DHCPv6 Route OptionsCisco SystemsHaarlerbergweg 13-191101 CH AmsterdamThe Netherlandswdec@cisco.comInternet Systems Consortium, Inc.
950 Charter StreetRedwood CityCA94063USA+1 650 423 1345tomasz.mrugalski@gmail.comChina MobileUnit2, 28 Xuanwumenxi AveBeijingXuanwu District100053Chinasuntao@chinamobile.comHuawei USA1700 Alma Dr. Suite 500PlanoTX75075United States+1 972-509-5599sarikaya@ieee.orgThis document describes DHCPv6 Route Options for provisioning IPv6
routes on DHCPv6 client nodes. This is expected to improve the ability
of an operator to configure and influence a nodes' ability to pick an
appropriate route to a destination when this node is multi-homed and
where other means of route configuration may be impractical.The key words "MUST", "MUST NOT", "REQUIRED", "SHALL", "SHALL NOT",
"SHOULD", "SHOULD NOT", "RECOMMENDED", "MAY", and "OPTIONAL" in this
document are to be interpreted as described in RFC 2119.The Neighbor Discovery (ND) protocol provides a mechanism for hosts to discover one
or more default routers on a directly connected network segment.
Extensions to the Router Advertisement (RA) protocol defined in allow hosts to discover the preferences for
multiple default routers on a given link, as well as any specific routes
advertised by these routers. This provides network administrators with a new
set of tools handle multi-homed host topologies and influence the route
selection by the host. This ND based mechanism however is sub optimal or
impractical in some multi-homing scenarios, where DHCPv6 is seen to be more viable.This draft defines the DHCPv6 Route Options for provisioning IPv6
routes on DHCPv6 clients. The proposed option is primarily envisaged for
use by DHCPv6 client nodes that are capable of making basic IP routing
decisions and maintaining an IPv6 routing table, broadly in line with
the capabilities of a generic host as described in .Throughout the document the words node and client are used as a
reference to the device with such routing capabilities, hosting the
DHCPv6 client software. The route information is taken to be equivalent
to static routing, and limited in the number of required routes to a
handful.The solution described in this document applies to multi-homed
scenarios including ones where the client is simultaneously connected to
multiple access network (e.g. WiFi and 3G). The following scenario is
used to illustrate the problem as found in typical multi-homed
residential access networks. It is duly noted that the problem is not
specific to IPv6, occurring also with IPv4, where it is today solved by
means of DHCPv4 classless route information option , or alternative configuration mechanisms.In multi-homed networks, a given user's node may be connected to more
than one gateway. Such connectivity may be realized by means of
dedicated physical or logical links that may also be shared with other
users nodes. In such multi-homed networks it is quite common for the
network operator to offer the delivery of a particular type of IP
service via a particular gateway, where the service can be characterised
by means of specific destination IP network prefixes. Thus, from an IP
routing perspective in order for the user node to select the appropriate
gateway for a given destination IP prefix, recourse needs to be made to
classic longest destination match IP routing, with the node acquiring
such prefixes into its routing table. This is typically the remit of
dynamic Internal Gateway Protocols (IGPs), which however are rarely used
by operators in residential access networks. This is primarily due to
operational costs and a desire to contain the complexity of user nodes
and IP Edge devices to a minimum. While, IP Route configuration may be
achieved using the ICMPv6 extensions defined in , this mechanism does not lend itself to other
operational constraints such as the desire to control the route
information on a per node basis, the ability to determine whether a
given node is actually capable of receiveing/processing such route
information. A preferred mechanism, and one that additionally also lends
itself to centralized management independent of the management of the
gateways, is that of using the DHCP protocol for conveying route
information to the nodes.The following section enumerates use cases, both in
existing networks and as well as in evisaged future
deployments. Usage scenarios are specified here in no
particular order. As those use cases are descibed by various
network operators, their scenarios may partially overlap.Discussion: this section is rather long. Nevertheless,
there were concerns raised that such option is not
needed. Such extensive list can possible solve those
concerns.Number of use cases should be limited in future
revisions. Alternatively, they can be moved to a separate
motivation draft, if needed.Use case 1: In Broadband network environment where the CPE
is multi-homed to two upstream edge routers and each router
provides connectivity for different types of services for
example internet access and Video on Demand (restricted inside
a walled garden) and the Service Provide would like to avoid
routing on the CPE, there is a need to provision static route
entries on RGs/CPEs. Service Provider requires a centralized
control/management point for storing the customer's related
innformation (IPv6 prefix, IPv6 routes and other provisioned
information) and DHCPv6 is a good place for that. Using RA's
would require to manually provision the edge router and this
operation is not always possible, for example when router is
operated by 3rd party. Broadband Forum document WT-124 issue 3
calls for this draft to solve the
problem.Use case 2: Operators want (approximate) feature parity so
that they can have (approximate) alignment between their
operational procedures for v4 and v6, especially in a dual
stack network. Having similar mechanisms for both protocols is
desired due to lower operational expenses (OPEX).Use case 3: In cellular networks, it is efficient for the
network to configure routing information in central DHCPv6
server to do unified routing policy information. The gateways
(GGSN in cellular network) only need to perform DHCPv6 relay.
