Rfc | 5534 |
Title | Failure Detection and Locator Pair Exploration Protocol for IPv6
Multihoming |
Author | J. Arkko, I. van Beijnum |
Date | June 2009 |
Format: | TXT,
HTML |
Status: | PROPOSED STANDARD |
|
Network Working Group J. Arkko
Request for Comments: 5534 Ericsson
Category: Standards Track I. van Beijnum
IMDEA Networks
June 2009
Failure Detection and Locator Pair
Exploration Protocol for IPv6 Multihoming
Status of This Memo
This document specifies an Internet standards track protocol for the
Internet community, and requests discussion and suggestions for
improvements. Please refer to the current edition of the "Internet
Official Protocol Standards" (STD 1) for the standardization state
and status of this protocol. Distribution of this memo is unlimited.
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Abstract
This document specifies how the level 3 multihoming Shim6 protocol
(Shim6) detects failures between two communicating nodes. It also
specifies an exploration protocol for switching to another pair of
interfaces and/or addresses between the same nodes if a failure
occurs and an operational pair can be found.
Table of Contents
1. Introduction ....................................................3
2. Requirements Language ...........................................4
3. Definitions .....................................................4
3.1. Available Addresses ........................................4
3.2. Locally Operational Addresses ..............................5
3.3. Operational Address Pairs ..................................5
3.4. Primary Address Pair .......................................7
3.5. Current Address Pair .......................................7
4. Protocol Overview ...............................................8
4.1. Failure Detection ..........................................8
4.2. Full Reachability Exploration .............................10
4.3. Exploration Order .........................................11
5. Protocol Definition ............................................13
5.1. Keepalive Message .........................................13
5.2. Probe Message .............................................14
5.3. Keepalive Timeout Option Format ...........................18
6. Behavior .......................................................19
6.1. Incoming Payload Packet ...................................20
6.2. Outgoing Payload Packet ...................................21
6.3. Keepalive Timeout .........................................21
6.4. Send Timeout ..............................................22
6.5. Retransmission ............................................22
6.6. Reception of the Keepalive Message ........................22
6.7. Reception of the Probe Message State=Exploring ............23
6.8. Reception of the Probe Message State=InboundOk ............23
6.9. Reception of the Probe Message State=Operational ..........23
6.10. Graphical Representation of the State Machine ............24
7. Protocol Constants and Variables ...............................24
8. Security Considerations ........................................25
9. Operational Considerations .....................................27
10. References ....................................................28
10.1. Normative References .....................................28
10.2. Informative References ...................................29
Appendix A. Example Protocol Runs..................................30
Appendix B. Contributors...........................................35
Appendix C. Acknowledgements.......................................35
1. Introduction
The Shim6 protocol [RFC5533] extends IPv6 to support multihoming. It
is an IP-layer mechanism that hides multihoming from applications. A
part of the Shim6 solution involves detecting when a currently used
pair of addresses (or interfaces) between two communication nodes has
failed and picking another pair when this occurs. We call the former
"failure detection", and the latter, "locator pair exploration".
This document specifies the mechanisms and protocol messages to
achieve both failure detection and locator pair exploration. This
part of the Shim6 protocol is called the REAchability Protocol
(REAP).
Failure detection is made as lightweight as possible. Payload data
traffic in both directions is observed, and in the case where there
is no traffic because the communication is idle, failure detection is
also idle and doesn't generate any packets. When payload traffic is
flowing in both directions, there is no need to send failure
detection packets, either. Only when there is traffic in one
direction does the failure detection mechanism generate keepalives in
the other direction. As a result, whenever there is outgoing traffic
and no incoming return traffic or keepalives, there must be failure,
at which point the locator pair exploration is performed to find a
working address pair for each direction.
This document is structured as follows: Section 3 defines a set of
useful terms, Section 4 gives an overview of REAP, and Section 5
provides a detailed definition. Section 6 specifies behavior, and
Section 7 discusses protocol constants. Section 8 discusses the
security considerations of REAP.
In this specification, we consider an address to be synonymous with a
locator. Other parts of the Shim6 protocol ensure that the different
locators used by a node actually belong together. That is, REAP is
not responsible for ensuring that said node ends up with a legitimate
locator.
REAP has been designed to be used with Shim6 and is therefore
tailored to an environment where it typically runs on hosts, uses
widely varying types of paths, and is unaware of application context.
As a result, REAP attempts to be as self-configuring and unobtrusive
as possible. In particular, it avoids sending any packets except
where absolutely required and employs exponential back-off to avoid
congestion. The downside is that it cannot offer the same
granularity of detecting problems as mechanisms that have more
application context and ability to negotiate or configure parameters.
Future versions of this specification may consider extensions with
such capabilities, for instance, through inheriting some mechanisms
from the Bidirectional Forwarding Detection (BFD) protocol [BFD].
2. Requirements Language
The key words "MUST", "MUST NOT", "REQUIRED", "SHALL", "SHALL NOT",
"SHOULD", "SHOULD NOT", "RECOMMENDED", "MAY", and "OPTIONAL" in this
document are to be interpreted as described in [RFC2119].
3. Definitions
This section defines terms useful for discussing failure detection
and locator pair exploration.
3.1. Available Addresses
Shim6 nodes need to be aware of what addresses they themselves have.
If a node loses the address it is currently using for communications,
another address must replace it. And if a node loses an address that
the node's peer knows about, the peer must be informed. Similarly,
when a node acquires a new address it may generally wish the peer to
know about it.
Definition. Available address - an address is said to be available
if all the following conditions are fulfilled:
o The address has been assigned to an interface of the node.
o The valid lifetime of the prefix (Section 4.6.2 of RFC 4861
[RFC4861]) associated with the address has not expired.
o The address is not tentative in the sense of RFC 4862 [RFC4862].
In other words, the address assignment is complete so that
communications can be started.
Note that this explicitly allows an address to be optimistic in
the sense of Optimistic Duplicate Address Detection (DAD)
[RFC4429] even though implementations may prefer using other
addresses as long as there is an alternative.
o The address is a global unicast or unique local address [RFC4193].
That is, it is not an IPv6 site-local or link-local address.
With link-local addresses, the nodes would be unable to determine
on which link the given address is usable.
o The address and interface are acceptable for use according to a
local policy.
Available addresses are discovered and monitored through mechanisms
outside the scope of Shim6. Shim6 implementations MUST be able to
employ information provided by IPv6 Neighbor Discovery [RFC4861],
Address Autoconfiguration [RFC4862], and DHCP [RFC3315] (when DHCP is
implemented). This information includes the availability of a new
address and status changes of existing addresses (such as when an
address becomes invalid).
3.2. Locally Operational Addresses
Two different granularity levels are needed for failure detection.
The coarser granularity is for individual addresses.
