Dynamic Host Configuration (DHC) | T. Mrugalski, Ed. |
Internet-Draft | M. Siodelski |
Obsoletes: 3315,3633,3736,7083,7550 (if | ISC |
approved) | B. Volz |
Intended status: Standards Track | A. Yourtchenko |
Expires: August 5, 2016 | Cisco |
M. Richardson | |
SSW | |
S. Jiang | |
Huawei | |
T. Lemon | |
Nominum | |
February 2, 2016 |
Dynamic Host Configuration Protocol for IPv6 (DHCPv6) bis
draft-ietf-dhc-rfc3315bis-03
This document describes the Dynamic Host Configuration Protocol for IPv6 (DHCPv6): an extensible mechanism for configuring hosts with network configuration parameters, IP addresses, and prefixes. Parameters can be provided statelessly, or in combination with stateful assignment of one or more IPv6 addresses and/or IPv6 prefixes. DHCPv6 can operate either in place of or in addition to stateless address autoconfiguration (SLAAC).
This document updates the text from RFC 3315, the original DHCPv6 specification, and incorporates the stateless DHCPv6 extensions (RFC 3736) and prefix delegation (RFC 3633), clarifying the interactions between these modes of operation (RFC 7550) and providing a mechanism for throttling DHCPv6 clients when DHCPv6 service is not available (RFC 7083). As such, this document obsoletes RFC3315, RFC3633, RFC3736, RFC7083, RFC7550.
This Internet-Draft is submitted in full conformance with the provisions of BCP 78 and BCP 79.
Internet-Drafts are working documents of the Internet Engineering Task Force (IETF). Note that other groups may also distribute working documents as Internet-Drafts. The list of current Internet-Drafts is at http://datatracker.ietf.org/drafts/current/.
Internet-Drafts are draft documents valid for a maximum of six months and may be updated, replaced, or obsoleted by other documents at any time. It is inappropriate to use Internet-Drafts as reference material or to cite them other than as "work in progress."
This Internet-Draft will expire on August 5, 2016.
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This document describes DHCP for IPv6 (DHCPv6), a client/server protocol that provides managed configuration of devices. Relay agent functionality is also defined for enabling communication between clients and servers that are not on the same link.
DHCPv6 can provide a device with addresses assigned by a DHCPv6 server and other configuration information, which are carried in options. DHCPv6 can be extended through the definition of new options to carry configuration information not specified in this document.
DHCPv6 is the "stateful address autoconfiguration protocol" and the "stateful autoconfiguration protocol" referred to in "IPv6 Stateless Address Autoconfiguration" [RFC4862].
This document also provides a mechanism for automated delegation of IPv6 prefixes using DHCPv6. Through this mechanism, a delegating router can delegate prefixes to requesting routers.
DHCPv6 can also operate in mode, where only configuration options (but no addresses or prefixes) are provided. That implies that the server doesn't have to track any state, and thus the mode is called stateless DHCPv6. Mechanisms necessary to support stateless DHCPv6 are much smaller than to support stateful DHCPv6.
The remainder of this introduction summarizes relation to the previous DHCPv6 standards Section 1.1, clarifies the stance with regards to DHCPv4 Section 1.2. More detailed description of the message exchange mechanisms and example message flows in Section 1.4 and Section 1.5 are intended as illustrations of DHCP operation rather than an exhaustive list of all possible client-server interactions. Section 5 provides an overview of common operational models. Section 18, Section 19, and Section 20 explain client and server operation in detail.
The initial specification of DHCPv6 was defined in [RFC3315] and a number of follow up extensions published over the years. Several notable extensions were published: prefix delegation [RFC3633], stateless [RFC3736], update to SOL_MAX_RT and INF_MAX_RT option values [RFC7083] and harmonization between addresses and prefixes support [RFC7550]. Understanding a protocol which definition is spread between large number of documents may be cumbersome. Furthermore, a significant operational experience has been gained over the years and certain small elements of the protocol have been reworked. This document provides a unified, corrected and cleaned up definition of the DHCPv6 that also covers all erratas filled against older RFCs. As such, it obsoletes a number of aforementioned RFCs. There is a small number of mechanisms that were obsoleted. They are listed in Section 27.
The operational models and relevant configuration information for DHCPv4 [RFC2132][RFC2131] and DHCPv6 are sufficiently different that integration between the two services is not included in this document. [RFC3315] suggested that future work might be to extend DHCPv6 to carry IPv4 address and configuration information. However, the current consensus of the IETF is that DHCPv4 should be used rather than DHCPv6 when conveying IPv4 configuration information to nodes. [RFC7341] describes a transport mechanism to carry DHCPv4 messages using the DHCPv6 protocol for the dynamic provisioning of IPv4 address and configuration information across IPv6-only networks.
Clients and servers exchange DHCP messages using UDP [RFC0768]. The client uses a link-local address or addresses determined through other mechanisms for transmitting and receiving DHCP messages.