The Option code sent by clients can be used as an indication
that host is MIF capable, so that network need not to do such
configuration to host without MIF capabilities.Use case 4: In cellular network, DHCPv6 is used for IPv6
parameter configuration and RA is used for SLACC of
handset. This behavior was introduced in 3GPP Release 8 (or
earlier). The network gateway in cellular network (e.g., GGSN)
can naturally support DHCPv6 extension since the gateway acts
as a DHCPv6 relay. However, it is very hard to update those
gateways to use RA announcing the route information. The
handsets with MIF feature need to visit subscribed/operator
provided service. Some traffic is routed to the operator's
network through 3G interface instead of to Internet through
WiFi. DHCPv6 will be used to configure these specific routes.
This use case is described in .Use case 5: PMIPv6 use case in LTE network. In LTE
cellular network, both GTP and PMIPv6 are used for mobility
management. In GTP, it is a point-to-point link between mobile
host and PGW (PDN Gateway). However, in PMIPv6 case, the
point-to-point link is between mobile host and SGW(Serving
Gateway). The PGW sends /64 prefix to SGW through PBA. The SGW
sends RA to mobile host. Route option may be needed when the
host is multi-homed if it is simultaneously connected to the
cellular network and WiFi or it simultaneously connects to
multiple APNs in the cellular network. If RA is used for route
configuration, both PGW and SGW(whose number is larger than
PGW) need to be updated. Moreover, since a host can only
connect to one SGW at a time, the SGW have to keep multiple
route information received from different PGWs for one host
and send them by RA to the host separately. This makes RA is
not favorable in this use case.Use case 6: WiFi networks. Some WiFi hotspots provide local
services ("walled garden"). The route configuration on hosts
or RGs is needed to direct some traffic to local network,
while other traffic to the Internet. While this can be
achieved using Route Information Option (RIO) in RA for all
nodes that support , it does not allow
doing so on a per-host basis.Use case 7: VPN network. When a user connects to enterprise
VPN network, the routing of VPN traffic need to be
configured. Due to the large number of such VPN networks, we
cannot assume all the VPN network only use RA. DHCPv6 provides
another choice which may be preferred by the VPN network. This
situation is described in , Section 5.2.
Hosts that do not support RFC4191 will not operate properly.
Use case 8: Selective walled garden. illustrates the case of two clients
connected to a shared link. Both clients are assumed to have
global IPv6 addresses and obtain their Internet
connectivity via Router2 by means of a configured or a
discovered default route. Client 1 however, unlike Client 2,
is intended to run a specific application, e.g. VoIP, that is
meant to access ServerA by means of Router1 with Server A
being otherwise not reachable from the Internet. In addition
to the global IP address Client1 may be assigned with another
IP address of a more restricted scope for the purpose of
communicating with Server A.The problem in the above scenario comes down to the fact
that in order to reach Server A, Client1 requires to use a
more specific route whose next-hop address is Router1. An
ICMPv6 based mechanism for disseminating more specific route
information, as defined in ,
disseminates this information via the shared link also to
Client2. Often the operator wants to avoid this redundant
dissemination to passing to Client2. In addition many
operators prefer to be able to manage specific client route
information from a centralized repository instead of managing
directly such configuration on a router, as is required with
the ICMPv6 based scheme. The former requirement is driven by
the desire to provide to each client only the information
required for their intended role which may be tied to a
specific service, as well as to allow the possibility to
introduce other routers into the scenario for purposes of load
sharing. The requirement for more centralized configuration
management is often due to administrative boundaries within an
operator's organization as well as an existing operational
practice that are in place for IPv4, all of which make router
based configuration difficult.Use case 9: Multihoming problem. A multihomed IPv6 host or
gateway needs to solve at least 3 problems to operate properly
when more than one link is operational:
Source address selectionNext-hop selectionDNS server selectionProblems one and three are solved by and , respectively.
