The Subnetwork Encapsulation and Adaptation Layer
(SEAL)Boeing Research & TechnologyP.O. Box 3707SeattleWA98124USAfltemplin@acm.orgI-DInternet-DraftThis document specifies a Subnetwork Encapsulation and Adaptation
Layer (SEAL). SEAL operates over virtual topologies configured over
connected IP network routing regions bounded by encapsulating border
nodes. These virtual topologies are manifested by tunnels that may span
multiple IP and/or sub-IP layer forwarding hops, where they may incur
packet duplication, packet reordering, source address spoofing and
traversal of links with diverse Maximum Transmission Units (MTUs). SEAL
addresses these issues through the encapsulation and messaging
mechanisms specified in this document.As Internet technology and communication has grown and matured, many
techniques have developed that use virtual topologies (manifested by
tunnels of one form or another) over an actual network that supports the
Internet Protocol (IP) .
Those virtual topologies have elements that appear as one network layer
hop, but are actually multiple IP or sub-IP layer hops. These multiple
hops often have quite diverse properties that are often not even visible
to the endpoints of the virtual hop. This introduces failure modes that
are not dealt with well in current approaches.The use of IP encapsulation (also known as "tunneling") has long been
considered as the means for creating such virtual topologies (e.g., see
). Tunnels serve a wide
variety of purposes, including mobility, security, routing control,
traffic engineering, multihoming, etc., and will remain an integral part
of the architecture moving forward. However, the encapsulation headers
often include insufficiently provisioned per-packet identification
values. IP encapsulation also allows an attacker to produce encapsulated
packets with spoofed source addresses even if the source address in the
encapsulating header cannot be spoofed. A denial-of-service vector that
is not possible in non-tunneled subnetworks is therefore presented.Additionally, the insertion of an outer IP header reduces the
effective path MTU visible to the inner network layer. When IPv6 is used
as the encapsulation protocol, original sources expect to be informed of
the MTU limitation through IPv6 Path MTU discovery (PMTUD) . When IPv4 is used, this reduced MTU can be
accommodated through the use of IPv4 fragmentation, but unmitigated
in-the-network fragmentation has been found to be harmful through
operational experience and studies conducted over the course of many
years . Additionally, classical IPv4 PMTUD has known operational issues that are exacerbated by
in-the-network tunnels .The following subsections present further details on the motivation
and approach for addressing these issues.Before discussing the approach, it is necessary to first understand
the problems. In both the Internet and private-use networks today, IP
is ubiquitously deployed as the Layer 3 protocol. The primary
functions of IP are to provide for routing, addressing, and a
fragmentation and reassembly capability used to accommodate links with
diverse MTUs. While it is well known that the IP address space is
rapidly becoming depleted, there is also a growing awareness that
other IP protocol limitations have already or may soon become
problematic.First, the Internet historically provided no means for discerning
whether the source addresses of IP packets are authentic. This
shortcoming is being addressed more and more through the deployment of
site border router ingress filters , however
the use of encapsulation provides a vector for an attacker to
circumvent filtering for the encapsulated packet even if filtering is
correctly applied to the encapsulation header. Secondly, the IP header
does not include a well-behaved identification value unless the source
has included a fragment header for IPv6 or unless the source permits
fragmentation for IPv4. These limitations preclude an efficient means
for routers to detect duplicate packets and packets that have been
re-ordered within the subnetwork. Additionally, recent studies have
shown that the arrival of fragments at high data rates can cause
denial-of-service (DoS) attacks on performance-sensitive networking
gear, prompting some administrators to configure their equipment to
drop fragments unconditionally .For IPv4 encapsulation, when fragmentation is permitted the header
includes a 16-bit Identification field, meaning that at most 2^16
unique packets with the same (source, destination, protocol)-tuple can
be active in the network at the same time .
(When middleboxes such as Network Address Translators (NATs) re-write
the Identification field to random values, the number of unique
packets is even further reduced.) Due to the escalating deployment of
high-speed links, however, these numbers have become too small by
several orders of magnitude for high data rate packet sources such as
tunnel endpoints .Furthermore, there are many well-known limitations pertaining to
IPv4 fragmentation and reassembly – even to the point that it
has been deemed “harmful” in both classic and modern-day
studies (see above). In particular, IPv4 fragmentation raises issues
ranging from minor annoyances (e.g., in-the-network router
fragmentation ) to the potential for major
integrity issues (e.g., mis-association of the fragments of multiple
IP packets during reassembly ).As a result of these perceived limitations, a
fragmentation-avoiding technique for discovering the MTU of the
forward path from a source to a destination node was devised through
the deliberations of the Path MTU Discovery Working Group (MTUDWG)
during the late 1980’s through early 1990’s which resulted
in the publication of . In this negative
feedback-based method, the source node provides explicit instructions
to routers in the path to discard the packet and return an ICMP error
message if an MTU restriction is encountered. However, this approach
has several serious shortcomings that lead to an overall
“brittleness” .In particular, site border routers in the Internet have been known
to discard ICMP error messages coming from the outside world. This is
due in large part to the fact that malicious spoofing of error
messages in the Internet is trivial since there is no way to
authenticate the source of the messages .
Furthermore, when a source node that requires ICMP error message
feedback when a packet is dropped due to an MTU restriction does not
receive the messages, a path MTU-related black hole occurs. This means
that the source will continue to send packets that are too large and
never receive an indication from the network that they are being
discarded. This behavior has been confirmed through documented studies
showing clear evidence of PMTUD failures for both IPv4 and IPv6 in the
Internet today .The issues with both IP fragmentation and this
“classical” PMTUD method are exacerbated further when IP
tunneling is used . For example, an ingress
tunnel endpoint (ITE) may be required to forward encapsulated packets
into the subnetwork on behalf of hundreds, thousands, or even more
original sources. If the ITE allows IP fragmentation on the
encapsulated packets, persistent fragmentation could lead to
undetected data corruption due to Identification field wrapping and/or
reassembly congestion at the ETE. If the ITE instead uses classical IP
PMTUD it must rely on ICMP error messages coming from the subnetwork
that may be suspect, subject to loss due to filtering middleboxes, or
insufficiently provisioned for translation into error messages to be
returned to the original sources.Although recent works have led to the development of a positive
feedback-based end-to-end MTU determination scheme , they do not excuse tunnels from accounting for the
encapsulation overhead they add to packets. Moreover, in current
practice existing tunneling protocols mask the MTU issues by selecting
a "lowest common denominator" MTU that may be much smaller than
necessary for most paths and difficult to change at a later date.
Therefore, a new approach to accommodate tunnels over links with
diverse MTUs is necessary.This document concerns subnetworks manifested through a virtual
topology configured over a connected network routing region and
bounded by encapsulating border nodes. Example connected network
routing regions include Mobile Ad hoc Networks (MANETs), enterprise
networks and the global public Internet itself. Subnetwork border
nodes forward unicast and multicast packets over the virtual topology
across multiple IP and/or sub-IP layer forwarding hops that may
introduce packet duplication and/or traverse links with diverse
Maximum Transmission Units (MTUs).This document introduces a Subnetwork Encapsulation and Adaptation
Layer (SEAL) for tunneling inner network layer protocol packets over
IP subnetworks that connect Ingress and Egress Tunnel Endpoints
(ITEs/ETEs) of border nodes. It provides a modular specification
designed to be tailored to specific associated tunneling protocols. (A
transport-mode of operation is also possible but out of scope for this
document.)SEAL provides a mid-layer encapsulation that accommodates links
with diverse MTUs, and allows routers in the subnetwork to perform
efficient duplicate packet and packet reordering detection. The
encapsulation further ensures message origin authentication, packet
header integrity and anti-replay in environments in which these
functions are necessary.SEAL treats tunnels that traverse the subnetwork as ordinary links
that must support network layer services. Moreover, SEAL provides
dynamic mechanisms (including limited segmentation and reassembly) to
ensure a maximal path MTU over the tunnel. This is in contrast to
static approaches which avoid MTU issues by selecting a lowest common
denominator MTU value that may be overly conservative for the vast
majority of tunnel paths and difficult to change even when larger MTUs
become available.This specification of SEAL is descended from an experimental
independent RFC publication of the same name .