A DHCP client sends most messages using a reserved, link-scoped multicast destination address so that the client need not be configured with the address or addresses of DHCP servers.
To allow a DHCP client to send a message to a DHCP server that is not attached to the same link, a DHCP relay agent on the client's link will relay messages between the client and server. The operation of the relay agent is transparent to the client and the discussion of message exchanges in the remainder of this section will omit the description of message relaying by relay agents.
Once the client has determined the address of a server, it may under some circumstances send messages directly to the server using unicast.
When a DHCP client does not need to have a DHCP server assign it IP addresses, the client can obtain configuration information such as a list of available DNS servers [RFC3646] or NTP servers [RFC4075] through a single message and reply exchanged with a DHCP server. To obtain configuration information the client first sends an Information-request message to the All_DHCP_Relay_Agents_and_Servers multicast address. Servers respond with a Reply message containing the configuration information for the client.
This message exchange assumes that the client requires only configuration information and does not require the assignment of any IPv6 addresses.
When a server has IPv6 addresses and other configuration information committed to a client, the client and server may be able to complete the exchange using only two messages, instead of four messages as described in the next section. In this case, the client sends a Solicit message to the All_DHCP_Relay_Agents_and_Servers requesting the assignment of addresses and other configuration information. This message includes an indication that the client is willing to accept an immediate Reply message from the server. The server that is willing to commit the assignment of addresses to the client immediately responds with a Reply message. The configuration information and the addresses in the Reply message are then immediately available for use by the client.
Each address assigned to the client has associated preferred and valid lifetimes specified by the server. To request an extension of the lifetimes assigned to an address, the client sends a Renew message to the server. The server sends a Reply message to the client with the new lifetimes, allowing the client to continue to use the address without interruption.
To request the assignment of one or more IPv6 addresses, a client first locates a DHCP server and then requests the assignment of addresses and other configuration information from the server. The client sends a Solicit message to the All_DHCP_Relay_Agents_and_Servers address to find available DHCP servers. Any server that can meet the client's requirements responds with an Advertise message. The client then chooses one of the servers and sends a Request message to the server asking for confirmed assignment of addresses and other configuration information. The server responds with a Reply message that contains the confirmed addresses and configuration.
As described in the previous section, the client sends a Renew message to the server to extend the lifetimes associated with its addresses, allowing the client to continue to use those addresses without interruption.
The key words "MUST", "MUST NOT", "REQUIRED", "SHALL", "SHALL NOT", "SHOULD", "SHOULD NOT", "RECOMMENDED", "NOT RECOMMENDED", "MAY", and "OPTIONAL" in this document are to be interpreted as described in [RFC2119].
This document also makes use of internal conceptual variables to describe protocol behavior and external variables that an implementation must allow system administrators to change. The specific variable names, how their values change, and how their settings influence protocol behavior are provided to demonstrate protocol behavior. An implementation is not required to have them in the exact form described here, so long as its external behavior is consistent with that described in this document.
The IPv6 Specification provides the base architecture and design of IPv6. Related work in IPv6 that would best serve an implementor to study includes the IPv6 Specification [RFC2460], the IPv6 Addressing Architecture [RFC4291], IPv6 Stateless Address Autoconfiguration [RFC4862], IPv6 Neighbor Discovery Processing [RFC4861], and Dynamic Updates to DNS [RFC2136]. These specifications enable DHCP to build upon the IPv6 work to provide both robust stateful autoconfiguration and autoregistration of DNS Host Names.
The IPv6 Addressing Architecture specification [RFC4291] defines the address scope that can be used in an IPv6 implementation, and the various configuration architecture guidelines for network designers of the IPv6 address space. Two advantages of IPv6 are that support for multicast is required and nodes can create link-local addresses during initialization. The availability of these features means that a client can use its link-local address and a well-known multicast address to discover and communicate with DHCP servers or relay agents on its link.
IPv6 Stateless Address Autoconfiguration [RFC4862] specifies procedures by which a node may autoconfigure addresses based on router advertisements [RFC4861], and the use of a valid lifetime to support renumbering of addresses on the Internet. In addition, the protocol interaction by which a node begins stateless or stateful autoconfiguration is specified. DHCP is one vehicle to perform stateful autoconfiguration. Compatibility with stateless address autoconfiguration is a design requirement of DHCP.
IPv6 Neighbor Discovery [RFC4861] is the node discovery protocol in IPv6 which replaces and enhances functions of ARP [RFC0826]. To understand IPv6 and stateless address autoconfiguration, it is strongly recommended that implementors understand IPv6 Neighbor Discovery.
Dynamic Updates to DNS [RFC2136] is a specification that supports the dynamic update of DNS records for both IPv4 and IPv6. DHCP can use the dynamic updates to DNS to integrate addresses and name space to not only support autoconfiguration, but also autoregistration in IPv6.
