  Baker, F., Ed., "Requirements for IP Version 4 Routers",
              RFC 1812, DOI 10.17487/RFC 1812, June 1995,
              <https://www.rfc-editor.org/info/RFC 1812>.

   [RFC 2923]  Lahey, K., "TCP Problems with Path MTU Discovery",
              RFC 2923, DOI 10.17487/RFC 2923, September 2000,
              <https://www.rfc-editor.org/info/RFC 2923>.

   [RFC 4340]  Kohler, E., Handley, M., and S. Floyd, "Datagram
              Congestion Control Protocol (DCCP)", RFC 4340,
              DOI 10.17487/RFC 4340, March 2006,
              <https://www.rfc-editor.org/info/RFC 4340>.

   [RFC 4443]  Conta, A., Deering, S., and M. Gupta, Ed., "Internet
              Control Message Protocol (ICMPv6) for the Internet
              Protocol Version 6 (IPv6) Specification", STD 89,
              RFC 4443, DOI 10.17487/RFC 4443, March 2006,
              <https://www.rfc-editor.org/info/RFC 4443>.

   [RFC 4821]  Mathis, M. and J. Heffner, "Packetization Layer Path MTU
              Discovery", RFC 4821, DOI 10.17487/RFC 4821, March 2007,
              <https://www.rfc-editor.org/info/RFC 4821>.

   [RFC 4890]  Davies, E. and J. Mohacsi, "Recommendations for Filtering
              ICMPv6 Messages in Firewalls", RFC 4890,
              DOI 10.17487/RFC 4890, May 2007,
              <https://www.rfc-editor.org/info/RFC 4890>.

   [RFC 5508]  Srisuresh, P., Ford, B., Sivakumar, S., and S. Guha, "NAT
              Behavioral Requirements for ICMP", BCP 148, RFC 5508,
              DOI 10.17487/RFC 5508, April 2009,
              <https://www.rfc-editor.org/info/RFC 5508>.

   [RFC 8900]  Bonica, R., Baker, F., Huston, G., Hinden, R., Troan, O.,
              and F. Gont, "IP Fragmentation Considered Fragile",
              RFC 8900, BCP 230, September 2020,
              <https://www.rfc-editor.org/info/RFC 8900>.

   [TUNNELS]  Touch, J. and M. Townsley, "IP Tunnels in the Internet
              Architecture", Work in Progress, Internet-Draft, draft-
              ietf-intarea-tunnels-10, 12 September 2019,
              <https://tools.ietf.org/html/draft-ietf-intarea-tunnels-
              10>.

Acknowledgments

   This work was partially funded by the European Union Horizon 2020
   Research and Innovation Programme under grant agreement No. 644334,
   "A New, Evolutive API and Transport-Layer Architecture for the
   Internet" (NEAT).  The views expressed are solely those of the
   author(s).

   Thanks to all who have commented or contributed, the TSVWG and QUIC
   working groups, and Mathew Calder and Julius Flohr for providing
   early implementations.

Authors' Addresses

   Godred Fairhurst
   University of Aberdeen
   School of Engineering
   Fraser Noble Building
   Aberdeen
   AB24 3UE
   United Kingdom

   Email: gorry@erg.abdn.ac.uk


   Tom Jones
   University of Aberdeen
   School of Engineering
   Fraser Noble Building
   Aberdeen
   AB24 3UE
   United Kingdom

   Email: tom@erg.abdn.ac.uk


   Michael Tüxen
   Münster University of Applied Sciences
   Stegerwaldstrasse 39
   48565 Steinfurt
   Germany

   Email: tuexen@fh-muenster.de


   Irene Rüngeler
   Münster University of Applied Sciences
   Stegerwaldstrasse 39
   48565 Steinfurt
   Germany

   Email: i.ruengeler@fh-muenster.de


   Timo Völker
   Münster University of Applied Sciences
   Stegerwaldstrasse 39
   48565 Steinfurt
   Germany

   Email: timo.voelker@fh-muenster.de



RFC TOTAL SIZE: 92357 bytes
PUBLICATION DATE: Saturday, September 12th, 2020
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