Definition. Locally operational address - an available address is
said to be locally operational when its use is known to be possible
locally. In other words, when the interface is up, a default router
(if needed) suitable for this address is known to be reachable, and
no other local information points to the address being unusable.
Locally operational addresses are discovered and monitored through
mechanisms outside the Shim6 protocol. Shim6 implementations MUST be
able to employ information provided from Neighbor Unreachability
Detection [RFC4861]. Implementations MAY also employ additional,
link-layer-specific mechanisms.
Note 1: A part of the problem in ensuring that an address is
operational is making sure that after a change in link-layer
connectivity, we are still connected to the same IP subnet.
Mechanisms such as [DNA-SIM] can be used to ensure this.
Note 2: In theory, it would also be possible for nodes to learn
about routing failures for a particular selected source prefix, if
only suitable protocols for this purpose existed. Some proposals
in this space have been made (see, for instance [ADD-SEL] and
[MULTI6]), but none have been standardized to date.
3.3. Operational Address Pairs
The existence of locally operational addresses are not, however, a
guarantee that communications can be established with the peer. A
failure in the routing infrastructure can prevent packets from
reaching their destination. For this reason, we need the definition
of a second level of granularity, which is used for pairs of
addresses.
Definition. Bidirectionally operational address pair - a pair of
locally operational addresses are said to be an operational address
pair when bidirectional connectivity can be shown between the
addresses. That is, a packet sent with one of the addresses in the
Source field and the other in the Destination field reaches the
destination, and vice versa.
Unfortunately, there are scenarios where bidirectionally operational
address pairs do not exist. For instance, ingress filtering or
network failures may result in one address pair being operational in
one direction while another one is operational from the other
direction. The following definition captures this general situation.
Definition. Unidirectionally operational address pair - a pair of
locally operational addresses are said to be a unidirectionally
operational address pair when packets sent with the first address as
the source and the second address as the destination reach the
destination.
Shim6 implementations MUST support the discovery of operational
address pairs through the use of explicit reachability tests and
Forced Bidirectional Communication (FBD), described later in this
specification. Future extensions of Shim6 may specify additional
mechanisms. Some ideas of such mechanisms are listed below but are
not fully specified in this document:
o Positive feedback from upper-layer protocols. For instance, TCP
can indicate to the IP layer that it is making progress. This is
similar to how IPv6 Neighbor Unreachability Detection can, in some
cases, be avoided when upper layers provide information about
bidirectional connectivity [RFC4861].
In the case of unidirectional connectivity, the upper-layer
protocol responses come back using another address pair, but show
that the messages sent using the first address pair have been
received.
o Negative feedback from upper-layer protocols. It is conceivable
that upper-layer protocols give an indication of a problem to the
multihoming layer. For instance, TCP could indicate that there's
either congestion or lack of connectivity in the path because it
is not getting ACKs.
o ICMP error messages. Given the ease of spoofing ICMP messages,
one should be careful not to trust these blindly, however. One
approach would be to use ICMP error messages only as a hint to
perform an explicit reachability test or to move an address pair
to a lower place in the list of address pairs to be probed, but
not to use these messages as a reason to disrupt ongoing
communications without other indications of problems. The
situation may be different when certain verifications of the ICMP
messages are being performed, as explained by Gont in [GONT].
These verifications can ensure that (practically) only on-path
attackers can spoof the messages.
3.4. Primary Address Pair
The primary address pair consists of the addresses that upper-layer
protocols use in their interaction with the Shim6 layer. Use of the
primary address pair means that the communication is compatible with
regular non-Shim6 communication and that no context tag needs to be
present.
3.5. Current Address Pair
Shim6 needs to avoid sending packets that belong to the same
transport connection concurrently over multiple paths. This is
because congestion control in commonly used transport protocols is
based upon a notion of a single path. While routing can introduce
path changes as well and transport protocols have means to deal with
this, frequent changes will cause problems. Effective congestion
control over multiple paths is considered a research topic at the
time of publication of this document. Shim6 does not attempt to
employ multiple paths simultaneously.
Note: The Stream Control Transmission Protocol (SCTP) and future
multipath transport protocols are likely to require interaction
with Shim6, at least to ensure that they do not employ Shim6
unexpectedly.
For these reasons, it is necessary to choose a particular pair of
addresses as the current address pair that will be used until
problems occur, at least for the same session.
It is theoretically possible to support multiple current address
pairs for different transport sessions or Shim6 contexts.
However, this is not supported in this version of the Shim6
protocol.
A current address pair need not be operational at all times. If
there is no traffic to send, we may not know if the current address
pair is operational. Nevertheless, it makes sense to assume that the
address pair that worked previously continues to be operational for
new communications as well.
4. Protocol Overview
This section discusses the design of the reachability detection and
full reachability exploration mechanisms, and gives an overview of
the REAP protocol.
Exploring the full set of communication options between two nodes
that both have two or more addresses is an expensive operation as the
number of combinations to be explored increases very quickly with the
number of addresses. For instance, with two addresses on both sides,
there are four possible address pairs. Since we can't assume that
reachability in one direction automatically means reachability for
the complement pair in the other direction, the total number of two-
way combinations is eight. (Combinations = nA * nB * 2.)
An important observation in multihoming is that failures are
relatively infrequent, so an operational pair that worked a few
seconds ago is very likely to still be operational. Thus, it makes
sense to have a lightweight protocol that confirms existing
reachability, and to only invoke heavier exploration mechanism when
there is a suspected failure.
4.1. Failure Detection
Failure detection consists of three parts: tracking local
information, tracking remote peer status, and finally verifying
reachability. Tracking local information consists of using, for
instance, reachability information about the local router as an
input. Nodes SHOULD employ techniques listed in Sections 3.1 and 3.2
to track the local situation. It is also necessary to track remote
address information from the peer. For instance, if the peer's
address in the current address pair is no longer locally operational,
a mechanism to relay that information is needed. The Update Request
message in the Shim6 protocol is used for this purpose [RFC5533].
Finally, when the local and remote information indicates that
communication should be possible and there are upper-layer packets to
be sent, reachability verification is necessary to ensure that the
peers actually have an operational address pair.
A technique called Forced Bidirectional Detection (FBD) is employed
for the reachability verification. Reachability for the currently
used address pair in a Shim6 context is determined by making sure
that whenever there is payload traffic in one direction, there is
also traffic in the other direction. This can be data traffic as
well, or it may be transport-layer acknowledgments or a REAP
reachability keepalive if there is no other traffic. This way, it is
no longer possible to have traffic in only one direction; so whenever
there is payload traffic going out, but there are no return packets,
there must be a failure, and the full exploration mechanism is
started.
A more detailed description of the current pair-reachability
evaluation mechanism:
1. To prevent the other side from concluding that there is a
reachability failure, it's necessary for a node implementing the
failure-detection mechanism to generate periodic keepalives when
there is no other traffic.