It should be noted that both mechanisms use DHCPv6 as well.
This draft attempts to solve problem two. Below is a brief
explanation of the problem. See draft
for detailed problem analysis, background information and
additional discussion regarding the need for a DHCPv6 solution
to route information problem and IPv6 multihoming in general
(with focus on aforementioned 3 problems).In multihoming environment, server can restrict assignment
of additional prefixes only to hosts that support more
advanced next-hop and address selection requirements. (See
Section 5.2 of ).
Obviously this MUST be done on a per-host basis. Information
about node capability is obtained via Option Request Option
(ORO) in Solicit message, so support for Route Options is also
used as means to report node capabilities to a network.Use case 10: In static networks (i.e. networks that have
static routers that are not changing over time, like home
network with), such as some enterprise, hosting provider
networks or even home network with a single router, it may be
possible to stop using RA mechanism and deliver all
configuration parameters to hosts using DHCPv6 only. This
approach solves the rogue RA problem (i.e. a node that is not
an approved router starts announcing RA in a network may
hijack traffic from other hosts). This approach may be
appealing in some cases, but not in all. For example if there
is security association shared between clients and a DHCPv6
server, it may be useful to trust DHCP and disable RA
mechanism. Also, environments that need DHCP for extended
information, including but not limited to communicating
information like DNS servers, hostnames, NTP servers, TFTP
boot information and so on are forced to run two protocols
increasing complexity and troubleshooting, where we have proof
of concept in IPv4 that only one protocol (DHCP) should be
needed.Use case 11: It also has been proposed that route
information option may be used as tie breaker in networks that
deploy both DHCPv6 route option and RA. DHCPv6 server could
announce routing information along with RA. Legitimate router
is also announced over DHCPv6. Host that receives conflicting
information over RA may use additional information received
from DHCPv6 as a tie breaker. This proposal was not investigated further.Use case 12: DHCP-based configuration provides different
failure mode than RA. While RA-based configuration works
better in networks that offer redundant uplink using separate
routers (second router can quickly take over upstream
traffic), there are many deployments that cannot use that
advantage, because of a single uplink. Current home networks
with a single uplink as most obvious example. On the other
hand, RA is more severly impacted by rogue entity problem.
New rogue RA device may instantly break all other devices on
the network. New rogue DHCP server will cause no immediate
harm, may cause slow breakage over time, and may in fact never
cause any breakage. This is due to the funamental design
choices of each protocol and it is hard to make either work the
other way.Use case 13: DHCP-based configuration may use mostly
unicast traffic, while RA-based configuration mostly uses
multicast. In some environments implementing multicast traffic
may be cumbersome, e.g. in WiMAX environment not every
subscriber station (SS) supports multicast channels and
multicast capability must be emulated by base station (BS)
using redundant transmissions. Classic, stateless, multicasted
RA is in disadvantage compared to DHCP with standard unicast
option enabled. While it is possible to selectively send
unicasted RAs to selected subscribers, such architecture
is essentially a stateful RA, thus forfeiting major benefit
of RA being stateless.Use case 14: Separated networks. In networks that do not
have any routers, two DHCPv6 clients get a global address from
DHCPv6 server. They cannot ping each other due to the fact
that they do not know prefix that is available on-link. While
it is tempting to suggest that separated networks should use
link-local addressing, other factors should be taken into
consideration. A stateful DHCPv6 may be used as a node
monitoring tool, thus having avantage over link-local address
usage. The also may be sensor networks that have outside
connectivity only sporadically, e.g. uplink is established
periodically to gather readings, but most of the time router
is powered down for power reasons. Route Option in DHCPv6
could be used to configure on-link routes, while router could
announce itself using short-lived RA.Those requirements and use cases can be summarized as following:
In view of the DHCPv6 requirements in several fields,
vendor-specific options lead to several segmented
definitions. An IETF defined general option is a better
choice.Per user/host configuration makes DHCPv6 be used for the
on-demand configuration.As there is no well-defined central management system for
prefix delegation and routing options va RA, it seems that
DHCPv6 is the only available solution. It is better to have
a generic option then a bunch of competing vendor
options.While this work was initially started with multihoming in
mind, it is useful for single interface devices as well.In a sense this route configuration mechanism makes DHCPv6
complete. Without it, this protocol cannot fully provision all
configuration parameters to a host on its own.Opponents of this option proposed several alternative
approaches. This section attempts to address raised issues.