This section defines terminology specific to IPv6 and DHCP used in this document.
IPv6 terminology relevant to this specification from the IPv6 Protocol [RFC2460], IPv6 Addressing Architecture [RFC4291], and IPv6 Stateless Address Autoconfiguration [RFC4862] is included below.
Terminology specific to DHCP can be found below.
This section describes some of the current most common DHCP operational models. The described models are not mutually exclusive and are sometimes used together. For example, a device may start in stateful mode to obtain an address, and at a later time when an application is started, request additional parameters using stateless mode.
This document assumes that the DHCP servers and the client, communicating with the servers via specific interface, belong to a single provisioning domain.
Stateless DHCP [RFC3736] is used when DHCP is not used for obtaining a lease, but a node (DHCP client) desires one or more DHCP "other configuration" parameters, such as a list of DNS recursive name servers or DNS domain search lists [RFC3646]. Stateless may be used when a node initially boots or at any time the software on the node requires some missing or expired configuration information that is available via DHCP.
This is the simplest and most basic operation for DHCP and requires a client (and a server) to support only two messages - Information-request and Reply. Note that DHCP servers and relay agents typically also need to support the Relay-Forw and Relay-Reply messages to accommodate operation when clients and servers are not on the same link.
This model of operation was the original motivation for DHCP and is the "stateful address autoconfiguration protocol" for IPv6 [RFC2462]. It is appropriate for situations where stateless address autoconfiguration is not desired, because of network policy, additional requirements (such as updating the DNS with forward or reverse resource records), or client specific requirements (i.e., some prefixes are only available to some clients) which are not possible using stateless address autoconfiguration.
The model of operation for non-temporary address assignment is as follows. The server is provided with IPv6 prefixes from which it may allocate addresses to clients, as well as any related network topology information as to which prefixes are present on which links. A client requests a non-temporary address to be assigned by the server. The server allocates an address or addresses appropriate for the link on which the client is connected. The server returns the allocated address or addresses to the client.
Each address has an associated preferred and valid lifetime, which constitutes an agreement about the length of time over which the client is allowed to use the address. A client can request an extension of the lifetimes on an address and is required to terminate the use of an address if the valid lifetime of the address expires.
Typically clients request other configuration parameters, such as the domain server addresses and search lists, when requesting addresses.
The prefix delegation mechanism, originally described in [RFC3633], is another stateful mode of operation and intended for simple delegation of prefixes from a delegating router (DHCP server) to requesting routers (DHCP clients). It is appropriate for situations in which the delegating router does not have knowledge about the topology of the networks to which the requesting router is attached, and the delegating router does not require other information aside from the identity of the requesting router to choose a prefix for delegation. For example, these options would be used by a service provider to assign a prefix to a Customer Edge Router device acting as a router between the subscriber's internal network and the service provider's core network.
The design of this prefix delegation mechanism meets the requirements for prefix delegation in [RFC3769].
The model of operation for prefix delegation is as follows. A delegating router is provided IPv6 prefixes to be delegated to requesting routers. A requesting router requests prefix(es) from the delegating router, as described in Section 19. The delegating router chooses prefix(es) for delegation, and responds with prefix(es) to the requesting router. The requesting router is then responsible for the delegated prefix(es). For example, the requesting router might assign a subnet from a delegated prefix to one of its interfaces, and begin sending router advertisements for the prefix on that link.
Each prefix has an associated valid and preferred lifetime, which constitutes an agreement about the length of time over which the requesting router is allowed to use the prefix. A requesting router can request an extension of the lifetimes on a delegated prefix and is required to terminate the use of a delegated prefix if the valid lifetime of the prefix expires.
The mechanism through which the delegating router selects prefix(es) for delegation is not specified in this document. Examples of ways in which the server might select prefix(es) for a client include: static assignment based on subscription to an ISP; dynamic assignment from a pool of available prefixes; selection based on an external authority such as a RADIUS server using the Framed-IPv6-Prefix option as described in [RFC3162].
This prefix delegation mechanism would be appropriate for use by an ISP to delegate a prefix to a subscriber, where the delegated prefix would possibly be subnetted and assigned to the links within the subscriber's network.
Figure 1 illustrates a network architecture in which prefix delegation could be used.
______________________ \ / \ \ | ISP core network | \ \__________ ___________/ | | | +-------+-------+ | | Aggregation | | ISP | device | | network | (delegating | | | router) | | +-------+-------+ | | / |DSL to subscriber / |premises / | +------+------+ \ | CPE | \ | (requesting | \ | router) | | +----+---+----+ | | | | Subscriber ---+-------------+-----+ +-----+------ | Network | | | | +----+-----+ +-----+----+ +----+-----+ | |Subscriber| |Subscriber| |Subscriber| / | PC | | PC | | PC | / +----------+ +----------+ +----------+ /
Figure 1: Prefix Delegation Network
In this example, the delegating router is configured with a set of prefixes to be used for assignment to customers at the time of each customer's first connection to the ISP service. The prefix delegation process begins when the requesting router requests configuration information through DHCP. The DHCP messages from the requesting router are received by the delegating router in the aggregation device. When the delegating router receives the request, it selects an available prefix or prefixes for delegation to the requesting router. The delegating router then returns the prefix or prefixes to the requesting router.