FBD works by generating REAP keepalives if the node is receiving
packets from its peer but not sending any of its own. The
keepalives are sent at certain intervals so that the other side
knows there is a reachability problem when it doesn't receive any
incoming packets for the duration of a Send Timeout period. The
node communicates its Send Timeout value to the peer as a
Keepalive Timeout Option (Section 5.3) in the I2, I2bis, R2, or
UPDATE messages. The peer then maps this value to its Keepalive
Timeout value.
The interval after which keepalives are sent is named the
Keepalive Interval. The RECOMMENDED approach for the Keepalive
Interval is to send keepalives at one-half to one-third of the
Keepalive Timeout interval, so that multiple keepalives are
generated and have time to reach the peer before it times out.
2. Whenever outgoing payload packets are generated, a timer is
started to reflect the requirement that the peer should generate
return traffic from payload packets. The timeout value is set to
the value of Send Timeout.
For the purposes of this specification, "payload packet" refers
to any packet that is part of a Shim6 context, including both
upper-layer protocol packets and Shim6 protocol messages, except
those defined in this specification. For the latter messages,
Section 6 specifies what happens to the timers when a message is
transmitted or received.
3. Whenever incoming payload packets are received, the timer
associated with the return traffic from the peer is stopped, and
another timer is started to reflect the requirement for this node
to generate return traffic. This timeout value is set to the
value of Keepalive Timeout.
These two timers are mutually exclusive. In other words, either
the node is expecting to see traffic from the peer based on the
traffic that the node sent earlier or the node is expecting to
respond to the peer based on the traffic that the peer sent
earlier (otherwise, the node is in an idle state).
4. The reception of a REAP Keepalive message leads to stopping the
timer associated with the return traffic from the peer.
5. Keepalive Interval seconds after the last payload packet has been
received for a context, if no other packet has been sent within
this context since the payload packet has been received, a REAP
Keepalive message is generated for the context in question and
transmitted to the peer. A node may send the keepalive sooner
than Keepalive Interval seconds if implementation considerations
warrant this, but should take care to avoid sending keepalives at
an excessive rate. REAP Keepalive messages SHOULD continue to be
sent at the Keepalive Interval until either a payload packet in
the Shim6 context has been received from the peer or the
Keepalive Timeout expires. Keepalives are not sent at all if one
or more payload packets were sent within the Keepalive Interval.
6. Send Timeout seconds after the transmission of a payload packet
with no return traffic on this context, a full reachability
exploration is started.
Section 7 provides some suggested defaults for these timeout values.
The actual value SHOULD be randomized in order to prevent
synchronization. Experience from the deployment of the Shim6
protocol is needed in order to determine what values are most
suitable.
4.2. Full Reachability Exploration
As explained in previous sections, the currently used address pair
may become invalid, either through one of the addresses becoming
unavailable or nonoperational or through the pair itself being
declared nonoperational. An exploration process attempts to find
another operational pair so that communications can resume.
What makes this process hard is the requirement to support
unidirectionally operational address pairs. It is insufficient to
probe address pairs by a simple request-response protocol. Instead,
the party that first detects the problem starts a process where it
tries each of the different address pairs in turn by sending a
message to its peer. These messages carry information about the
state of connectivity between the peers, such as whether the sender
has seen any traffic from the peer recently. When the peer receives
a message that indicates a problem, it assists the process by
starting its own parallel exploration to the other direction, again
sending information about the recently received payload traffic or
signaling messages.
Specifically, when A decides that it needs to explore for an
alternative address pair to B, it will initiate a set of Probe
messages, in sequence, until it gets a Probe message from B
indicating that (a) B has received one of A's messages and,
obviously, (b) that B's Probe message gets back to A. B uses the
same algorithm, but starts the process from the reception of the
first Probe message from A.
Upon changing to a new address pair, the network path traversed most
likely has changed, so the upper-layer protocol (ULP), SHOULD be
informed. This can be a signal for the ULP to adapt, due to the
change in path, so that for example, if the ULP is TCP, it could
initiate a slow start procedure. However, it's likely that the
circumstances that led to the selection of a new path already caused
enough packet loss to trigger slow start.
REAP is designed to support failure recovery even in the case of
having only unidirectionally operational address pairs. However, due
to security concerns discussed in Section 8, the exploration process
can typically be run only for a session that has already been
established. Specifically, while REAP would in theory be capable of
exploration even during connection establishment, its use within the
Shim6 protocol does not allow this.
4.3. Exploration Order
The exploration process assumes an ability to choose address pairs
for testing. An overview of the choosing process used by REAP is as
follows:
o As an input to start the process, the node has knowledge of its
own addresses and has been told via Shim6 protocol messages what
the addresses of the peer are. A list of possible pairs of
addresses can be constructed by combining the two pieces of
information.
o By employing standard IPv6 address selection rules, the list is
pruned by removing combinations that are inappropriate, such as
attempting to use a link-local address when contacting a peer that
uses a global unicast address.
o Similarly, standard IPv6 address selection rules provide a basic
priority order for the pairs.
o Local preferences may be applied for some additional tuning of the
order in the list. The mechanisms for local preference settings
are not specified but can involve, for instance, configuration
that sets the preference for using one interface over another.
o As a result, the node has a prioritized list of address pairs to
try. However, the list may still be long, as there may be a
combinatorial explosion when there are many addresses on both
sides. REAP employs these pairs sequentially, however, and uses a
back-off procedure to avoid a "signaling storm". This ensures
that the exploration process is relatively conservative or "safe".
The tradeoff is that finding a working path may take time if there
are many addresses on both sides.
In more detail, the process is as follows. Nodes first consult the
RFC 3484 default address selection rules [RFC3484] to determine what
combinations of addresses are allowed from a local point of view, as
this reduces the search space. RFC 3484 also provides a priority
ordering among different address pairs, possibly making the search
faster. (Additional mechanisms may be defined in the future for
arriving at an initial ordering of address pairs before testing
starts [PAIR].) Nodes may also use local information, such as known
quality of service parameters or interface types, to determine what
addresses are preferred over others, and try pairs containing such
addresses first. The Shim6 protocol also carries preference
information in its messages.
Out of the set of possible candidate address pairs, nodes SHOULD
attempt to test through all of them until an operational pair is
found, and retry the process as necessary. However, all nodes MUST
perform this process sequentially and with exponential back-off.
This sequential process is necessary in order to avoid a "signaling
storm" when an outage occurs (particularly for a complete site).
However, it also limits the number of addresses that can, in
practice, be used for multihoming, considering that transport- and
application-layer protocols will fail if the switch to a new address
pair takes too long.