However, this specification introduces a number of important
differences from the earlier publication.First, this specification includes a protocol version field in the
SEAL header whereas does not, and therefore
cannot be updated by future revisions. This specification therefore
obsoletes (i.e., and does not update) .Secondly, forms a 32-bit Identification
value by concatenating the 16-bit IPv4 Identification field with a
16-bit Identification "extension" field in the SEAL header. This means
that can only operate over IPv4 networks
(since IPv6 headers do not include a 16-bit version number) and that
the SEAL Identification value can be corrupted if the Identification
in the outer IPv4 header is rewritten. In contrast, this specification
includes a 32-bit Identification value that is independent of any
identification fields found in the inner or outer IP headers, and is
therefore compatible with any inner and outer IP protocol version
combinations.Additionally, the SEAL segmentation and reassembly procedures
defined in differ significantly from those
found in this specification. In particular, this specification defines
an 8-bit Offset field that allows for smaller segment sizes when SEAL
segmentation is necessary. In contrast,
includes a 3-bit Segment field and performs reassembly through
concatenation of consecutive segments.This version of SEAL also includes an optional Integrity Check
Vector (ICV) that can be used to digitally sign the SEAL header and
the leading portion of the encapsulated inner packet. This allows for
a lightweight integrity check and a loose message origin
authentication capability. The header further includes new control
bits as well as a link identification and encapsulation level field
for additional control capabilities.Finally, this version of SEAL includes a new messaging protocol
known as the SEAL Control Message Protocol (SCMP), whereas performs signalling through the use of
SEAL-encapsulated ICMP messages. The use of SCMP allows SEAL-specific
departures from ICMP, as well as a control messaging capability that
extends to other specifications, including Virtual Enterprise
Traversal (VET) .The following terms are defined within the scope of this
document:a virtual topology configured over
a connected network routing region and bounded by encapsulating
border nodes.used to generically refer to either
Internet Protocol (IP) version, i.e., IPv4 or IPv6.a portal over
which an encapsulating border node (host or router) sends
encapsulated packets into the subnetwork.a portal over
which an encapsulating border node (host or router) receives
encapsulated packets from the subnetwork.a subnetwork path from an ITE to an
ETE beginning with an underlying link of the ITE as the first hop.
Note that, if the ITE's interface connection to the underlying link
assigns multiple IP addresses, each address represents a separate
SEAL path.an unencapsulated network layer
protocol packet (e.g., IPv4 , OSI/CLNP , IPv6 , etc.) before any
outer encapsulations are added. Internet protocol numbers that
identify inner packets are found in the IANA Internet Protocol
registry . SEAL protocol packets that incur
an additional layer of SEAL encapsulation are also considered inner
packets.a packet resulting from
adding an outer IP header (and possibly other outer headers) to a
SEAL-encapsulated inner packet.the leading portion of an
invoking data packet encapsulated in the body of an error control
message (e.g., an ICMPv4 error message, an
ICMPv6 error message, etc.).a control plane
message indicating an MTU restriction (e.g., an ICMPv6 "Packet Too
Big" message , an ICMPv4 "Fragmentation
Needed" message , etc.).a bit that indicates
whether the packet may be fragmented by the network. The DF bit is
explicitly included in the IPv4 header and
may be set to '0' to allow fragmentation or '1' to disallow further
in-network fragmentation. The bit is absent from the IPv6 header
, but implicitly set to '1' because
fragmentation can occur only at IPv6 sources.The following abbreviations correspond to terms used within this
document and/or elsewhere in common Internetworking nomenclature:HLEN - the length of the SEAL header plus outer
headersICV - Integrity Check VectorMAC - Message Authentication CodeMTU - Maximum Transmission UnitSCMP - the SEAL Control Message ProtocolSDU - SCMP Destination Unreachable messageSPP - SCMP Parameter Problem messageSPTB - SCMP Packet Too Big messageSEAL - Subnetwork Encapsulation and Adaptation LayerTE - Tunnel Endpoint (i.e., either ingress or egress)
VET - Virtual Enterprise TraversalThe key words "MUST", "MUST NOT", "REQUIRED", "SHALL", "SHALL NOT",
"SHOULD", "SHOULD NOT", "RECOMMENDED", "MAY", and "OPTIONAL" in this
document are to be interpreted as described in .
When used in lower case (e.g., must, must not, etc.), these words MUST
NOT be interpreted as described in , but are
rather interpreted as they would be in common English.SEAL was originally motivated by the specific case of subnetwork
abstraction for Mobile Ad hoc Networks (MANETs), however the domain of
applicability also extends to subnetwork abstractions over enterprise
networks, mobile networks, ISP networks, SO/HO networks, the global
public Internet itself, and any other connected network routing
region.SEAL provides a network sublayer for encapsulation of an inner
network layer packet within outer encapsulating headers. SEAL can also
be used as a sublayer within a transport layer protocol data payload,
where transport layer encapsulation is typically used for Network
Address Translator (NAT) traversal as well as operation over subnetworks
that give preferential treatment to certain "core" Internet protocols,
e.g., TCP, UDP, etc. (However, note that TCP encapsulation may not be
appropriate for all use cases; particularly those that require low delay
and/or delay variance.) The SEAL header is processed in a similar manner
as for IPv6 extension headers, i.e., it is not part of the outer IP
header but rather allows for the creation of an arbitrarily extensible
chain of headers in the same way that IPv6 does.To accommodate MTU diversity, the Ingress Tunnel Endpoint (ITE) may
need to perform limited segmentation which the Egress Tunnel Endpoint
(ETE) reassembles. The ETE further acts as a passive observer that
informs the ITE of any packet size limitations. This allows the ITE to
return appropriate PMTUD feedback even if the network path between the
ITE and ETE filters ICMP messages.SEAL further provides mechanisms to ensure message origin
authentication, packet header integrity, and anti-replay. The SEAL
framework is therefore similar to the IP Security (IPsec) Authentication
Header (AH) , however it
provides only minimal hop-by-hop authenticating services while leaving
full data integrity, authentication and confidentiality services as an
end-to-end consideration.In many aspects, SEAL also very closely resembles the Generic Routing
Encapsulation (GRE) framework . SEAL can
therefore be applied in the same use cases that are traditionally
addressed by GRE, but goes beyond GRE to also provide additional
capabilities (e.,g., path MTU accommodation, message origin
authentication, etc.) as described in this document. The SEAL header is
also exactly analogous to the IPv6 Fragment Header, and in fact shares
the same format. SEAL can therefore re-use most existing code that
implements IPv6 fragmentation and reassembly.Finally, SEAL is typically used as an encapsulation sublayer in
conjunction with existing tunnel types such as IPsec, GRE, IP-in-IPv6
, IP-in-IPv4 , etc. When used with existing tunnel types that
insert mid-layer headers between the inner and outer IP headers (e.g.,
IPsec, GRE, etc.), the SEAL header is inserted between the mid-layer
headers and outer IP header.The following sections specify the operation of SEAL:SEAL is an encapsulation sublayer used within point-to-point,
point-to-multipoint, and non-broadcast, multiple access (NBMA)
tunnels. Each SEAL path is configured over one or more underlying
interfaces attached to subnetwork links. The SEAL tunnel connects an
ITE to one or more ETE "neighbors" via encapsulation across an
underlying subnetwork, where the tunnel neighbor relationship may be
bidirectional, partially unidirectional or fully unidirectional.A bidirectional tunnel neighbor relationship is one over which both
TEs can exchange both data and control messages. A partially
unidirectional tunnel neighbor relationship allows the near end ITE to
send data packets forward to the far end ETE, while the far end only
returns control messages when necessary. Finally, a fully
unidirectional mode of operation is one in which the near end ITE can
receive neither data nor control messages from the far end ETE.Implications of the SEAL bidirectional and unidirectional models
are the same as discussed in .SEAL-enabled ITEs encapsulate each inner packet in a SEAL header,
any outer header encapsulations and in some instances a SEAL trailer
as shown in :The ITE inserts the SEAL header according to the specific tunneling
protocol. For simple encapsulation of an inner network layer packet
within an outer IP header, the ITE inserts the SEAL header following
the outer IP header and before the inner packet as: IP/SEAL/{inner
packet}.For encapsulations over transports such as UDP, the ITE inserts the
SEAL header following the outer transport layer header and before the
inner packet, e.g., as IP/UDP/SEAL/{inner packet}. In that case, the
UDP header is seen as an "other outer header" as depicted in and the outer IP and transport layer headers are
together seen as the outer encapsulation headers. (Note that outer
transport layer headers such as UDP must sometimes be included to
ensure that SEAL packets will traverse the path to the ETE without
loss due filtering middleboxes. The ETE MUST accept both IP/SEAL and
IP/UDP/SEAL as equivalent packets so that the ITE can discontinue
outer transport layer encapsulation if the path supports raw IP/SEAL
encapsulation.)For SEAL encapsulations that involve other tunnel types (e.g., GRE,
IPsec, etc.) the ITE inserts the SEAL header as a leading extension to
the other tunnel headers, i.e., the SEAL encapsulation appears as part
of the same tunnel and not a separate tunnel. For example, for GRE the
ITE iserts the SEAL header as IP/SEAL/GRE/{inner packet}, and for
IPsec the ITE inserts the SEAL header as IP/SEAL/IPsec-header/{inner
packet}/IPsec-trailer. In such cases, SEAL considers the length of the
inner packet only (i.e., and not the other tunnel headers and
trailers) when performing its packet size calculations.SEAL supports both "nested" tunneling and "re-encapsulating"
tunneling. Nested tunneling occurs when a first tunnel is encapsulated
within a second tunnel, which may then further be encapsulated within
additional tunnels. Nested tunneling can be useful, and stands in
contrast to "recursive" tunneling which is an anomalous condition
incurred due to misconfiguration or a routing loop. Considerations for
nested tunneling and avoiding recursive tunneling are discussed in
Section 4 of as well as in Section 9 of this
document.Re-encapsulating tunneling occurs when a packet arrives at a first
ETE, which then acts as an ITE to re-encapsulate and forward the
packet to a second ETE connected to the same subnetwork. In that case
each ITE/ETE transition represents a segment of a bridged path between
the ITE nearest the source and the ETE nearest the destination.