The requesting router subnets the delegated prefix and assigns the longer prefixes to links in the subscriber's network. In a typical scenario based on the network shown in Figure 1, the requesting router subnets a single delegated /48 prefix into /64 prefixes and assigns one /64 prefix to each of the links in the subscriber network.
The prefix delegation options can be used in conjunction with other DHCP options carrying other configuration information to the requesting router. The requesting router may, in turn, provide DHCP service to hosts attached to the internal network. For example, the requesting router may obtain the addresses of DNS and NTP servers from the ISP delegating router, and then pass that configuration information on to the subscriber hosts through a DHCP server in the requesting router.
If the requesting router assigns a delegated prefix to a link to which the router is attached, and begins to send router advertisements for the prefix on the link, the requesting router MUST set the valid lifetime in those advertisements to be no later than the valid lifetime specified in the IA_PD Prefix option. A requesting router MAY use the preferred lifetime specified in the IA_PD Prefix option.
The DHCP requirements and network architecture for Customer Edge Routers are described in [RFC7084]. This model of operation combines address assignment (see Section 5.2) and prefix delegation (see Section 5.3). In general, this model assumes that a single set of transactions between the client and server will assign or extend the client's non-temporary addresses and delegated prefixes.
Temporary addresses were originally introduced to avoid privacy concerns with stateless address autoconfiguration, which based 64-bits of the address on the EUI-64 (see [RFC3041] and [RFC4941]). They were added to DHCP to provide complementary support when stateful address assignment is used.
Temporary address assignment works mostly like non-temporary address assignment (see Section 5.2), however these addresses are generally intended to be used for a short period of time and not to have their lifetimes extended, though they can be if required.
This section describes various program and networking constants used by DHCP.
DHCP makes use of the following multicast addresses:
Clients listen for DHCP messages on UDP port 546. Servers and relay agents listen for DHCP messages on UDP port 547.
DHCP defines the following message types. More detail on these message types can be found in Section 7 and Section 8. Message types not listed here are reserved for future use. The numeric encoding for each message type is shown in parentheses.
DHCPv6 uses status codes to communicate the success or failure of operations requested in messages from clients and servers, and to provide additional information about the specific cause of the failure of a message. The specific status codes are defined in Section 23.12.
If the Status Code option does not appear in a message in which the option could appear, the status of the message is assumed to be Success.
This section presents a table of values used to describe the message transmission behavior of clients and servers.
Parameter | Default | Description |
---|---|---|
SOL_MAX_DELAY | 1 sec | Max delay of first Solicit |
SOL_TIMEOUT | 1 sec | Initial Solicit timeout |
SOL_MAX_RT | 3600 secs | Max Solicit timeout value |
REQ_TIMEOUT | 1 sec | Initial Request timeout |
REQ_MAX_RT | 30 secs | Max Request timeout value |
REQ_MAX_RC | 10 | Max Request retry attempts |
CNF_MAX_DELAY | 1 sec | Max delay of first Confirm |
CNF_TIMEOUT | 1 sec | Initial Confirm timeout |
CNF_MAX_RT | 4 secs | Max Confirm timeout |
CNF_MAX_RD | 10 secs | Max Confirm duration |
REN_TIMEOUT | 10 secs | Initial Renew timeout |
REN_MAX_RT | 600 secs | Max Renew timeout value |
REB_TIMEOUT | 10 secs | Initial Rebind timeout |
REB_MAX_RT | 600 secs | Max Rebind timeout value |
INF_MAX_DELAY | 1 sec | Max delay of first Information-request |
INF_TIMEOUT | 1 sec | Initial Information-request timeout |
INF_MAX_RT | 3600 secs | Max Information-request timeout value |
REL_TIMEOUT | 1 sec | Initial Release timeout |
REL_MAX_RC | 4 | MAX Release retry attempts |
DEC_TIMEOUT | 1 sec | Initial Decline timeout |
DEC_MAX_RC | 4 | Max Decline retry attempts |
REC_TIMEOUT | 2 secs | Initial Reconfigure timeout |
REC_MAX_RC | 8 | Max Reconfigure attempts |
HOP_COUNT_LIMIT | 32 | Max hop count in a Relay-forward message |
All time values for lifetimes, T1 and T2 are unsigned integers. The value 0xffffffff is taken to mean "infinity" when used as a lifetime (as in [RFC4861]) or a value for T1 or T2.