Section 7 suggests default values for the timers associated with the
exploration process. The value Initial Probe Timeout (0.5 seconds)
specifies the interval between initial attempts to send probes; the
Number of Initial Probes (4) specifies how many initial probes can be
sent before the exponential back-off procedure needs to be employed.
This process increases the time between every probe if there is no
response. Typically, each increase doubles the time, but this
specification does not mandate a particular increase.
Note: The rationale for sending four packets at a fixed rate
before the exponential back-off is employed is to avoid having to
send these packets excessively fast. Without this, having 0.5
seconds between the third and fourth probe means that the time
between the first and second probe would have to be 0.125 seconds,
which gives very little time for a reply to the first packet to
arrive. Also, this means that the first four packets are sent
within 0.875 seconds rather than 2 seconds, increasing the
potential for congestion if a large number of Shim6 contexts need
to send probes at the same time after a failure.
Finally, Max Probe Timeout (60 seconds) specifies a limit beyond
which the probe interval may not grow. If the exploration process
reaches this interval, it will continue sending at this rate until a
suitable response is triggered or the Shim6 context is garbage
collected, because upper-layer protocols using the Shim6 context in
question are no longer attempting to send packets. Reaching the Max
Probe Timeout may also serve as a hint to the garbage collection
process that the context is no longer usable.
5. Protocol Definition
5.1. Keepalive Message
The format of the Keepalive message is as follows:
0 1 2 3
0 1 2 3 4 5 6 7 8 9 0 1 2 3 4 5 6 7 8 9 0 1 2 3 4 5 6 7 8 9 0 1
+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
| Next Header | Hdr Ext Len |0| Type = 66 | Reserved1 |0|
+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
| Checksum |R| |
+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+ |
| Receiver Context Tag |
+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
| Reserved2 |
+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
| |
+ Options +
| |
+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
Next Header, Hdr Ext Len, 0, 0, Checksum
These are as specified in Section 5.3 of the Shim6 protocol
description [RFC5533].
Type
This field identifies the Keepalive message and MUST be set to 66
(Keepalive).
Reserved1
This is a 7-bit field reserved for future use. It is set to zero
on transmit and MUST be ignored on receipt.
R
This is a 1-bit field reserved for future use. It is set to zero
on transmit and MUST be ignored on receipt.
Receiver Context Tag
This is a 47-bit field for the context tag that the receiver has
allocated for the context.
Reserved2
This is a 32-bit field reserved for future use. It is set to zero
on transmit and MUST be ignored on receipt.
Options
This field MAY contain one or more Shim6 options. However, there
are currently no defined options that are useful in a Keepalive
message. The Options field is provided only for future
extensibility reasons.
A valid message conforms to the format above, has a Receiver Context
Tag that matches the context known by the receiver, is a valid Shim6
control message as defined in Section 12.3 of the Shim6 protocol
description [RFC5533], and has a Shim6 context that is in state
ESTABLISHED. The receiver processes a valid message by inspecting
its options and executing any actions specified for such options.
The processing rules for this message are given in more detail in
Section 6.
5.2. Probe Message
This message performs REAP exploration. Its format is as follows:
0 1 2 3
0 1 2 3 4 5 6 7 8 9 0 1 2 3 4 5 6 7 8 9 0 1 2 3 4 5 6 7 8 9 0 1
+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
| Next Header | Hdr Ext Len |0| Type = 67 | Reserved |0|
+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
| Checksum |R| |
+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+ |
| Receiver Context Tag |
+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
| Precvd| Psent |Sta| Reserved2 |
+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
| |
+ First probe sent +
| |
+ Source address +
| |
+ +
| |
+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
| |
+ First probe sent +
| |
+ Destination address +
| |
+ +
| |
+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
| First Probe Nonce |
+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
| First Probe Data |
+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
/ /
/ Nth probe sent /
| |
+ Source address +
| |
+ +
| |
+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
| |
+ Nth probe sent +
| |
+ Destination address +
| |
+ +
| |
+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
| Nth Probe Nonce |
+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
| Nth Probe Data |
+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
| |
+ First probe received +
| |
+ Source address +
| |
+ +
| |
+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
| |
+ First probe received +
| |
+ Destination address +
| |
+ +
| |
+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
| First Probe Nonce |
+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
| First Probe Data |
+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
| |
+ Nth probe received +
| |
+ Source address +
| |
+ +
| |
+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
| |
+ Nth probe received +
| |
+ Destination address +
| |
+ +
| |
+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
| Nth Probe Nonce |
+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
| Nth Probe Data |
+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
// Options //
+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
Next Header, Hdr Ext Len, 0, 0, Checksum
These are as specified in Section 5.3 of the Shim6 protocol
description [RFC5533].
Type
This field identifies the Probe message and MUST be set to 67
(Probe).
Reserved
This is a 7-bit field reserved for future use. It is set to zero
on transmit and MUST be ignored on receipt.
R
This is a 1-bit field reserved for future use. It is set to zero
on transmit and MUST be ignored on receipt.
Receiver Context Tag
This is a 47-bit field for the context tag that the receiver has
allocated for the context.
Psent
This is a 4-bit field that indicates the number of sent probes
included in this Probe message. The first set of Probe fields
pertains to the current message and MUST be present, so the
minimum value for this field is 1. Additional sent Probe fields
are copies of the same fields sent in (recent) earlier probes and
may be included or omitted as per any logic employed by the
implementation.
Precvd
This is a 4-bit field that indicates the number of received probes
included in this Probe message. Received Probe fields are copies
of the same fields in earlier received probes that arrived since
the last transition to state Exploring. When a sender is in state
InboundOk it MUST include copies of the fields of at least one of
the inbound probes. A sender MAY include additional sets of these
received Probe fields in any state as per any logic employed by
the implementation.
The fields Probe Source, Probe Destination, Probe Nonce, and Probe
Data may be repeated, depending on the value of Psent and
Preceived.
Sta (State)
This 2-bit State field is used to inform the peer about the state
of the sender. It has three legal values:
0 (Operational) implies that the sender both (a) believes it has
no problem communicating and (b) believes that the recipient also
has no problem communicating.
1 (Exploring) implies that the sender has a problem communicating
with the recipient, e.g., it has not seen any traffic from the
recipient even when it expected some.
2 (InboundOk) implies that the sender believes it has no problem
communicating, i.e., it at least sees packets from the recipient
but that the recipient either has a problem or has not yet
confirmed to the sender that the problem has been resolved.
Reserved2
MUST be set to zero upon transmission and MUST be ignored upon
reception.
Probe Source
This 128-bit field contains the source IPv6 address used to send
the probe.
Probe Destination
This 128-bit field contains the destination IPv6 address used to
send the probe.