Considerations for re-encapsulating tunneling are discussed in. Combinations of nested and
re-encapsulating tunneling are also naturally supported by SEAL.The SEAL ITE considers each underlying interface as the ingress
attachment point to a separate SEAL path to the ETE. The ITE therefore
may experience different path MTUs on different SEAL paths.Finally, the SEAL ITE ensures that the inner network layer protocol
will see a minimum MTU of 1500 bytes over each SEAL path regardless of
the outer network layer protocol version, i.e., even if a small amount
of segmentation and reassembly are necessary. This is to avoid path
MTU "black holes" for the minimum MTU configured by the vast majority
of links in the Internet. Note that in some scenarios, however,
reassembly may place a heavy burden on the ETE. In that case, the ITE
can avoid invoking segmentation and instead report an MTU smaller than
1500 bytes to the original source.SEAL encapsulates each inner packet within a SEAL header as shown
in :The fields of the SEAL header are formatted as follows:an 8-bit field that encodes the next
header Internet Protocol number the same as for the IPv4 protocol
and IPv6 next header fields.a 2-bit version field. This
document specifies Version 0 of the SEAL protocol, i.e., the VER
field encodes the value 0.a 3-bit link identification value,
set to a unique value by the ITE for each SEAL path over which it
will send encapsulated packets to the ETE (up to 8 SEAL paths per
ETE are therefore supported). Note that, if the ITE's interface
connection to the underlying link assigns multiple IP addresses,
each address represents a separate SEAL path that must be assigned
a separate link ID.the "Integrity Check Vector (ICV)
included" bit.the "Redirects Permitted" bit when
used by VET (see:);
reserved for future use in other contexts.a 1-bit Reserved field. Initialized
to zero for transmission; ignored on reception.a 13-bit Offset field. The
offset, in 8-octet units, of the data following this header.the "Control/Data" bit. Set to 1 by
the ITE in SEAL Control Message Protocol (SCMP) control messages,
and set to 0 in ordinary data packets.The "Probe" bit when C=0; set to 1 by
the ITE in SEAL probe data packets for which it wishes to receive
an explicit acknowledgement from the ETE. The "Pass" bit when C=1;
set to 1 by the ETE in SCMP messages it relays to the ITE on
behalf of another SEAL path.the "More Segments" bit. Set to 1 in a
non-final segment and set to 0 in the final segment of the SEAL
packet.a 32-bit per-packet
identification field. Set to a randomly-initialized 32-bit value
that is monotonically-incremented for each SEAL packet transmitted
to this ETE.When an IIntegrity Check Vector (ICV) is included, it is
added as a trailing field at the end of the SEAL packet. The ICV is
formatted as shown in :As shown in the figure, the ICV begins with a 1-octet control field
with a 1-bit (F)lag, a 2-bit Key identifier and a 5-bit Algorithm
identifier. The control octet is followed by a variable-length Message
Authentication Code (MAC). The ITE maintains a per ETE algorithm and
secret key to calculate the MAC in each packet it will send to this
ETE. (By default, the ITE sets the F bit and Algorithm fields to 0 to
indicate use of the HMAC-SHA-1 algorithm with a 160 bit shared secret
key to calculate an 80 bit MAC per over the
leading 128 bytes of the packet. Other values for F and Algorithm are
out of scope.)The tunnel must present a stable MTU value to the inner network
layer as the size for admission of inner packets into the tunnel.
Since tunnels may support a large set of SEAL paths that accept
widely varying maximum packet sizes, however, a number of factors
should be taken into consideration when selecting a tunnel MTU.Due to the ubiquitous deployment of standard Ethernet and similar
networking gear, the nominal Internet cell size has become 1500
bytes; this is the de facto size that end systems have come to
expect will either be delivered by the network without loss due to
an MTU restriction on the path or a suitable ICMP Packet Too Big
(PTB) message returned. When large packets sent by end systems incur
additional encapsulation at an ITE, however, they may be dropped
silently within the tunnel since the network may not always deliver
the necessary PTBs . The ITE SHOULD
therefore set a tunnel MTU of at least 1500 bytes and provide
accommodations to ensure that packets up to that size are
successfully conveyed to the ETE.The inner network layer protocol consults the tunnel MTU when
admitting a packet into the tunnel. For non-SEAL inner IPv4 packets
with the IPv4 Don't Fragment (DF) bit cleared (i.e, DF==0), if the
packet is larger than the tunnel MTU the inner IPv4 layer uses IPv4
fragmentation to break the packet into fragments no larger than the
MTU. The ITE then admits each fragment into the tunel as an
independent packet.For all other inner packets, the inner network layer admits the
packet if it is no larger than the tunnel MTU; otherwise, it drops
the packet and sends a PTB error message to the source with the MTU
value set to the MTU. The message contains as much of the invoking
packet as possible without the entire message exceeding the network
layer minimum MTU size.The ITE can alternatively set an indefinite tunnel MTU such that
all inner packets are admitted into the tunnel regardless of their
size (theoretical maximums are 64KB for IPv4 and 4GB for IPv6 ). For ITEs that host applications that use the
tunnel directly, this option must be carefully coordinated with
protocol stack upper layers since some upper layer protocols (e.g.,
TCP) derive their packet sizing parameters from the MTU of the
outgoing interface and as such may select too large an initial size.