All DHCP messages sent between clients and servers share an identical fixed format header and a variable format area for options.
All values in the message header and in options are in network byte order.
Options are stored serially in the options field, with no padding between the options. Options are byte-aligned but are not aligned in any other way such as on 2 or 4 byte boundaries.
The following diagram illustrates the format of DHCP messages sent between clients and servers:
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 +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+ | msg-type | transaction-id | +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+ | | . options . . (variable) . | | +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
Figure 2: Client/Server message format
Relay agents exchange messages with servers to relay messages between clients and servers that are not connected to the same link.
All values in the message header and in options are in network byte order.
Options are stored serially in the options field, with no padding between the options. Options are byte-aligned but are not aligned in any other way such as on 2 or 4 byte boundaries.
There are two relay agent messages, which share the following format:
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 +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+ | msg-type | hop-count | | +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+ | | | | link-address | | | | +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-| | | | +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+ | | | | peer-address | | | | +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-| | | | +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+ | . . . options (variable number and length) .... . | | +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
Figure 3: Relay Agent/Server message format
The following sections describe the use of the Relay Agent message header.
The following table defines the use of message fields in a Relay-forward message.
The following table defines the use of message fields in a Relay-reply message.
So that domain names may be encoded uniformly, a domain name or a list of domain names is encoded using the technique described in section 3.1 of [RFC1035]. A domain name, or list of domain names, in DHCP MUST NOT be stored in compressed form, as described in section 4.1.4 of [RFC1035].
Each DHCP client and server has a DUID. DHCP servers use DUIDs to identify clients for the selection of configuration parameters and in the association of IAs with clients. DHCP clients use DUIDs to identify a server in messages where a server needs to be identified. See Section 23.2 and Section 23.3 for the representation of a DUID in a DHCP message.
Clients and servers MUST treat DUIDs as opaque values and MUST only compare DUIDs for equality. Clients and servers MUST NOT in any other way interpret DUIDs. Clients and servers MUST NOT restrict DUIDs to the types defined in this document, as additional DUID types may be defined in the future.
The DUID is carried in an option because it may be variable length and because it is not required in all DHCP messages. The DUID is designed to be unique across all DHCP clients and servers, and stable for any specific client or server - that is, the DUID used by a client or server SHOULD NOT change over time if at all possible; for example, a device's DUID should not change as a result of a change in the device's network hardware.
The motivation for having more than one type of DUID is that the DUID must be globally unique, and must also be easy to generate. The sort of globally-unique identifier that is easy to generate for any given device can differ quite widely. Also, some devices may not contain any persistent storage. Retaining a generated DUID in such a device is not possible, so the DUID scheme must accommodate such devices.
A DUID consists of a two-octet type code represented in network byte order, followed by a variable number of octets that make up the actual identifier. The length of the DUID (not including the type code) is at least 1 octet and at most 128 octets. The following types are currently defined:
Type | Description |
---|---|
1 | Link-layer address plus time |
2 | Vendor-assigned unique ID based on Enterprise Number |
3 | Link-layer address |
4 | Universally Unique IDentifier (UUID) - see [RFC6355] |
Formats for the variable field of the DUID for the first 3 of the above types are shown below. The fourth type, DUID-UUID [RFC6355], can be used in situations where there is a UUID stored in a device's firmware settings.
This type of DUID consists of a two octet type field containing the value 1, a two octet hardware type code, four octets containing a time value, followed by link-layer address of any one network interface that is connected to the DHCP device at the time that the DUID is generated. The time value is the time that the DUID is generated represented in seconds since midnight (UTC), January 1, 2000, modulo 2^32. The hardware type MUST be a valid hardware type assigned by the IANA as described in [RFC0826]. Both the time and the hardware type are stored in network byte order. The link-layer address is stored in canonical form, as described in [RFC2464].
The following diagram illustrates the format of a DUID-LLT:
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 +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+ | 1 | hardware type (16 bits) | +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+ | time (32 bits) | +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+ . . . link-layer address (variable length) . . . +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
Figure 4: DUID-LLT format
The choice of network interface can be completely arbitrary, as long as that interface provides a globally unique link-layer address for the link type, and the same DUID-LLT SHOULD be used in configuring all network interfaces connected to the device, regardless of which interface's link-layer address was used to generate the DUID-LLT.
Clients and servers using this type of DUID MUST store the DUID-LLT in stable storage, and MUST continue to use this DUID-LLT even if the network interface used to generate the DUID-LLT is removed. Clients and servers that do not have any stable storage MUST NOT use this type of DUID.
Clients and servers that use this DUID SHOULD attempt to configure the time prior to generating the DUID, if that is possible, and MUST use some sort of time source (for example, a real-time clock) in generating the DUID, even if that time source could not be configured prior to generating the DUID. The use of a time source makes it unlikely that two identical DUID-LLTs will be generated if the network interface is removed from the client and another client then uses the same network interface to generate a DUID-LLT. A collision between two DUID-LLTs is very unlikely even if the clocks have not been configured prior to generating the DUID.