Claim: During discussion about route configuration, some
opponents say that routing information should be defined as
vendor specific option.Response: There are many ISPs, cellular and BBF network
operators, CPE vendors, hardware vendors, DHCP implementors
that want to implement and deploy this mechanism. Using
vendor-specific option would severly limit interoperability
and would make adoption and deployment much more
complicated.This solution is not a technology-specific requirement, it
is requested by wide variety of companies, so it is not a
vendor specific.Claim: Some proponents insist that instead of using DHCPv6
solution, RA should be used instead. Some propose to send
unicast RA with RIO option on a per-host basis.Response: While this approach technically does not violate
existing specs, it uses RA in a stateful way, thus the benefit
of RA being stateless is lost. Furthermore, it would require
deploying additional mechanism, like RADIUS to deliver
necessary information about hosts to routers. Authors consider
deploying such stateful RA server with RADIUS support more
complicated to deploy than the solution it tries to avoid
(DHCPv6).As there is no well-defined central management system for
prefix delegation and routing options va RA, it seems that
DHCPv6 is the only available solution. It is better to have
a generic option than a bunch of competing vendor
options.Another concern raised is that RIO is not menadatory nor
optional in 3GPP system and there is currently not support in
29.061 RADIUS or Diameter profile, so use of that alternative
is somewhat limited in some cases.Claim: DHCPv6 has less rich semantics as client has to pick
one out of all available server.Response: While that is how currently most clients are
implemented, there is nothing in that
mandates that. It is true that DHCPv6 was not designed with
several provisioning domains. On the contrary, section 17.1.3
states that "Upon receipt of one or more valid Advertise
messages, the client selects one or more Advertise messages
based upon the following criteria.". This means that DHCPv6
client can obtain parameters from all available DHCPv6
servers, not just selected one. As such, DHCPv6 may work with
overlapping provisioning domains. Authors acknowledge that
this possibility is currently rather theoretical, as most
known implementations do not take advantage of that
possibility.Claim: There was a proposal to use VLANs as a solution to
lack of per-host capability in RA mechanism.Response: Deploying VLANs complicates network topology much
more than adding a single DHCPv6 option. Furthermore in many
cases it is not possible to deploy VLANs in any reasonable
way, e.g. in multihost environment. Also, low cost devices
(e.g. CPE) often do not offer VLAN capabilities, but they are
very much capable of supporting DHCPv6. Another objection of
estetic nature. Using layer 2 mechanisms to work around
limitations in layer 3 is not elegant.A DHCPv6 based solution allows an operator an on demand and
node specific means of configuring static routing
information. Such a solution also fits into network environments
where the operator prefers to manage Residential Gateway (RG)
configuration information from a centralized DHCP server. provides
additional background to the need for a DHCPv6 solution to the
problem.In terms of the high level operation of the solution defined in this
draft, a DHCPv6 client interested in obtaining routing information
request the route options using the DHCPv6 Option Request Option (ORO)
sent to a server. A Server, when configured to do so, provides the
requested route information as part of a nested options structure
covering; the next-hop address; the destination prefix; the route
metric; any additional options applicable to the destination or
next-hop.Defined mechanism may be used to configure default
route. Default route is configured using
RT_PREFIX option that specifies ::/0 route, included as
suboption in NEXT_HOP. Server MUST NOT define more than one default route.Server may also configure on-link routes, i.e. routes that
are available directly over the link, not via routers. To
specify on-link routes, server MAY include RTPREFIX option
directly in Advertise and Reply messages.There are two mechanisms that allow removing a route. Each
defined route has a route lifetime. If specific route
is not refreshed and its timer reaches 0, client MUST remove
corresponding entry from routing table.In cases, where faster route removal is needed, server
SHOULD return RT_PREFIX option with route lifetime set to
0. Client that receives RT_PREFIX with route lifetime set to 0
MUST remove specified route immediately, even if its previous
lifetime did not expire yet.Contrary to Router Adverisement mechanism, defined in that explicitly limits configuration to
hosts, routing configuration over DHCPv6 defined in this
document may be used by both hosts and routers. (This
limitation of RA mechanism was partially lifted by W-1
requirement formulated in .)One of the envisaged usages for this solution are
residential gateways (RG) or Customer Premises Equipment
(CPE). Those devices very often perform routing. It may be
useful to configure routing on such devices over DHCPv6. One
example of such use may be a class of premium users that are
allowed to use dedicated router that is not available to
regular users.Network configuration occassionally changes, due to failure