This is not a problem for upper layers that use conservative initial
maximum segment size estimates and/or when the tunnel can reduce the
upper layer's maximum segment size, e.g., by reducing the size
advertised in the MSS option of outgoing TCP messages (sometimes
known as "MSS clamping").In light of the above considerations, the ITE SHOULD configure an
indefinite MTU on *router* tunnels so that SEAL performs all
subnetwork adaptation from within the tunnel as specified in the
following sections. The ITE MAY instead set a smaller MTU on *host*
tunnels; in that case, the RECOMMENDED MTU is the maximum of 1500
bytes and the smallest MTU among all of the underlying links minus
the size of the encapsulation headers.The ITE maintains a number of soft state variables for each ETE
and for each SEAL path.The ITE maintains a per ETE window of Identification values for
the packets it has recently sent to this ETE as welll as a per ETE
window of Identification values for the packets it has recently
received from this ETE. The ITE then includes an Identification in
each packet it sends to this ETE.When message origin authentication and integrity checking is
required, the ITE sets a variable "USE_ICV" to TRUE, and includes an
ICV in each packet it sends to this ETE; otherwise, it sets USE_ICV
to FALSE.For each SEAL path, the ITE must also account for encapsulation
header lengths. The ITE therefore maintains the per SEAL path
constant values "SHLEN" set to the length of the SEAL header and
trailer, "THLEN" set to the length of the outer encapsulating
transport layer headers (or 0 if outer transport layer encapsulation
is not used), "IHLEN" set to the length of the outer IP layer
header, and "HLEN" set to (SHLEN+THLEN+IHLEN). (The ITE must include
the length of the uncompressed headers even if header compression is
enabled when calculating these lengths.) When SEAL is used in
conjunction with another tunnel type such as GRE or IPsec, the
length of the headers associated with those tunnels is also included
in the HLEN calculation for the first segment only and the length of
the associated trailers is included in the HLEN calculation for the
final segment only.The ITE maintains a per SEAL path variable "MAXMTU" initialized
to the maximum of (1500+HLEN) bytes and the MTU of the underlying
link. The ITE further sets a variable 'MINMTU' to the minimum MTU
for the SEAL path over which encapsulated packets will travel. For
IPv6 paths, the ITE sets MINMTU=1280 per .
For IPv4 paths, the ITE sets MINMTU=576 based on practical
interpretation of even though the
theoretical MINMTU for IPv4 is only 68 bytes .The ITE can also set MINMTU to a larger value if there is reason
to believe that the minimum path MTU is larger, or to a smaller
value if there is reason to believe the MTU is smaller, e.g., if
there may be additional encapsulations on the path. If this value
proves too large, the ITE will receive PTB message feedback either
from the ETE or from a router on the path and will be able to reduce
its MINMTU to a smaller value. (Note that since IPv4 links with MTUs
smaller than 1280 are presumably peformance-constrained, the ITE can
instead initialize MINMTU to 1280 the same as for IPv6. If this
value proves too large, standard IPv4 fragmentation and reassembly
will provide short term accommodation for the sizing constraints
while the ITE readjusts its MINMTU estimate.)The ITE may instead maintain the packet sizing variables and
constants as per ETE (rather than per SEAL path) values. In that
case, the values reflect the smallest MTU size across all of the
SEAL paths associated with this ETE.The SEAL layer is logically positioned between the inner and
outer network protocol layers, where the inner layer is seen as the
(true) network layer and the outer layer is seen as the (virtual)
data link layer. Each packet to be processed by the SEAL layer is
either admitted into the tunnel by the inner network layer protocol
as described in Section 5.4.1 or is undergoing re-encapsulation from
within the tunnel. The SEAL layer sees the former class of packets
as inner packets that include inner network and transport layer
headers, and sees the latter class of packets as transitional SEAL
packets that include the outer and SEAL layer headers that were
inserted by the previous hop SEAL ITE. For these transitional
packets, the SEAL layer re-encapsulates the packet with new outer
and SEAL layer headers when it forwards the packet to the next hop
SEAL ITE.We now discuss the SEAL layer pre-processing actions for these
two classes of packets.For each for non-SEAL IPv4 inner packet with DF==0 in the IP
header and IPv6 inner packet with a fragment header and with
(MF=0; Offset=0), if the packet is larger than (MINMTU-HLEN) the
ITE uses IP fragmentation to fragment the packet into N pieces,
where N is minimized. (For IPv6 as the inner protocol, the first
fragment MUST be at least as large as the IPv6 minimum of 1280
bytes so that the entire IPv6 header chain is likely to fit within
the first segment.) The ITE then submits each fragment for SEAL
encapsulation as specified in Section 5.4.4.For all other inner packets, if the packet is no larger than
(MAXMTU-HLEN) for the corresponding SEAL path the ITE submits it
for SEAL encapsulation as specified in Section 5.4.4. Otherwise,
the ITE drops the packet and sends an ordinary PTB message
appropriate to the inner protocol version (subject to rate
limiting) with the MTU field set to (MAXMTU-HLEN). (For IPv4 SEAL
packets with DF==0, the ITE SHOULD set DF=1 and re-calculate the
IPv4 header checksum before generating the PTB message in order to
avoid bogon filters.) After sending the PTB message, the ITE
discards the inner packet.For each transitional packet that is to be processed by the
SEAL layer from within the tunnel, if the packet is larger than
MAXMTU bytes for the next hop SEAL path the ITE sends an SCMP
Packet Too Big (SPTB) message to the previous hop subject to rate
limiting with the MTU field set to MAXMTU and with (C=1; P=1) in
the SEAL header (see: Section 5.6.1.1). After sending the SPTB
message, the ITE discards the packet. Otherwise, the ITE sets
aside the encapsulating SEAL and outer headers and submits the
inner packet for SEAL re-encapsulation as specified in Section
5.4.4. (Note that in the calculation for MAXMTU, HLEN for the next
hop SEAL path may be different than HLEN for the previous hop. In
that case, MAXMTU must reflect the smaller of the two HLEN
values.)For each inner packet/fragment submitted for SEAL encapsulation,
the ITE next encapsulates the packet in a SEAL header formatted as
specified in Section 5.3. The SEAL header includes an Identification
field when USE_ID is TRUE, followed by an ICV field when USE_ICV is
TRUE.The ITE next sets (C=0; P=0), sets LINK to the value assigned to
the underlying SEAL path, and sets the Next Header field to the
protocol number corresponding to the address family of the
encapsulated inner packet. For example, the ITE sets the Next Header
field to the value '4' for encapsulated IPv4 packets , '41' for encapsulated IPv6 packets , '47' for GRE , '80' for encapsulated OSI/CLNP packets , etc.Next, if the inner packet is no larger than (MINMTU-HLEN) or
larger than 1500, the ITE sets (M=0; Fragment Offset=0). Otherwise,
the ITE breaks the inner packet into N non-overlapping segments,
where N is minimized. (For IPv6 as the inner protocol, the first
segment MUST be at least as large as the IPv6 minimum of 1280 bytes
so that the entire IPv6 header chain is likely to fit within the
first segment.) The ITE then appends a clone of the SEAL header from
the first segment onto the head of each additional segment. The ITE
then sets (M=1; Fragment Offset=0) in the first segment, sets
(M=0/1; Fragment Offset=O(1)) in the second segment, sets (M=0/1;
Fragment Offset=O(2)) in the third segment (if needed), etc., then
finally sets (M=0; Fragment Offset=O(n)) in the final segment (where
O(i) is the number of 256 byte blocks that preceded this
segment).The ITE then writes a monotonically-incrementing integer value
for this ETE in the Identification field beginning with a
randomly-initialized value in the first packet transmitted. (For
SEAL packets that have been split into multiple pieces, the ITE
writes the same Identification value in each piece.) The
monotonically-incrementing requirement is to satisfy ETEs that use
this value for anti-replay purposes. The value is incremented modulo
2^32, i.e., it wraps back to 0 when the previous value was (2^32 -
1).When USE_ICV is FALSE, the ITE next sets V=0. Otherwise, the ITE
sets V=1, includes a trailing ICV and calculates the MAC using
HMAC-SHA-1 with a 160 bit secret key and 80 bit MAC field. Beginning
with the SEAL header, the ITE calculates the MAC over the leading
128 bytes of the packet (or up to the end of the packet if there are
fewer than 128 bytes) and places the result in the MAC field. (For
SEAL packets that have been split into multiple pieces, each piece
calculates its own MAC.) The ITE then writes the value 0 in the F
flag and 0x00 in the Algorithm field of the ICV control octet (other
values for these fields, and other MAC calculation disciplines, are
outside the scope of this document and may be specified in future
documents.)If the packet is undergoing SEAL re-encapsulation, the ITE then
copies the R value from the SEAL header of the packet to be
re-encapsulated. Otherwise, it sets R=0 unless otherwise specified
in other documents that employ SEAL. The ITE then adds the outer
encapsulating headers as specified in Section 5.4.5.Following SEAL encapsulation, the ITE next encapsulates each
segment in the requisite outer transport (when necessary) and IP
layer headers. When a transport layer header such as UDP or TCP is
included, the ITE writes the port number for SEAL in the transport
destination service port field.When UDP encapsulation is used, the ITE sets the UDP checksum
field to zero for IPv4 packets and also sets the UDP checksum field
to zero for IPv6 packets even though IPv6 generally requires UDP
checksums. Further considerations for setting the UDP checksum field
for IPv6 packets are discussed in .The ITE then sets the outer IP layer headers the same as
specified for ordinary IP encapsulation (e.g., ,,, etc.)