This method of DUID generation is recommended for all general purpose computing devices such as desktop computers and laptop computers, and also for devices such as printers, routers, and so on, that contain some form of writable non-volatile storage.
Despite our best efforts, it is possible that this algorithm for generating a DUID could result in a client identifier collision. A DHCP client that generates a DUID-LLT using this mechanism MUST provide an administrative interface that replaces the existing DUID with a newly-generated DUID-LLT.
This form of DUID is assigned by the vendor to the device. It consists of the vendor's registered Private Enterprise Number as maintained by IANA [IANA-PEN] followed by a unique identifier assigned by the vendor. The following diagram summarizes the structure of a DUID-EN:
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 +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+ | 2 | enterprise-number | +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+ | enterprise-number (contd) | | +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+ | . identifier . . (variable length) . . . +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
Figure 5: DUID-EN format
The source of the identifier is left up to the vendor defining it, but each identifier part of each DUID-EN MUST be unique to the device that is using it, and MUST be assigned to the device no later than at the first usage and stored in some form of non-volatile storage. This typically means being assigned during manufacture process in case of physical devices or when the image is created or booted for the first time in case of virtual machines. The generated DUID SHOULD be recorded in non-erasable storage. The enterprise-number is the vendor's registered Private Enterprise Number as maintained by IANA [IANA-PEN]. The enterprise-number is stored as an unsigned 32 bit number.
An example DUID of this type might look like this:
+---+---+---+---+---+---+---+---+ | 0 | 2 | 0 | 0 | 0 | 9| 12|192| +---+---+---+---+---+---+---+---+ |132|211| 3 | 0 | 9 | 18| +---+---+---+---+---+---+
Figure 6: DUID-EN example
This example includes the two-octet type of 2, the Enterprise Number (9), followed by eight octets of identifier data (0x0CC084D303000912).
This type of DUID consists of two octets containing the DUID type 3, a two octet network hardware type code, followed by the link-layer address of any one network interface that is permanently connected to the client or server device. For example, a host that has a network interface implemented in a chip that is unlikely to be removed and used elsewhere could use a DUID-LL. The hardware type MUST be a valid hardware type assigned by the IANA, as described in [RFC0826]. The hardware type is stored in network byte order. The link-layer address is stored in canonical form, as described in [RFC2464]. The following diagram illustrates the format of a DUID-LL:
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 +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+ | 3 | hardware type (16 bits) | +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+ . . . link-layer address (variable length) . . . +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
Figure 7: DUID-LL format
The choice of network interface can be completely arbitrary, as long as that interface provides a unique link-layer address and is permanently attached to the device on which the DUID-LL is being generated. The same DUID-LL SHOULD be used in configuring all network interfaces connected to the device, regardless of which interface's link-layer address was used to generate the DUID.
DUID-LL is recommended for devices that have a permanently-connected network interface with a link-layer address, and do not have nonvolatile, writable stable storage. DUID-LL MUST NOT be used by DHCP clients or servers that cannot tell whether or not a network interface is permanently attached to the device on which the DHCP client is running.
An "identity-association" (IA) is a construct through which a server and a client can identify, group, and manage a set of related IPv6 addresses or delegated prefixes. Each IA consists of an IAID and associated configuration information.
The IAID uniquely identifies the IA and must be chosen to be unique among the IAIDs for that IA type on the client. The IAID is chosen by the client. For any given use of an IA by the client, the IAID for that IA MUST be consistent across restarts of the DHCP client. The client may maintain consistency either by storing the IAID in non-volatile storage or by using an algorithm that will consistently produce the same IAID as long as the configuration of the client has not changed. There may be no way for a client to maintain consistency of the IAIDs if it does not have non-volatile storage and the client's hardware configuration changes. If the client uses only one IAID, it can use a well-known value, e.g., zero.
A client must associate at least one distinct IA with each of its network interfaces for which it is to request the assignment of IPv6 addresses from a DHCP server. The client uses the IAs assigned to an interface to obtain configuration information from a server for that interface. Each IA must be associated with exactly one interface.
The configuration information in an IA consists of one or more IPv6 addresses along with the times T1 and T2 for the IA. See Section 23.4 for the representation of an IA in a DHCP message.
Each address in an IA has a preferred lifetime and a valid lifetime, as defined in [RFC4862]. The lifetimes are transmitted from the DHCP server to the client in the IA option. The lifetimes apply to the use of IPv6 addresses, as described in section 5.5.4 of [RFC4862].