of existing hardware, migration to newer equipment or many
other reasons. Therefore there a way to inform clients that
routing information have changed is required.There are several ways to inform clients about new routing
information. Every client SHOULD periodically refresh its
configuration, according to Information Refresh Time Option,
so server may send updated information the next time client
refreshes its information. New routes may be configured at
that time. As every route has associated lifetime, client is
required to remove its routes when this timer expires. This
method is particularly useful, when migrating to new router is
undergoing, but old router is still available.Server MAY also announce routes via soon to be removed
router with lifetimes set to 0. This will cause the client to
remove its routes, despite the fact that previously received
lifetime may not yet expire.Aforementioned methods are useful, when there is no urgent
need to update routing information. Bound by timer set by
value of Information Refresh Time Option, clients may use
outdated routing information until next scheduled
renewal. Depending on configured value this delay may be not
acceptable in some cases. In such scenarios, administrators
are advised to use RECONFIGURE mechanism, defined in . Server transmits RECONFIRGURE message to
each client, thus forcing it to immediately start renewal
process.See also about limitations regarding
dynamic routing.Defined mechanism is not intended to be used as a dynamic
routing protocol. It should be noted that proposed mechanism
cannot automatically detect routing changes. In networks that
use dynamic routing and also employ this mechanism, clients
may attempt using routes configured over DHCPv6 even though
routers or specific routes ceased to be available. This may
cause black hole routing problem. Therefore it is not
recommended to use this mechanism in networks that use dynamic
routing protocols. This mechanism SHOULD NOT be used in such
networks, unless network operator can provide a way to update
DHCP server information in case of router availability
changes.Discussion: It should be noted that DHCPv6 server is not
able to monitor health of existing routers. As there are
currently more than 60 options defined for DHCPv6, it is
infeasible to implement mechanism that would monitor huge set
of services and stop announcing its availability in case of
service outage. Therefore in case of prolonged unavailability
human interverntion is required to change DHCPv6 server
configuration. If that is considered a problem, network
administrators should consider using other alternatives, like
RA and ND mechanisms (see ).User is also encouraged to read .A DHCPv6 client interested in obtaining routing information
includes the NEXT_HOP and RT_PREFIX options as part of its
Option Request Option (ORO) in messages directed to a server (as
allowed by , i.e. Solicit,
Request, Renew, Rebind or Information-request messages). A
Server, when configured to do so, provides the requested route
information using zero, one or more NEXT_HOP options in messages
sent in response (Advertise, and Reply). So as to allow the
route options to be both extensible, as well as conveying
detailed info for routes, use is made of a nested options
structure. Server sends one or more NEXT_HOP options that
specify the IPv6 next hop addresses. Each NEXT_HOP option
conveys in turn zero, one or more RT_PREFIX options that
represents the IPv6 destination prefixes reachable via the given
next hop. Server includes RT_PREFIX directly in message to
indicate that given prefix is available directly on-link. Server
MAY send a single NEXT_HOP without any RT_PREFIX suboptions or
with RT_PREFIX that contains ::/0 to indicate available default
route. The Formats of the NEXT_HOP and RT_PREFIX options are
defined in the following sub-sections.The DHCPv6 Route Options format borrows from the principles
of the Route Information Option defined in .Each IPv6 route consists of an IPv6 next hop address, an
IPv6 destination prefix (a.k.a. the destination subnet), and a
host preference value for the route. Elements of such route
(e.g. Next hops and prefixes associated with them) are
conveyed in NEXT_HOP option that contains RT_PREFIX
suboptions.The Next Hop Option defines the IPv6 address of the next hop,
usually corresponding to a specific next-hop router. For each next hop
address there can be zero, one or more prefixes reachable via that next
hop.OPTION_NEXT_HOP (TBD1).16 + Length of NEXT_HOP options
field.16 octet long field that
specified IPv6 address of the next hop.Options associated with this Next
Hop. This includes, but is not limited to, zero, one or more
RT_PREFIX options that specify prefixes reachable through
the given next hop.The Route Prefix Option is used to convey information about
a single prefix that represents the destination network. The
Route Prefix Option is used as a sub-option in the previously
defined Next Hop Option. It may also be sent directly in
message to indicate that route is available directly
on-link.OPTION_RT_PREFIX (TBD2).Length of the Route Prefix option
including all its sub-options.32-bit unsigned
integer. Specifies lifetime of the route information,
expressed in seconds (relative to the time the packet is
sent). There are 2 special values defined. 0 means that
route is no longer valid and must be removed by clients. A
value of all one bits (0xffffffff) represents infinity.