except that for ordinary SEAL packets the ITE copies the "TTL/Hop
Limit", "Type of Service/Traffic Class" and "Congestion Experienced"
values in the inner network layer header into the corresponding
fields in the outer IP header. For transitional SEAL packets
undergoing re-encapsulation, the ITE instead copies the "TTL/Hop
Limit", "Type of Service/Traffic Class" and "Congestion Experienced"
values in the original outer IP header of the transitional packet
into the corresponding fields in the new outer IP header of the
packet to be forwarded (i.e., the values are transferred between
outer headers and *not* copied from the inner network layer
header).The ITE also sets the IP protocol number to the appropriate value
for the first protocol layer within the encapsulation (e.g., UDP,
TCP, SEAL, etc.). When IPv6 is used as the outer IP protocol, the
ITE then sets the flow label value in the outer IPv6 header the same
as described in . When IPv4 is used as the
outer IP protocol, the ITE sets DF=0 in the IPv4 header to allow the
packet to be fragmented if it encounters a restricting link (for
IPv6 SEAL paths, the DF bit is absent but implicitly set to 1).The ITE finally sends each outer packet via the underlying link
corresponding to LINK.All SEAL data packets sent by the ITE are considered implicit
probes that detect MTU limitations on the SEAL path, while explicit
probe packets can be constructed to probe the path MTU and/or verify
ETE reachability. These probes will elicit an SCMP message from the
ETE if it needs to send an acknowledgement and/or report an error
condition. The probe packets may also be dropped by either the ETE
or a router on the path, which may or may not result in an ICMP
message being returned to the ITE.To generate an explicit probe packet, the ITE creates a duplicate
of an actual data packet and uses the duplicate as a probe.
(Alternatively, the ITE can create a packet buffer beginning with
the same outer headers, SEAL header and inner network layer headers
that would appear in an ordinary data packet, then pad the packet
with random data.) The ITE then sets (C=0; P=1) in the SEAL header
of the probe packet, and also sets DF=1 in the outer IP header when
IPv4 is used.The ITE sends periodic explicit probes to determine whether SEAL
segmentation is still necessary (see Section 5.4.4). In particular,
if a probe packet of 1500 bytes (i.e., a packet that becomes
(1500+HLEN) bytes after encapsulation) succeeds without incurring
fragmentation the ITE is assured that the path MTU is large enough
so that the segmentation/reassembly process can be suspended. This
probing discipline can therefore be considered as Packetization
Layer Path MTU Discovery (PLPMTUD) applied
to tunnels, which operates independently of any application of
PLPMTUD between end systems. Note that the explicit probe size of
1500 bytes is chosen since probe packets smaller than this size may
be fragmented by a nested ITE further down the path. For example, a
successful probe for a packet size of 1400 bytes does not guarantee
that fragmentation is not occurring at another ITE.The ITE can also send probes to detect whether an outer transport
layer header is no longer necessary to reach this ETE. For example,
if the ITE sends its initial packets as IP/UDP/SEAL/*, it can send
probes constructed as IP/SEAL/* to determine whether the ETE is
reachable without the added layer of encapsulation. If so, the ITE
should also re-probe the path MTU since switching to a new
encapsulation type may result in a path change.While probing, the ITE processes ICMP messages as specified in
Section 5.4.7 and processes SCMP messages as specified in Section
5.6.2.When the ITE sends SEAL packets, it may receive ICMP error
messages from a
router on the path to the ETE. Each ICMP message includes an outer
IP header, followed by an ICMP header, followed by a portion of the
SEAL data packet that generated the error (also known as the
"packet-in-error"). Note that the ITE may receive an ICMP message
from another ITE that is at the head end of a nested level of
encapsulation. The ITE has no security associations with this nested
ITE, hence it should consider the message the same as if it
originated from an ordinary router on the path to the ETE.The ITE should process ICMPv4 Protocol Unreachable messages and
ICMPv6 Parameter Problem messages with Code "Unrecognized Next
Header type encountered" as a hint that the ETE does not implement
SEAL. The ITE can optionally ignore other ICMP messages that do not
include sufficient information in the packet-in-error, or process
them as a hint that the SEAL path to the ETE may be failing. The ITE
then discards these types of messages.For other ICMP messages, the ITE first examines the SEAL data
packet within the packet-in-error field. If the IP source and/or
destination addresses are invalid, or if the value in the SEAL
header Identification field (if present) is not within the window of
packets the ITE has recently sent to this ETE, or if the MAC value
in the ICV field (if present) is incorrect, the ITE discards the
message.Next, if the received ICMP message is a PTB the ITE sets the
temporary variable "PMTU" for this SEAL path to the MTU value in the
PTB message. If the outer IP length value in the packet-in-error is
no larger than (1500+HLEN) bytes the ITE sets MAXMTU=(1500+HLEN) and
discards the message. If the outer IP length value in the
packet-in-error is larger than (1500+HLEN) bytes and PMTU is no
smaller than MINMTU the ITE sets MAXMTU to the maximum of
(1500+HLEN) and PMTU; otherwise the ITE consults a plateau table
(e.g., as described in ) to determine a new
value for MAXMTU. For example, if the ITE receives a PTB message
with small PMTU and packet-in-error length 8KB, it can set
MAXMTU=4KB. If the ITE subsequently receives a PTB message with
small PMTU and length 4KB, it can set MAXMTU=2KB, etc., to a minimum
value of MAXMTU=(1500+HLEN). Next, if the packet-in-error was an
explicit probe (i.e., one with P=1 in the SEAL header), the ITE
discards the message. Finally, if the ITE is using a MINMTU value
larger than 1280 for IPv6 or 576 for IPv4, it may need to reduce
MINMTU if the PMTU value is small.If the ICMP message was not discarded, the ITE transcribes it
into a message appropriate for the SEAL data packet within the
packet-in-error. If the previous hop toward the inner source address
within the SEAL data packet is reached via the same SEAL tunnel, the
ITE transcribes the message into an SCMP message the same as
described for ETE generation of SCMP messages in Section 5.6.1,
i.e., it copies the SEAL data packet within the packet-in-error into
the packet-in-error field of the new message. (In this process, the
ETE also sets (C=1; P=1) in the SEAL header of the SCMP message.)
Otherwise, the ITE seeks beyond the SEAL header within the
packet-in-error and transcribes the inner packet into a message
appropriate for the inner protocol version (e.g., ICMPv4 for IPv4,
ICMPv6 for IPv6, etc.).The ITE finally forwards the transcribed message to the previous
hop toward the inner source address.The ITE can perform a qualification exchange to ensure that the
subnetwork correctly delivers fragments to the ETE. This procedure
can be used, e.g., to determine whether there are middleboxes on the
path that violate the , Section 5.2.6
requirement that: "A router MUST NOT reassemble any datagram before
forwarding it". Examples of middleboxes that may perform reassembly
include stateful NATs and firewalls. Such devices could still allow
for stateless MTU determination if they gather the fragments of a
fragmented SEAL data packet for packet analysis purposes but then
forward the fragments on to the final destination rather than
forwarding the reassembled packet. (This process is often referred
to as "Virtual Fragmentation Reassembly" (VFR)).The ITE should use knowledge of its topological arrangement as an
aid in determining when middlebox reassembly testing is necessary.