An IA_PD is different from an IA for address assignment, in that it does not need to be associated with exactly one interface. One IA_PD can be associated with the requesting router, with a set of interfaces or with exactly one interface. A requesting router must create at least one distinct IA_PD. It may associate a distinct IA_PD with each of its downstream network interfaces and use that IA_PD to obtain a prefix for that interface from the delegating router.
The configuration information in an IA_PD consists of one or more IPv6 prefixes along with the times T1 and T2 for the IA_PD. See Section 23.21 for the representation of an IA_PD in a DHCP message.
A server selects addresses to be assigned to an IA according to the address assignment policies determined by the server administrator and the specific information the server determines about the client from some combination of the following sources:
Any address assigned by a server that is based on an EUI-64 identifier MUST include an interface identifier with the "u" (universal/local) and "g" (individual/group) bits of the interface identifier set appropriately, as indicated in section 2.5.1 of [RFC4291].
A server MUST NOT assign an address that is otherwise reserved for some other purpose. For example, a server MUST NOT assign reserved anycast addresses, as defined in [RFC2526], from any subnet.
A client may request the assignment of temporary addresses (see [RFC4941] for the definition of temporary addresses). DHCPv6 handling of address assignment is no different for temporary addresses.
Clients ask for temporary addresses and servers assign them. Temporary addresses are carried in the Identity Association for Temporary Addresses (IA_TA) option (see Section 23.5). Each IA_TA option contains at most one temporary address for each of the prefixes on the link to which the client is attached.
The lifetime of the assigned temporary address is set in the IA Address Option (see Section 23.6) with in the IA_TA option. It is RECOMMENDED to set short lifetimes, typically shorter than TEMP_VALID_LIFETIME and TEMP_PREFERRED_LIFETIME (see Section 5, [RFC4941].
The IAID number space for the IA_TA option IAID number space is separate from the IA_NA option IAID number space.
A DHCPv6 server implementation MAY generate temporary addresses referring to the algorithm defined in Section 3.2.1, [RFC4941], with additional condition that the new address is not duplicated with any assigned addresses.
The server MAY update the DNS for a temporary address, as described in section 4 of [RFC4941].
On the clients, by default, temporary addresses are preferred in source address selection, according to Rule 7, [RFC6724]. However, this policy is overridable.
One of the most important properties of temporary address is unlinkability of different actions over time. So, it is NOT RECOMMENDED for a client to renew expired temporary addresses, though DHCPv6 provides such possibility (see Section 23.5).
Unless otherwise specified in this document, or in a document that describes how IPv6 is carried over a specific type of link (for link types that do not support multicast), a client sends DHCP messages to the All_DHCP_Relay_Agents_and_Servers.
A client uses multicast to reach all servers or an individual server. An individual server is indicated by specifying that server's DUID in a Server Identifier option (see Section 23.3) in the client's message (all servers will receive this message but only the indicated server will respond). All servers are indicated by not supplying this option.
A client may send some messages directly to a server using unicast, as described in Section 23.12.
In order to avoid prolonged message bursts that may be caused by possible logic loops, a DHCPv6 client MUST limit the rate of DHCPv6 messages it transmits. One example is that a client obtains an address, but does not like the response; it reverts back to Solicit procedure, discovers the same (sole) server, requests an address and gets the same address as before (the server still has the lease that was requested just previously). This loops can repeat infinitely if there is not a quit/stop mechanism. Therefore, a client must not initiate transmissions too frequently.
A recommended method for implementing the rate limiting function is a token bucket, limiting the average rate of transmission to a certain number in a certain time. This method of bounding burstiness also guarantees that the long-term transmission rate will not exceed.
The Transmission Rate Limit parameter (TRT) SHOULD be configurable. A possible default could be 20 packets in 20 seconds.
For a device that has multiple interfaces, the limit MUST be enforced on a per interface basis.
Rate limiting of forwarded DHCPv6 messages and server-side messages are out of scope of this specification.
In certain cases, T1 and/or T2 timers may be set to zero. Currently there are three such cases: 1. a client received IA_NA option with zeroed values; 2. a client received IA_PD option with zeroed values; 3. a client received IA_TA option (which does not contain T1 or T2 fields). Additional cases may appear in the future. This is an indication that the transmission times are left at client's discretion. They are not completely discretionary, though.
When T1 and/or T2 timers are set to zero, client MUST choose transmission time to avoid packet storms. In particular, it MUST NOT transmit immediately. If the client received multiple IA containers, it SHOULD pick renew and/or rebind transmission time so all IA containers are received in one exchange, if possible. Client MUST choose the transmission times to not violate rate limiting restrictions, defined in Section 14.1.
DHCP clients are responsible for reliable delivery of messages in the client-initiated message exchanges described in Section 18 and Section 19. If a DHCP client fails to receive an expected response from a server, the client must retransmit its message. This section describes the retransmission strategy to be used by clients in client-initiated message exchanges.
Note that the procedure described in this section is slightly modified when used with the Solicit message. The modified procedure is described in Section 18.1.2.