means infinity.8-bit unsigned integer. The length in
bits of the IP Prefix. The value ranges from 0 to 128. This field
represents the number of valid leading bits in the prefix.Reserved field. Server MUST set this value
to zero and client MUST ignore its content. 2-bit signed
integer. The Route Preference indicates whether to prefer
the router associated with this prefix over others, when
multiple identical prefixes (for different routers) have
been received. If the Reserved (10) value is received,
the Route Information Option MUST be ignored.Route Metric. 8-bit signed integer. The
Route Metric indicates whether to prefer the next hop associated
with this prefix over others, when multiple identical prefixes
(for different next hops) have been received. a variable size field that
specifies Rule IPv6 prefix. Length of the field is defined
by prefix6-len field and is rounded up to the nearest
octet boundary (if case when prefix6-len is not divisible
by 8). In such case additional padding bits must be
zeroed.Options specific to this
particular prefix.Values for preference field have meaning identical to
Route Information Option, defined in , Section 2.1:
HighMedium (default)LowReserved - MUST NOT be sentWhen configured to do so, a DHCPv6 server shall provide the
Next Hop and Route Prefix Options in ADVERTISE and REPLY
messages sent to a client that requested the route option. Each
Next Hop Option sent by the server must convey at least one
Route Prefix Option.Server includes NEXT_HOP option with possible RT_PREFIX
suboptions to designate that specific routes are available via
routers. Server includes RT_PREFIX options directly in Advertise
and Reply messages to inform that specific routes are available
directly on-link.If there is more than one route available via specific next
hop, server MUST send only one NEXT_HOP for that next hop,
which contains multiple RT_PREFIX options. Server MUST NOT
send more than one identical (i.e. with equal next hop address
field) NEXT_HOP option.Servers SHOULD NOT send Route Option to clients that did not
explicitly requested it, using the ORO.Servers MUST NOT send Route Option in messages other than ADVERTISE
or REPLY.Servers MAY also include Status Code Option, defined in Section 22.13
of the to indicate the status of the
operation.Servers MUST include the Status Code Option, if the requested routing
configuration was not successful and SHOULD use status codes as defined
in and .The maximum number of routing information in one DHCPv6 message
depend on the maximum DHCPv6 message size defined in A DHCPv6 client compliant with this specification MUST
request the NEXT_HOP and RT_PREFIX Options in an Option Request
Option (ORO) in the following messages: Solicit, Request, Renew,
Rebind, and Information-Request. The messages are to be sent as
and when specified by .When processing a received Route Options a client MUST substitute a
received 0::0 value in the Next Hop Option with the source IPv6 address
of the received DHCPv6 message. It MUST also associate a received Link
Local next hop addresses with the interface on which the client received
the DHCPv6 message containing the route option. Such a substitution
and/or association is useful in cases where the DHCPv6 server operator
does not directly know the IPv6 next-hop address, other than knowing it
is that of a DHCPv6 relay agent on the client LAN segment. DHCPv6
Packets relayed to the client are sourced by the relay using this
relay's IPv6 address, which could be a link local address.The Client SHOULD refresh assigned route information periodically. The
generic DHCPv6 Information Refresh Time Option, as specified in , can be used when it is desired for the client
to periodically refresh of route information.The routes conveyed by the Route Option should be considered as
complimentary to any other static route learning and maintenance
mechanism used by, or on the client with one modification: The client
MUST flush DHCPv6 installed routes following a link flap event on the
DHCPv6 client interface over which the routes were installed. This
requirement is necessary to automate the flushing of routes for clients
that may move to a different network.Client MUST confirm that routers announced over DHCPv6 are
reachable, using one of methods suitable for specific network
type. The most common mechanism is Neighbor Unreachability
Detection (NUD), specified in . Client