For example, if the ITE is aware that the ETE is located somewhere
in the public Internet, middlebox reassembly testing should not be
necessary. If the ITE is aware that the ETE is located behind a NAT
or a firewall, however, then reassembly testing can be used to
detect middleboxes that do not conform to specifications.The ITE can perform a middlebox reassembly test by sending
explicit probe packets. The ITE should only send probe packets that
are smaller than (576-HLEN) before encapsulation since the least an
ordinary node can be expected to reassemble is 576 bytes. To
generate a probe, the ITE either creates a clone of an ordinary data
packet or creates a packet buffer beginning with the same outer
headers, SEAL header and inner network layer header that would
appear in an ordinary data packet. The ITE then pads the probe
packet with random data to a length that is at least 128 bytes but
smaller than (576-HLEN) bytes.The ITE then sets (C=0; P=1) in the SEAL header of the probe
packet and sets the Next Header field to the inner network layer
protocol type. Next, the ITE sets LINK to the appropriate value for
this SEAL path, sets the Identification field, then finally
calculates the ICV and sets V=1 (when USE_ICV is TRUE).The ITE then encapsulates the probe packet in the appropriate
outer headers, splits it into two outer IP fragments, then sends
both fragments over the same SEAL path.The ITE should send a series of probe packets (e.g., 3-5 probes
with 1sec intervals between tests) instead of a single isolated
probe in case of packet loss. If the ETE returns an SCMP PTB message
with the original first fragment in the packet-in-error, then the
SEAL path correctly supports fragmentation; otherwise, the ITE
enables stateful MTU determination for this SEAL path as specified
in Section 5.4.9.SEAL supports a stateless MTU determination capability, however
the ITE may in some instances wish to impose a stateful MTU limit on
a particular SEAL path. For example, when the ETE is situated behind
a middlebox that performs reassembly in violation of the specs (see:
Section 5.4.8) it is imperative that fragmentation be avoided. In
other instances (e.g., when the SEAL path includes
performance-constrained links), the ITE may deem it necessary to
cache a conservative static MTU in order to avoid sending large
packets that would only be dropped due to an MTU restriction
somewhere on the path.To determine a static MTU value, the ITE can send a series of
probe packets of various sizes to the ETE with (C=0; P=1) in the
SEAL header and DF=1 in the outer IP header. The ITE then caches the
size 'S' of the largest packet for which it receives a probe reply
from the ETE by setting MAXMTU=MAX((S, (1500+HLEN)) for this SEAL
path.For example, the ITE could send probe packets of 8KB, followed by
4KB, followed by 2KB, etc. While probing, the ITE processes any ICMP
PTB message it receives as a potential indication of probe failure
then discards the message.When stateful MTU determination is used, the ITE SHOULD
periodically reset MAXMTU and/or re-probe the path to determine
whether MAXMTU has increased. If the path still has a too-small MTU,
the ITE will receive a PTB message that reports a smaller size.For IPv6, the ETE MUST configure a minimum reassembly buffer size
of (1500 + HLEN) bytes for the reassembly of outer IPv6 packets,
i.e., even though the true minimum reassembly size for IPv6 is only
1500 bytes . For IPv4, the ETE also MUST
configure a minimum reassembly buffer size of (1500 + HLEN) bytes
for the reassembly of outer IPv4 packets, i.e., even though the true
minimum reassembly size for IPv4 is only 576 bytes .In addition to this outer reassembly buffer requirement, the ETE
further MUST configure a minimum SEAL reassembly buffer size of
(1500 + HLEN) bytes for the reassembly of segmented SEAL packets
(see: Section 5.5.4).Note that the value "HLEN" may be variable and initially unknown
to the ETE, and would typically range from a few bytes to a few tens
of bytes or even more. It is therefore RECOMMENDED that the ETE
configure slightly larger minimum IP/SEAL reassembly buffer sizes of
2048 bytes (2KB).When message origin authentication and integrity checking is
required, the ETE maintains a per-ITE MAC calculation algorithm and
a symmetric secret key to verify the MAC. The ETE also maintains a
window of Identification values for the packets it has recently
received from this ITE as well as a window of Identification values
for the packets it has recently sent to this ITE.When the tunnel neighbor relationship is bidirectional, the ETE
further maintains a per SEAL path mapping of outer IP and transport
layer addresses to the LINK value that appears in packets received
from the ITE.The ETE reassembles fragmented IP packets that are explicitly
addressed to itself. For IP fragments that are received via a SEAL
tunnel, the ETE SHOULD maintain conservative reassembly cache high-
and low-water marks. When the size of the reassembly cache exceeds
this high-water mark, the ETE SHOULD actively discard stale
incomplete reassemblies (e.g., using an Active Queue Management
(AQM) strategy) until the size falls below the low-water mark. The
ETE SHOULD also actively discard any pending reassemblies that
clearly have no opportunity for completion, e.g., when a
considerable number of new fragments have arrived before a fragment
that completes a pending reassembly arrives.The ETE processes non-SEAL IP packets as specified in the
normative references, i.e., it performs any necessary IP reassembly
then discards the packet if it is larger than the reassembly buffer
size or delivers the (fully-reassembled) packet to the appropriate
upper layer protocol module.For SEAL packets, the ETE performs any necessary IP reassembly
then submits the packet for SEAL decapsulation as specified in
Section 5.5.4. (Note that if the packet is larger than the
reassembly buffer size, the ETE still examines the leading portion
of the (partially) reassembled packet during decapsulation.)For each SEAL packet accepted for decapsulation, the ETE first
examines the Identification field. If the Identification is not
within the window of acceptable values for this ITE, the ETE
silently discards the packet.Next, if V==1 the ETE SHOULD verify the MAC value and silently
discard the packet if the value is incorrect. (Note that this means
that the ETE would need to receive all IP fragments if the packet
was fragmented at the outer IP layer, since the MAC is included as a
trailing field.)Next, if the packet arrived as multiple IP fragments, the ETE
sends an SPTB message back to the ITE with MTU set to the size of
the largest fragment received (see: Section 5.6.1.1).Next, if the packet arrived as multiple IP fragments and the
inner packet is larger than 1500 bytes, the ETE silently discards
the packet; otherwise, it continues to process the packet.Next, if there is an incorrect value in a SEAL header field
(e.g., an incorrect "VER" field value), the ETE discards the packet.
If the SEAL header has C==0, the ETE also returns an SCMP "Parameter
Problem" (SPP) message (see Section 5.6.1.2).Next, if the SEAL header has C==1, the ETE processes the packet
as an SCMP packet as specified in Section 5.6.2. Otherwise, the ETE
continues to process the packet as a SEAL data packet.Next, if the SEAL header has (M==1 || Fragment Offset!=0) the ETE
checks to see if the other segments of this already-segmented SEAL
packet have arrived, i.e., by looking for additional segments that
have the same outer IP source address, destination address, source
port number and SEAL Identification value. If all other segments
have already arrived, the ETE discards the SEAL header and other
outer headers from the non-initial segments and appends the segments
onto the end of the first segment according to their offset value.