Probe Nonce
This is a 32-bit field that is initialized by the sender with a
value that allows it to determine with which sent probes a
received probe correlates. It is highly RECOMMENDED that the
Nonce field be at least moderately hard to guess so that even on-
path attackers can't deduce the next nonce value that will be
used. This value SHOULD be generated using a random number
generator that is known to have good randomness properties as
outlined in RFC 4086 [RFC4086].
Probe Data
This is a 32-bit field with no fixed meaning. The Probe Data
field is copied back with no changes. Future flags may define a
use for this field.
Options
For future extensions.
5.3. Keepalive Timeout Option Format
Either side of a Shim6 context can notify the peer of the value that
it would prefer the peer to use as its Keepalive Timeout value. If
the node is using a non-default Send Timeout value, it MUST
communicate this value as a Keepalive Timeout value to the peer in
the below option. This option MAY be sent in the I2, I2bis, R2, or
UPDATE messages. The option SHOULD only need to be sent once in a
given Shim6 association. If a node receives this option, it SHOULD
update its Keepalive Timeout value for the peer.
0 1 2 3
0 1 2 3 4 5 6 7 8 9 0 1 2 3 4 5 6 7 8 9 0 1 2 3 4 5 6 7 8 9 0 1
+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
| Type = 10 |0| Length = 4 |
+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
+ Reserved | Keepalive Timeout |
+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
Fields:
Type
This field identifies the option and MUST be set to 10 (Keepalive
Timeout).
Length
This field MUST be set as specified in Section 5.1 of the Shim6
protocol description [RFC5533] -- that is, set to 4.
Reserved
A 16-bit field reserved for future use. It is set to zero upon
transmit and MUST be ignored upon receipt.
Keepalive Timeout
The value in seconds corresponding to the suggested Keepalive
Timeout value for the peer.
6. Behavior
The required behavior of REAP nodes is specified below in the form of
a state machine. The externally observable behavior of an
implementation MUST conform to this state machine, but there is no
requirement that the implementation actually employ a state machine.
Intermixed with the following description, we also provide a state
machine description in tabular form. However, that form is only
informational.
On a given context with a given peer, the node can be in one of three
states: Operational, Exploring, or InboundOK. In the Operational
state, the underlying address pairs are assumed to be operational.
In the Exploring state, this node hasn't seen any traffic from the
peer for more than a Send Timer period. Finally, in the InboundOK
state, this node sees traffic from the peer, but the peer may not yet
see any traffic from this node, so the exploration process needs to
continue.
The node also maintains the Send Timer (Send Timeout seconds) and
Keepalive Timer (Keepalive Timeout seconds). The Send Timer reflects
the requirement that when this node sends a payload packet, there
should be some return traffic (either payload packets or Keepalive
messages) within Send Timeout seconds. The Keepalive Timer reflects
the requirement that when this node receives a payload packet, there
should a similar response towards the peer. The Keepalive Timer is
only used within the Operational state, and the Send Timer within the
Operational and InboundOK states. No timer is running in the
Exploring state. As explained in Section 4.1, the two timers are
mutually exclusive. That is, either the Keepalive Timer or the Send
Timer is running, or neither of them is running.
Note that Appendix A gives some examples of typical protocol runs in
order to illustrate the behavior.
6.1. Incoming Payload Packet
Upon the reception of a payload packet in the Operational state, the
node starts the Keepalive Timer if it was not yet running, and stops
the Send Timer if it was running.
If the node is in the Exploring state, it transitions to the
InboundOK state, sends a Probe message, and starts the Send Timer.
It fills the Psent and corresponding Probe Source Address, Probe
Destination Address, Probe Nonce, and Probe Data fields with
information about recent Probe messages that have not yet been
reported as seen by the peer. It also fills the Precvd and
corresponding Probe Source Address, Probe Destination Address, Probe
Nonce, and Probe Data fields with information about recent Probe
messages it has seen from the peer. When sending a Probe message,
the State field MUST be set to a value that matches the conceptual
state of the sender after sending the Probe. In this case, the node
therefore sets the State field to 2 (InboundOk). The IP source and
destination addresses for sending the Probe message are selected as
discussed in Section 4.3.
In the InboundOK state, the node stops the Send Timer if it was
running, but does not do anything else.
The reception of Shim6 control messages other than the Keepalive and
Probe messages are treated the same as the reception of payload
packets.
While the Keepalive Timer is running, the node SHOULD send Keepalive
messages to the peer with an interval of Keepalive Interval seconds.
Conceptually, a separate timer is used to distinguish between the
interval between Keepalive messages and the overall Keepalive Timeout
interval. However, this separate timer is not modelled in the
tabular or graphical state machines. When sent, the Keepalive
message is constructed as described in Section 5.1. It is sent using
the current address pair.
In the below tables, "START", "RESTART", and "STOP" refer to
starting, restarting, and stopping the Keepalive Timer or the Send
Timer, respectively. "GOTO" refers to transitioning to another
state. "SEND" refers to sending a message, and "-" refers to taking
no action.
Operational Exploring InboundOk
--------------------------------------------------------------------
STOP Send SEND Probe InboundOk STOP Send
START Keepalive START Send
GOTO InboundOk
6.2. Outgoing Payload Packet
Upon sending a payload packet in the Operational state, the node
stops the Keepalive Timer if it was running and starts the Send Timer
if it was not running. In the Exploring state there is no effect,
and in the InboundOK state the node simply starts the Send Timer if
it was not yet running. (The sending of Shim6 control messages is
again treated the same.)
Operational Exploring InboundOk
------------------------------------------------------------------
START Send - START Send
STOP Keepalive
6.3. Keepalive Timeout
Upon a timeout on the Keepalive Timer, the node sends one last
Keepalive message. This can only happen in the Operational state.
The Keepalive message is constructed as described in Section 5.1. It
is sent using the current address pair.
Operational Exploring InboundOk
------------------------------------------------------------------
SEND Keepalive - -
6.4. Send Timeout
Upon a timeout on the Send Timer, the node enters the Exploring state
and sends a Probe message. The Probe message is constructed as
explained in Section 6.1, except that the State field is set to 1
(Exploring).
Operational Exploring InboundOk
------------------------------------------------------------------
SEND Probe Exploring - SEND Probe Exploring
GOTO Exploring GOTO Exploring
6.5. Retransmission
While in the Exploring state, the node keeps retransmitting its Probe
messages to different (or the same) addresses as defined in
Section 4.3. A similar process is employed in the InboundOk state,
except that upon such retransmission, the Send Timer is started if it
was not running already.
The Probe messages are constructed as explained in Section 6.1,
except that the State field is set to 1 (Exploring) or 2 (InboundOk),
depending on which state the sender is in.
Operational Exploring InboundOk
-----------------------------------------------------------------
- SEND Probe Exploring SEND Probe InboundOk
START Send
6.6. Reception of the Keepalive Message
Upon the reception of a Keepalive message in the Operational state,
the node stops the Send Timer if it was running. If the node is in
the Exploring state, it transitions to the InboundOK state, sends a
Probe message, and starts the Send Timer. The Probe message is
constructed as explained in Section 6.1.