SHOULD use NUD to verify that received routers are reachable
before adjusting its routing tables. Client MAY use other
reachibality verification mechanisms specific to used network
technology. To avoid potential long-lived routing black holes,
client MAY periodically confirm that router is still
reachable.Information received via Route Options over DHCPv6 MUST be
treated equally to routing information obtained via other
sources. In particular, from the RA perspective, DHCPv6
provisioning should be treated as if yet another RA was
received. Preference field should be taken into consideration
during route information processing. In particular,
administrators are encouraged to read , Section 4.1 for guidance.To facilitate information merge between DHCPv6 and RA,
DHCPv6 option conveys the same information as RIO, specified
in , albeit on-wire format is slightly
different. The differences are:Metric field (available in previous version of this draft)
has been replaced with 2-bit preference field that is in line
with RIO information.RIO uses 128-length prefix field, while DHCPv6 option uses
variable prefix length. That difference is used to minimize
packet size as it avoid transmitting zeroed octets. Despite
slightly different encoding, delivered information is exactly
the same.If prefix is available directly on-link, Route Prefix
option is conveyed directly in DHCPv6 message, not withing
Next Hop option. That feature is considered a superset,
compared to RIO.IANA is kindly requested to allocate DHCPv6 option code TBD1
to the OPTION_NEXT_HOP and TBD2 to OPTION_RT_PREFIX. Both values
should be added to the DHCPv6 option code space defined in
Section 24.3 of .The overall security considerations discussed in apply also to this document. The Route option
could be used by malicious parties to misdirect traffic sent by the
client either as part of a denial of service or man-in-the-middle
attack. An alternative denial of service attack could also be realized
by means of using the route option to overflowing any known memory
limitations of the client, or to exceed the client's ability to handle
the number of next hop addresses.Neither of the above considerations are new and specific to the
proposed route option. The mechanisms identified for securing DHCPv6 as
well as reasonable checks performed by client implementations are deemed
sufficient in addressing these problems.It is essential that clients verify that announced routers are
indeed reachable, as specified in . Failing to
do so may create black hole routing problem.This mechanism may introduce severe problems if deployed in
networks that use dynamic routing protocols. See for details.DHCPv6 becomes a complete provisioning protocol with this
mechanism, i.e. all necessary configuration parameters may be
delivered using DHCPv6 only. It was suggested that in some cases
this may lead to decision of disabling RA. While RA-less
networks could offer lower operational expenses and protection
against rogue RAs, they would not work with nodes that do not
support this feature. Therefore such decision is not
recommended, unless all effects are carefully analyzed. It is
worth noting that disabling RA support in hosts would solve
rogue RA problem, it would in fact only change the issue into
rogue DHCPv6 problem. That is somewhat beneficial, however, as
rogue RA may affect all nodes immediately while rogue DHCPv6
server will affect only new nodes, that boot up after rogue
server manifests itself.Reader is also encouraged to read DHCPv6 security considerations
document .This document would not have been possible without the significant
contribution provided by: Arifumi Matsumoto, Hui Deng, Richard Johnson,
and Zhen Cao.The authors would also like to thank Alfred Hines, Ralph
Droms, Ted Lemon, Ole Troan, Dave Oran, Dave Ward, Joel Halpern,
Marcin Siodelski, Alexandru Petrescu, Roberta Maglione, Tim
Chown, Brian Carpenter, Dave Thaler, Lorenzo Colitti and Leo
Bicknell for their comments and useful suggestions.This work has been partially supported by Department of
Computer Communications (a division of Gdansk University of
Technology) and the Polish Ministry of Science and Higher
Education under the European Regional Development Fund, Grant
No. POIG.01.01.02-00-045/09-00 (Future Internet Engineering
Project).3GPP TR 23.853: Operator Policies for IP Interface Selection (OPIIS)3GPPBBF WT-124 issue 3Broadband ForumNANOG