Otherwise, the ETE caches the new segment for at most 60 seconds
while awaiting the arrival of its partners. During this process, the
ETE discards any segments that are overlapping with respect to
segments that have already been received, and also discards any
segments that have M==1 in the SEAL header but do not contain an
integer multiple of 8 bytes. The ETE further SHOULD manage the SEAL
reassembly cache the same as described for the IP-Layer Reassembly
cache in Section 5.5.3, i.e., it SHOULD perform an early discard for
any pending reassemblies that have low probability of
completion.Next, if the SEAL header in the (reassembled) packet has P==1,
the ETE drops the packet unconditionally and sends an SPTB message
back to the ITE (see: Section 5.6.1.1) if it has not already sent an
SPTB message based on IP fragmentation. (Note that the ETE therefore
sends only a single SPTB message for a probe packet that also
experienced IP fragmentation, i.e., it does not send multiple SPTB
messages.)Finally, the ETE discards the outer headers and processes the
inner packet according to the header type indicated in the SEAL Next
Header field. If the next hop toward the inner destination address
is via a different interface than the SEAL packet arrived on, the
ETE discards the SEAL header and delivers the inner packet either to
the local host or to the next hop if the packet is not destined to
the local host.If the next hop is on the same tunnel the SEAL packet arrived on,
however, the ETE submits the packet for SEAL re-encapsulation
beginning with the specification in Section 5.4.3 above and without
decrementing the value in the inner (TTL / Hop Limit) field.SEAL provides a companion SEAL Control Message Protocol (SCMP) that
uses the same message types and formats as for the Internet Control
Message Protocol for IPv6 (ICMPv6) . The SCMP
messaging protocol operates over bidirectional and partially
unidirectional tunnels. (For fully unidirectional tunnels, SEAL must
operate without the benefit of SCMP meaning that steady-state
fragmentation and reassembly may be necessary in extreme cases. In
that case, the ITE must select a conservative MINMTU to ensure that
IPv4 fragmentation is avoided in order to avoid reassembly errors at
high data rates .)As for ICMPv6, each SCMP message includes a 32-bit header and a
variable-length body. The ITE encapsulates the SCMP message in a SEAL
header and outer headers as shown in :The following sections specify the generation, processing and
relaying of SCMP messages.ETEs generate SCMP messages in response to receiving certain SEAL
data packets using the format shown in :The error message includes the 32-bit SCMP message
header, followed by a 32-bit Type-Specific Data field, followed by
the leading portion of the invoking SEAL data packet beginning with
the SEAL header as the "packet-in-error". The packet-in-error
includes as much of the invoking packet as possible extending to a
length that would not cause the entire SCMP packet following outer
encapsulation to exceed MINMTU bytes.When the ETE processes a SEAL data packet for which the
Identification and ICV values are correct but an error must be
returned, it prepares an SCMP message as shown in . The ETE sets the Type and Code fields to the
same values that would appear in the corresponding ICMPv6 message
, but calculates the Checksum beginning with
the SCMP message header using the algorithm specified for ICMPv4 in
.The ETE next encapsulates the SCMP message in the requisite SEAL
and outer headers as shown in . During
encapsulation, the ETE sets the outer destination address/port
numbers of the SCMP packet to the values associated with the ITE and
sets the outer source address/port numbers to its own outer
address/port numbers.The ETE then sets (C=1; M=0; Fragment Offset=0) in the SEAL
header, then sets V, Next Header and LINK to the same values that
appeared in the SEAL header of the data packet. The ETE next sets
the Identification field to the next Identification value scheduled
for this ITE, then increments the next Identification value. When
V==1, the ETE then prepares the ICV field the same as specified for
SEAL data packet encapsulation in Section 5.4.4. If this message is
in direct response to a SEAL data packet sent by the ITE, the ETE
next sets P=0 and sends the resulting SCMP packet to the ITE the
same as specified for SEAL data packets in Section 5.4.5.If the message is in response to an SCMP message received from a
next hop ETE or to an ICMP message received from a router on the
path to a next hop ETE, the ETE instead sets P=1 and passes the
message to the ITE in a "reverse re-encapsulation" process. In
particular, when the previous hop toward the source of the inner
packet within the packet-in-error in a received SCMP/ICMP message is
reached via the same tunnel as the message arrived on, the ETE
replaces the outer headers of the message (up to and including the
SEAL header) with headers that will be recognized and accepted by
the previous hop and sends the resulting packet to the previous
hop.The following sections describe additional considerations for
various SCMP error messages:An ETE generates an SPTB message when it receives a SEAL probe
packet (i.e., one with C=0; P=1 in the SEAL header) or when it
receives a SEAL packet that arrived as multiple outer IP
fragments. The ETE prepares the SPTB message the same as for the
corresponding ICMPv6 PTB message, and writes the length of the
largest outer IP fragment received in the MTU field of the message
(or the full length of the outer IP packet if the packet was
unfragmented). In that case, the ETE sets (C=1; P=0) in the SEAL
header.An ETE also generates an SPTB message when it attempts to
forward a SEAL data packet to a next hop ETE via the same tunnel
the data packet arrived on, but for which MAXMTU for that SEAL
path is insufficient to accommodate the packet (See Section
5.4.3.2). In that case, the ETE sets (C=1; P=1) in the SEAL
header.An ETE finally generates an SPTB message when it receives an
ICMP PTB message from a router on the path to a next hop ETE (See
Section 5.4.7). In that case, the ETE also sets (C=1; P=1) in the
SEAL header.An ETE generates an SCMP "Destination Unreachable" (SDU)
message under the same conditions that an IPv6 system would
generate an ICMPv6 Destination Unreachable message.An ETE generates an SCMP "Parameter Problem" (SPP) message when
it receives a SEAL packet with an incorrect value in the SEAL
header.TEs generate other SCMP message types using methods and
procedures specified in other documents. For example, SCMP message
types used for tunnel neighbor coordinations are specified in VET
.An ITE may receive SCMP messages with C==1 in the SEAL header
after sending packets to an ETE. The ITE first verifies that the
outer addresses of the SCMP packet are correct, and that the
Identification field contains an acceptable value. The ITE next
verifies that the SEAL header fields are set correctly as specified
in Section 5.6.1. When V==1, the ITE then verifies the ICV. The ITE
next verifies the Checksum value in the SCMP message header. If any
of these values are incorrect, the ITE silently discards the
message; otherwise, it processes the message as follows:After an ITE sends a SEAL packet to an ETE, it may receive an
SPTB message with a packet-in-error containing the leading portion
of the packet (see: Section 5.6.1.1). If the SEAL header has P==1
the ITE consults its forwarding information base to pass the
message to the previous hop toward the source address of the
encapsulated inner packet. When the previous hop is reached via
the same SEAL tunnel, the ITE passes the SPTB message to the
previous hop as specified in Section 5.6.1. Otherwise, the ITE
transcribes the inner packet within the packet-in-error into a
message appropriate for the inner protocol version (e.g., ICMPv4
for IPv4, ICMPv6 for IPv6, etc.).If the SEAL header has P==0, the ITE instead processes the
message as an MTU limitation on the SEAL path to this ETE. In that
case, the ITE first sets the temporary variable "PMTU" for this
SEAL path to the MTU value in the SPTB message and processes the
message as follows:If PMTU is no smaller than (1500+HLEN), the ITE suspends
the SEAL segmentation/reassembly process for this SEAL path so
that whole (unfragmented) SEAL packets can be used. If the
packet is a probe being used to establish a stateful MTU for
this SEAL path (see: section 5.4.9), the ITE also sets
MAXMTU=PMTU.If PMTU is smaller than (1500+HLEN) but no smaller than
MINMTU the ITE sets MAXMTU to (1500+HLEN) and resumes the SEAL
segmentation/reassembly process for this SEAL path.If PMTU is smaller than MINMTU and the packet-in-error is a
probe used for the purpose of middlebox reassembly detection
(see: section 5.4.8), the ITE notes the results of the probe.