In the InboundOK state, the Send Timer is stopped if it was running.
Operational Exploring InboundOk
------------------------------------------------------------------
STOP Send SEND Probe InboundOk STOP Send
START Send
GOTO InboundOk
6.7. Reception of the Probe Message State=Exploring
Upon receiving a Probe message with State set to Exploring, the node
enters the InboundOK state, sends a Probe message as described in
Section 6.1, stops the Keepalive Timer if it was running, and
restarts the Send Timer.
Operational Exploring InboundOk
------------------------------------------------------------------
SEND Probe InboundOk SEND Probe InboundOk SEND Probe InboundOk
STOP Keepalive START Send RESTART Send
RESTART Send GOTO InboundOk
GOTO InboundOk
6.8. Reception of the Probe Message State=InboundOk
Upon the reception of a Probe message with State set to InboundOk,
the node sends a Probe message, restarts the Send Timer, stops the
Keepalive Timer if it was running, and transitions to the Operational
state. A new current address pair is chosen for the connection,
based on the reports of received probes in the message that we just
received. If no received probes have been reported, the current
address pair is unchanged.
The Probe message is constructed as explained in Section 6.1, except
that the State field is set to zero (Operational).
Operational Exploring InboundOk
--------------------------------------------------------------------
SEND Probe Operational SEND Probe Operational SEND Probe Operational
RESTART Send RESTART Send RESTART Send
STOP Keepalive GOTO Operational GOTO Operational
6.9. Reception of the Probe Message State=Operational
Upon the reception of a Probe message with State set to Operational,
the node stops the Send Timer if it was running, starts the Keepalive
Timer if it was not yet running, and transitions to the Operational
state. The Probe message is constructed as explained in Section 6.1,
except that the State field is set to zero (Operational).
Note: This terminates the exploration process when both parties
are happy and know that their peer is happy as well.
Operational Exploring InboundOk
------------------------------------------------------------------
STOP Send STOP Send STOP Send
START Keepalive START Keepalive START Keepalive
GOTO Operational GOTO Operational
The reachability detection and exploration process has no effect on
payload communications until a new operational address pair has
actually been confirmed. Prior to that, the payload packets continue
to be sent to the previously used addresses.
6.10. Graphical Representation of the State Machine
In the PDF version of this specification, an informational drawing
illustrates the state machine. Where the text and the drawing
differ, the text takes precedence.
7. Protocol Constants and Variables
The following protocol constants are defined:
Initial Probe Timeout 0.5 seconds
Number of Initial Probes 4 probes
And these variables have the following default values:
Send Timeout 15 seconds
Keepalive Timeout X seconds, where X is the peer's
Send Timeout as communicated in
the Keepalive Timeout Option
15 seconds if the peer didn't send
a Keepalive Timeout option
Keepalive Interval Y seconds, where Y is one-third to
one-half of the Keepalive Timeout
value (see Section 4.1)
Alternate values of the Send Timeout may be selected by a node and
communicated to the peer in the Keepalive Timeout Option. A very
small value of the Send Timeout may affect the ability to exchange
keepalives over a path that has a long roundtrip delay. Similarly,
it may cause Shim6 to react to temporary failures more often than
necessary. As a result, it is RECOMMENDED that an alternate Send
Timeout value not be under 10 seconds. Choosing a higher value than
the one recommended above is also possible, but there is a
relationship between Send Timeout and the ability of REAP to discover
and correct errors in the communication path. In any case, in order
for Shim6 to be useful, it should detect and repair communication
problems long before upper layers give up. For this reason, it is
RECOMMENDED that Send Timeout be at most 100 seconds (default TCP R2
timeout [RFC1122]).
Note: It is not expected that the Send Timeout or other values
will be estimated based on experienced roundtrip times. Signaling
exchanges are performed based on exponential back-off. The
keepalive processes send packets only in the relatively rare
condition that all traffic is unidirectional.
8. Security Considerations
Attackers may spoof various indications from lower layers and from
the network in an effort to confuse the peers about which addresses
are or are not operational. For example, attackers may spoof ICMP
error messages in an effort to cause the parties to move their
traffic elsewhere or even to disconnect. Attackers may also spoof
information related to network attachments, Router Discovery, and
address assignments in an effort to make the parties believe they
have Internet connectivity when in reality they do not.
This may cause use of non-preferred addresses or even denial of
service.
This protocol does not provide any protection of its own for
indications from other parts of the protocol stack. Unprotected
indications SHOULD NOT be taken as a proof of connectivity problems.
However, REAP has weak resistance against incorrect information even
from unprotected indications in the sense that it performs its own
tests prior to picking a new address pair. Denial-of-service
vulnerabilities remain, however, as do vulnerabilities against on-
path attackers.
Some aspects of these vulnerabilities can be mitigated through the
use of techniques specific to the other parts of the stack, such as
properly dealing with ICMP errors [GONT], link-layer security, or the
use of SEND [RFC3971] to protect IPv6 Router and Neighbor Discovery.
Other parts of the Shim6 protocol ensure that the set of addresses we
are switching between actually belong together. REAP itself provides
no such assurances. Similarly, REAP provides some protection against
third-party flooding attacks [AURA02]; when REAP is run, its Probe
Nonces can be used as a return routability check that the claimed
address is indeed willing to receive traffic. However, this needs to
be complemented with another mechanism to ensure that the claimed
address is also the correct node. Shim6 does this by performing
binding of all operations to context tags.
The keepalive mechanism in this specification is vulnerable to
spoofing. On-path attackers that can see a Shim6 context tag can
send spoofed Keepalive messages once per Send Timeout interval in
order to prevent two Shim6 nodes from sending Keepalives themselves.
This vulnerability is only relevant to nodes involved in a one-way
communication. The result of the attack is that the nodes enter the
exploration phase needlessly, but they should be able to confirm
connectivity unless, of course, the attacker is able to prevent the
exploration phase from completing. Off-path attackers may not be
able to generate spoofed results, given that the context tags are 47-
bit random numbers.
To protect against spoofed Keepalive messages, a node implementing
both Shim6 and IPsec MAY ignore incoming REAP keepalives if it has
good reason to assume that the other side will be sending IPsec-
protected return traffic. In other words, if a node is sending TCP
payload data, it can reasonably expect to receive TCP ACKs in return.
If no IPsec-protected ACKs come back but unprotected keepalives do,
this could be the result of an attacker trying to hide broken
connectivity.
The exploration phase is vulnerable to attackers that are on the
path. Off-path attackers would find it hard to guess either the
context tag or the correct probe identifiers. Given that IPsec
operates above the Shim6 layer, it is not possible to protect the
exploration phase against on-path attackers with IPsec. This is
similar to the issues with protecting other Shim6 control exchanges.
There are mechanisms in place to prevent the redirection of
communications to wrong addresses, but on-path attackers can cause
denial-of-service, move communications to less-preferred address
pairs, and so on.
Finally, the exploration itself can cause a number of packets to be
sent. As a result, it may be used as a tool for packet amplification
in flooding attacks. It is required that the protocol employing REAP
has built-in mechanisms to prevent this. For instance, Shim6
contexts are created only after a relatively large number of packets
have been exchanged, a cost that reduces the attractiveness of using
Shim6 and REAP for amplification attacks. However, such protections
are typically not present at connection-establishment time. When
exploration would be needed for connection establishment to succeed,
its usage would result in an amplification vulnerability. As a
result, Shim6 does not support the use of REAP in the connection-
establishment stage.
9. Operational Considerations
When there are no failures, the failure-detection mechanism (and
Shim6 in general) are lightweight: keepalives are not sent when a
Shim6 context is idle or when there is traffic in both directions.
So in normal TCP or TCP-like operations, there would only be one or
two keepalives when a session transitions from active to idle.
Only when there are failures is there significant failure-detection
traffic, especially in the case where a link goes down that is shared
by many active sessions and by multiple nodes. When this happens,
one keepalive is sent and then a series of probes. This happens per
active (traffic-generating) context, all of which will time out
within 15 seconds after the failure. This makes the peak traffic
that Shim6 generates after a failure around one packet per second per
context. Presumably, the sessions that run over those contexts were
sending at least that much traffic and most likely more, but if the
backup path is significantly lower bandwidth than the failed path,
this could lead to temporary congestion.
However, note that in the case of multihoming using BGP, if the
failover is fast enough that TCP doesn't go into slow start, the
full payload data traffic that flows over the failed path is
switched over to the backup path, and if this backup path is of a
lower capacity, there will be even more congestion.
Although the failure detection probing does not perform congestion
control as such, the exponential back-off makes sure that the number
of packets sent quickly goes down and eventually reaches one per
context per minute, which should be sufficiently conservative even on
the lowest bandwidth links.
Section 7 specifies a number of protocol parameters. Possible tuning
of these parameters and others that are not mandated in this
specification may affect these properties. It is expected that
further revisions of this specification provide additional
information after sufficient deployment experience has been obtained
from different environments.
Implementations may provide means to monitor their performance and
send alarms about problems. Their standardization is, however, the
subject of future specifications. In general, Shim6 is most
applicable for small sites and nodes, and it is expected that
monitoring requirements on such deployments are relatively modest.
In any case, where the node is associated with a management system,
it is RECOMMENDED that detected failures and failover events are
reported via asynchronous notifications to the management system.
Similarly, where logging mechanisms are available on the node, these
events should be recorded in event logs.
Shim6 uses the same header for both signaling and the encapsulation
of payload packets after a rehoming event. This way, fate is shared
between the two types of packets, so the situation where reachability
probes or keepalives can be transmitted successfully but payload
packets cannot, is largely avoided: either all Shim6 packets make it
through, so Shim6 functions as intended, or none do, and no Shim6
state is negotiated. Even in the situation where some packets make
it through and others do not, Shim6 will generally either work as
intended or provide a service that is no worse than in the absence of
Shim6, apart from the possible generation of a small amount of
signaling traffic.
Sometimes payload packets (and possibly payload packets encapsulated
in the Shim6 header) do not make it through, but signaling and
keepalives do. This situation can occur when there is a path MTU
discovery black hole on one of the paths. If only large packets are
sent at some point, then reachability exploration will be turned on
and REAP will likely select another path, which may or may not be
affected by the PMTUD black hole.
10. References
10.1. Normative References
[RFC2119] Bradner, S., "Key words for use in RFCs to Indicate
Requirement Levels", BCP 14, RFC 2119, March 1997.
[RFC3315] Droms, R., Bound, J., Volz, B., Lemon, T., Perkins, C.,
and M. Carney, "Dynamic Host Configuration Protocol for
IPv6 (DHCPv6)", RFC 3315, July 2003.
[RFC3484] Draves, R., "Default Address Selection for Internet
Protocol version 6 (IPv6)", RFC 3484, February 2003.
[RFC4086] Eastlake, D., Schiller, J., and S. Crocker, "Randomness
Requirements for Security", BCP 106, RFC 4086, June 2005.
[RFC4193] Hinden, R. and B. Haberman, "Unique Local IPv6 Unicast
Addresses", RFC 4193, October 2005.
[RFC4429] Moore, N., "Optimistic Duplicate Address Detection (DAD)
for IPv6", RFC 4429, April 2006.
[RFC4861] Narten, T., Nordmark, E., Simpson, W., and H. Soliman,
"Neighbor Discovery for IP version 6 (IPv6)", RFC 4861,
September 2007.
[RFC4862] Thomson, S., Narten, T., and T. Jinmei, "IPv6 Stateless
Address Autoconfiguration", RFC 4862, September 2007.
[RFC5533] Nordmark, E. and M. Bagnulo, "Shim6: Level 3 Multihoming
Shim Protocol for IPv6", RFC 5533, June 2009.
10.2. Informative References
[ADD-SEL] Bagnulo, M., "Address selection in multihomed
environments", Work in Progress, October 2005.
[AURA02] Aura, T., Roe, M., and J. Arkko, "Security of Internet
Location Management", Proceedings of the 18th Annual
Computer Security Applications Conference, Las Vegas,
Nevada, USA, December 2002.
[BFD] Katz, D. and D. Ward, "Bidirectional Forwarding
Detection", Work in Progress, February 2009.
[DNA-SIM] Krishnan, S. and G. Daley, "Simple procedures for
Detecting Network Attachment in IPv6", Work in Progress,
February 2009.
[GONT] Gont, F., "ICMP attacks against TCP", Work in Progress,
October 2008.
[MULTI6] Huitema, C., "Address selection in multihomed
environments", Work in Progress, October 2004.
[PAIR] Bagnulo, M., "Default Locator-pair selection algorithm for
the Shim6 protocol", Work in Progress, October 2008.
[RFC1122] Braden, R., "Requirements for Internet Hosts -
Communication Layers", STD 3, RFC 1122, October 1989.
[RFC3971] Arkko, J., Kempf, J., Zill, B., and P. Nikander, "SEcure
Neighbor Discovery (SEND)", RFC 3971, March 2005.
[RFC4960] Stewart, R., "Stream Control Transmission Protocol",
RFC 4960, September 2007.
[RFC5206] Nikander, P., Henderson, T., Vogt, C., and J. Arkko, "End-
Host Mobility and Multihoming with the Host Identity
Protocol", RFC 5206, April 2008.