Otherwise, the ITE consults a plateau table to determine a new
value for MAXMTU. For example, if the ITE receives a PTB
message with small PMTU and packet-in-error length 8KB, it can
set MAXMTU=4KB. If the ITE subsequently receives a PTB message
with small PMTU and length 4KB, it can set MAXMTU=2KB, etc.,
to a minimum value of MAXMTU=(1500+HLEN). Finally, if the ITE
is using a MINMTU value larger than 1280 for IPv6 or 576 for
IPv4, it may need to reduce MINMTU if the PMTU value is
small.Next, if the packet-in-error was no larger than (1500+HLEN) or
the packet-in-error was an explicit probe (i.e., one with (C==0;
P==1 in the SEAL header of the packet-in-error), the ITE discards
the SPTB message.An ITE may receive an SDU message with an appropriate code
under the same circumstances that an IPv6 node would receive an
ICMPv6 Destination Unreachable message. The ITE transcribes the
message and forwards it toward the source address of the inner
packet within the packet-in-error the same as specified for SPTB
messages with P==1 in Section 5.6.2.1.An ITE may receive an SPP message when the ETE receives a SEAL
packet with an incorrect value in the SEAL header. The ITE should
examine the SEAL header within the packet-in-error to determine
whether different settings should be used in subsequent packets,
but does not relay the message further.TEs process other SCMP message types using methods and
procedures specified in other documents. For example, SCMP message
types used for tunnel neighbor coordinations are specified in VET
.Subnetwork designers are expected to follow the recommendations in
Section 2 of when configuring link MTUs.End systems are encouraged to implement end-to-end MTU assurance
(e.g., using Packetization Layer Path MTU Discovery (PLPMTUD) per ) even if the subnetwork is using SEAL.When end systems use PLPMTUD, SEAL will ensure that the tunnel
behaves as a link in the path that assures an MTU of at least 1500 bytes
while not precluding discovery of larger MTUs. The PLPMTUD mechanism
will therefore be able to function as designed in order to discover and
utilize larger MTUs.Routers within the subnetwork are expected to observe the standard IP
router requirements, including the implementation of IP fragmentation
and reassembly as well as the generation of ICMP messages .Note that, even when routers support existing requirements for the
generation of ICMP messages, these messages are often filtered and
discarded by middleboxes on the path to the original source of the
message that triggered the ICMP. It is therefore not possible to assume
delivery of ICMP messages even when routers are correctly
implemented.SEAL supports nested tunneling - an example would be a recursive
nesting of mobile networks, where the first network receives service
from an ISP, the second network receives service from the first network,
the third network receives service from the second network, etc. It is
imperative that such nesting not extend indefinitely; SEAL tunnels
therefore honor the Encapsulation Limit option defined in .In such nested arrangements, the SEAL ITE has a tunnel neighbor
relationship only with ETEs at its own nesting level, i.e., it does not
have a tunnel neighbor relationship with TEs at other nesting
levels.Therefore, when an ITE 'A' within an outer nesting level needs to
return an error message to an ITE 'B' within an inner nesting level, it
generates an ordinary ICMP error message the same as if it were an
ordinary router within the subnetwork. 'B' can then perform message
validation as specified in Section 5.4.7, but full message origin
authentication is not possible.(Note that the SCMP protocol could instead be extended to allow an
outer nesting level ITE 'A' to return an SCMP message to an inner
nesting level ITE 'B' rather than return an ICMP message. This would
conceptually allow the control messages to pass through firewalls and
NATs, however it would give no more message origin authentication
assurance than for ordinary ICMP messages. It was therefore determined
that the complexity of extending the SCMP protocol was of little value
within the context of the anticipated use cases for nested
encapsulations.)Although a SEAL tunnel may span an arbitrarily-large subnetwork
expanse, the IP layer sees the tunnel as a simple link that supports the
IP service model. Links with high bit error rates (BERs) (e.g., IEEE
802.11) use Automatic Repeat-ReQuest (ARQ) mechanisms to increase packet delivery ratios, while links with
much lower BERs typically omit such mechanisms. Since SEAL tunnels may
traverse arbitrarily-long paths over links of various types that are
already either performing or omitting ARQ as appropriate, it would
therefore be inefficient to require the tunnel endpoints to also perform
ARQ.The SEAL header includes an integrity check field that covers the
SEAL header and at least the inner packet headers. This provides for
header integrity verification on a segment-by-segment basis for a
segmented re-encapsulating tunnel path.Fragmentation and reassembly schemes must also consider
packet-splicing errors, e.g., when two fragments from the same packet
are concatenated incorrectly, when a fragment from packet X is
reassembled with fragments from packet Y, etc. The primary sources of
such errors include implementation bugs and wrapping IPv4 ID fields.In particular, the IPv4 16-bit ID field can wrap with only 64K
packets with the same (src, dst, protocol)-tuple alive in the system at
a given time . When the IPv4 ID field is
re-written by a middlebox such as a NAT or Firewall, ID field wrapping
can occur with even fewer packets alive in the system. It is therefore
essential that IPv4 fragmentation and reassembly be detected early and
tuned out through proper application of SEAL segmentation and
reassembly.The IANA is requested to allocate a User Port number for "SEAL" in
the 'port-numbers' registry. The Service Name is "SEAL", and the
Transport Protocols are TCP and UDP. The Assignee is the IESG
(iesg@ietf.org) and the Contact is the IETF Chair (chair@ietf.org). The
Description is "Subnetwork Encapsulation and Adaptation Layer (SEAL)",
and the Reference is the RFC-to-be currently known as
'draft-templin-intarea-seal'.SEAL provides a segment-by-segment message origin authentication,
integrity and anti-replay service. The SEAL header is sent in-the-clear
the same as for the outer IP and other outer headers. In this respect,
the threat model is no different than for IPv6 extension headers. Unlike
IPv6 extension headers, however, the SEAL header can be protected by an
integrity check that also covers the inner packet headers.An amplification/reflection/buffer overflow attack is possible when
an attacker sends IP fragments with spoofed source addresses to an ETE
in an attempt to clog the ETE's reassembly buffer and/or cause the ETE
to generate a stream of SCMP messages returned to a victim ITE. The SCMP
message ICV, Identification, as well as the inner headers of the
packet-in-error, provide mitigation for the ETE to detect and discard
SEAL segments with spoofed source addresses.Security issues that apply to tunneling in general are discussed in
.Section 3.1.7 of provides a high-level
sketch for supporting large tunnel MTUs via a tunnel-level segmentation
and reassembly capability to avoid IP level fragmentation.Section 3 of describes inner and
outer fragmentation at the tunnel endpoints as alternatives for
accommodating the tunnel MTU.Section 4 of specifies a method for
inserting and processing extension headers between the base IPv6 header
and transport layer protocol data. The SEAL header is inserted and
processed in exactly the same manner.IPsec/AH is is used
for full message integrity verification between tunnel endpoints,
whereas SEAL only ensures integrity for the inner packet headers. The
AYIYA proposal uses similar
means for providing message authentication and integrity.SEAL, along with the Virtual Enterprise Traversal (VET) tunnel virtual interface abstraction,
are the functional building blocks for the Interior Routing Overlay
Network (IRON) and Routing and
Addressing in Networks with Global Enterprise Recursion (RANGER) architectures.The concepts of path MTU determination through the report of
fragmentation and extending the IPv4 Identification field were first
proposed in deliberations of the TCP-IP mailing list and the Path MTU
Discovery Working Group (MTUDWG) during the late 1980's and early
1990's. An historical analysis of the evolution of these concepts, as
well as the development of the eventual PMTUD mechanism, appears in
.An early implementation of the first revision of SEAL is available at: http://isatap.com/seal.The following individuals are acknowledged for helpful comments and
suggestions: Jari Arkko, Fred Baker, Iljitsch van Beijnum, Oliver
Bonaventure, Teco Boot, Bob Braden, Brian Carpenter, Steve Casner, Ian
Chakeres, Noel Chiappa, Remi Denis-Courmont, Remi Despres, Ralph Droms,
Aurnaud Ebalard, Gorry Fairhurst, Washam Fan, Dino Farinacci, Joel
Halpern, Sam Hartman, John Heffner, Thomas Henderson, Bob Hinden,
Christian Huitema, Eliot Lear, Darrel Lewis, Joe Macker, Matt Mathis,
Erik Nordmark, Dan Romascanu, Dave Thaler, Joe Touch, Mark Townsley, Ole
Troan, Margaret Wasserman, Magnus Westerlund, Robin Whittle, James
Woodyatt, and members of the Boeing Research & Technology NST
DC&NT group.Discussions with colleagues following the publication of have provided useful insights that have resulted in
significant improvements to this, the Second Edition of SEAL.This document received substantial review input from the IESG and
IETF area directorates in the February 2013 timeframe. IESG members and
IETF area directorate representatives who contributed helpful comments
and suggestions are gratefully acknowledged. Discussions on the IETF
IPv6 and Intarea mailing lists in the summer 2013 timeframe also
stimulated several useful ideas.Path MTU determination through the report of fragmentation was first
proposed by Charles Lynn on the TCP-IP mailing list in 1987. Extending
the IP identification field was first proposed by Steve Deering on the
MTUDWG mailing list in 1989.Fragmentation Considered HarmfulBeyond Folklore: Observations on Fragmented TrafficMeasuring Interactions Between Transport Protocols and
MiddleboxesInferring and Debugging Path MTU Discovery FailuresMeasuring Path MTU Discovery BehaviorDiscovering Path MTU Black Holes on the Internet using RIPE
Atlas