Appendix A. Example Protocol Runs
This appendix has examples of REAP protocol runs in typical
scenarios. We start with the simplest scenario of two nodes, A and
B, that have a Shim6 connection with each other but are not currently
sending any payload data. As neither side sends anything, they also
do not expect anything back, so there are no messages at all:
EXAMPLE 1: No Communications
Peer A Peer B
| |
| |
| |
| |
| |
| |
| |
| |
Our second example involves an active connection with bidirectional
payload packet flows. Here, the reception of payload data from the
peer is taken as an indication of reachability, so again there are no
extra packets:
EXAMPLE 2: Bidirectional Communications
Peer A Peer B
| |
| payload packet |
|-------------------------------------------->|
| |
| payload packet |
|<--------------------------------------------|
| |
| payload packet |
|-------------------------------------------->|
| |
| |
The third example is the first one that involves an actual REAP
message. Here, the nodes communicate in just one direction, so REAP
messages are needed to indicate to the peer that sends payload
packets that its packets are getting through:
EXAMPLE 3: Unidirectional Communications
Peer A Peer B
| |
| payload packet |
|-------------------------------------------->|
| |
| payload packet |
|-------------------------------------------->|
| |
| payload packet |
|-------------------------------------------->|
| |
| Keepalive Nonce=p |
|<--------------------------------------------|
| |
| payload packet |
|-------------------------------------------->|
| |
| |
The next example involves a failure scenario. Here, A has address A,
and B has addresses B1 and B2. The currently used address pairs are
(A, B1) and (B1, A). All connections via B1 become broken, which
leads to an exploration process:
EXAMPLE 4: Failure Scenario
Peer A Peer B
| |
State: | State:
Operational | Operational
| (A,B1) payload packet |
|-------------------------------------------->|
| |
| (B1,A) payload packet |
|<--------------------------------------------| At time T1
| | path A<->B1
| (A,B1) payload packet | becomes
|----------------------------------------/ | broken.
| |
| ( B1,A) payload packet |
| /-----------------------------------------|
| |
| (A,B1) payload packet |
|----------------------------------------/ |
| |
| (B1,A) payload packet |
| /-----------------------------------------|
| |
| (A,B1) payload packet |
|----------------------------------------/ |
| |
| | Send Timeout
| | seconds after
| | T1, B happens to
| | see the problem
| (B1,A) Probe Nonce=p, | first and sends a
| state=exploring | complaint that
| /-----------------------------------------| it is not
| | receiving
| | anything.
| | State:
| | Exploring
| |
| (B2,A) Probe Nonce=q, |
| state=exploring | But it's lost,
|<--------------------------------------------| retransmission
| | uses another pair
A realizes |
that it needs |
to start the |
exploration. |
It picks B2 as the |
most likely candidate, |
as it appeared in the |
Probe. |
State: InboundOk |
| |
| (A, B2) Probe Nonce=r, |
| state=inboundok, |
| received probe q | This one gets
|-------------------------------------------->| through.
| | State:
| | Operational
| (B2,A) Probe Nonce=s, |
| state=operational, | B now knows
| received probe r | that A has no
|<--------------------------------------------| problem receiving
| | its packets.
State: Operational |
| |
| (A,B2) payload packet |
|-------------------------------------------->| Payload packets
| | flow again.
| (B2,A) payload packet |
|<--------------------------------------------|
The next example shows when the failure for the current locator pair
is in the other direction only. A has addresses A1 and A2, and B has
addresses B1 and B2. The current communication is between A1 and B1,
but A's packets no longer reach B using this pair.
EXAMPLE 5: One-Way Failure
Peer A Peer B
| |
State: | State:
Operational | Operational
| |
| (A1,B1) payload packet |
|-------------------------------------------->|
| |
| (B1,A1) payload packet |
|<--------------------------------------------|
| |
| (A1,B1) payload packet | At time T1
|----------------------------------------/ | path A1->B1
| | becomes
| | broken.
| (B1,A1) payload packet |
|<--------------------------------------------|
| |
| (A1,B1) payload packet |
|----------------------------------------/ |
| |
| (B1,A1) payload packet |
|<--------------------------------------------|
| |
| (A1,B1) payload packet |
|----------------------------------------/ |
| |
| | Send Timeout
| | seconds after
| | T1, B notices
| | the problem and
| (B1,A1) Probe Nonce=p, | sends a
| state=exploring | complaint that
|<--------------------------------------------| it is not
| | receiving
| | anything.
A responds. | State: Exploring
State: InboundOk |
| |
| (A1, B1) Probe Nonce=q, |
| state=inboundok, |
| received probe p |
|----------------------------------------/ | A's response
| | is lost.
| (B2,A2) Probe Nonce=r, |
| state=exploring | Next, try a different
|<--------------------------------------------| locator pair.
| |
| (A2, B2) Probe Nonce=s, |
| state=inboundok, |
| received probes p, r | This one gets
|-------------------------------------------->| through.
| | State: Operational
| |
| | B now knows
| | that A has no
| (B2,A2) Probe Nonce=t, | problem receiving
| state=operational, | its packets and
| received probe s | that A's probe
|<--------------------------------------------| gets to B. It
| | sends a
State: Operational | confirmation to A.
| |
| (A2,B2) payload packet |
|-------------------------------------------->| Payload packets
| | flow again.
| (B1,A1) payload packet |
|<--------------------------------------------|
Appendix B. Contributors
This document attempts to summarize the thoughts and unpublished
contributions of many people, including MULTI6 WG design team members
Marcelo Bagnulo Braun, Erik Nordmark, Geoff Huston, Kurtis Lindqvist,
Margaret Wasserman, and Jukka Ylitalo; MOBIKE WG contributors Pasi
Eronen, Tero Kivinen, Francis Dupont, Spencer Dawkins, and James
Kempf; and HIP WG contributors such as Pekka Nikander. This document
is also in debt to work done in the context of SCTP [RFC4960] and the
Host Identity Protocol (HIP) multihoming and mobility extension
[RFC5206].
Appendix C. Acknowledgements
The authors would also like to thank Christian Huitema, Pekka Savola,
John Loughney, Sam Xia, Hannes Tschofenig, Sebastien Barre, Thomas
Henderson, Matthijs Mekking, Deguang Le, Eric Gray, Dan Romascanu,
Stephen Kent, Alberto Garcia, Bernard Aboba, Lars Eggert, Dave Ward,
and Tim Polk for interesting discussions in this problem space, and
for review of this specification.
Authors' Addresses
Jari Arkko
Ericsson
Jorvas 02420
Finland
EMail: jari.arkko@ericsson.com
Iljitsch van Beijnum
IMDEA Networks
Avda. del Mar Mediterraneo, 22
Leganes, Madrid 28918
Spain
EMail: iljitsch@muada.com