The client begins the message exchange by transmitting a message to the server. The message exchange terminates when either the client successfully receives the appropriate response or responses from a server or servers, or when the message exchange is considered to have failed according to the retransmission mechanism described below.
The client retransmission behavior is controlled and described by the following variables:
With each message transmission or retransmission, the client sets RT according to the rules given below. If RT expires before the message exchange terminates, the client recomputes RT and retransmits the message.
Each of the computations of a new RT include a randomization factor (RAND), which is a random number chosen with a uniform distribution between -0.1 and +0.1. The randomization factor is included to minimize synchronization of messages transmitted by DHCP clients.
The algorithm for choosing a random number does not need to be cryptographically sound. The algorithm SHOULD produce a different sequence of random numbers from each invocation of the DHCP client.
RT for the first message transmission is based on IRT:
RT = IRT + RAND*IRT
RT for each subsequent message transmission is based on the previous value of RT:
RT = 2*RTprev + RAND*RTprev
MRT specifies an upper bound on the value of RT (disregarding the randomization added by the use of RAND). If MRT has a value of 0, there is no upper limit on the value of RT. Otherwise:
if (RT > MRT) RT = MRT + RAND*MRT
MRC specifies an upper bound on the number of times a client may retransmit a message. Unless MRC is zero, the message exchange fails once the client has transmitted the message MRC times.
MRD specifies an upper bound on the length of time a client may retransmit a message. Unless MRD is zero, the message exchange fails once MRD seconds have elapsed since the client first transmitted the message.
If both MRC and MRD are non-zero, the message exchange fails whenever either of the conditions specified in the previous two paragraphs are met.
If both MRC and MRD are zero, the client continues to transmit the message until it receives a response.
A client is not expected to listen for a response during the entire period between transmission of Solicit or Information-request messages.
Clients and servers might get messages that contain options not allowed to appear in the received message. For example, an IA option is not allowed to appear in an Information-request message. Clients and servers MAY choose either to extract information from such a message if the information is of use to the recipient, or to ignore such message completely and just drop it.
If a server receives a message that contains options it should not contain (such as an Information-request message with an IA option), is missing options that it should contain, or is otherwise not valid, it MAY send a Reply (or Advertise as appropriate) with a Server Identifier option, a Client Identifier option if one was included in the message and a Status Code option with status UnSpecFail.
Clients, relay agents and servers MUST NOT discard messages that contain unknown options (or instances of vendor options with unknown enterprise-numbers). These should be ignored as if they weren't present.
A server MUST discard any Solicit, Confirm, Rebind or Information-request messages it receives with a unicast destination address.
A client or server MUST silently discard any received DHCPv6 messages with an unknown message type.
The "transaction-id" field holds a value used by clients and servers to synchronize server responses to client messages. A client SHOULD generate a random number that cannot easily be guessed or predicted to use as the transaction ID for each new message it sends. Note that if a client generates easily predictable transaction identifiers, it may become more vulnerable to certain kinds of attacks from off-path intruders. A client MUST leave the transaction ID unchanged in retransmissions of a message.
Clients MUST discard any received Solicit messages.
Servers MUST discard any Solicit messages that do not include a Client Identifier option or that do include a Server Identifier option.
Clients MUST discard any received Advertise message that meets any of the following conditions:
Servers and relay agents MUST discard any received Advertise messages.
Clients MUST discard any received Request messages.
Servers MUST discard any received Request message that meets any of the following conditions:
Clients MUST discard any received Confirm messages.
Servers MUST discard any received Confirm messages that do not include a Client Identifier option or that do include a Server Identifier option.
Clients MUST discard any received Renew messages.
Servers MUST discard any received Renew message that meets any of the following conditions:
Clients MUST discard any received Rebind messages.
Servers MUST discard any received Rebind messages that do not include a Client Identifier option or that do include a Server Identifier option.
Clients MUST discard any received Decline messages.
Servers MUST discard any received Decline message that meets any of the following conditions:
Clients MUST discard any received Release messages.
Servers MUST discard any received Release message that meets any of the following conditions:
Clients MUST discard any received Reply message that meets any of the following conditions:
If the client included a Client Identifier option in the original message, the Reply message MUST include a Client Identifier option and the contents of the Client Identifier option MUST match the DUID of the client; OR, if the client did not include a Client Identifier option in the original message, the Reply message MUST NOT include a Client Identifier option.
Servers and relay agents MUST discard any received Reply messages.
Servers and relay agents MUST discard any received Reconfigure messages.
Clients MUST discard any Reconfigure message that meets any of the following conditions:
Clients MUST discard any received Information-request messages.
Servers MUST discard any received Information-request message that meets any of the following conditions:
Clients MUST discard any received Relay-forward messages.
Clients and servers MUST discard any received Relay-reply messages.
Client's behavior is different depending on the purpose of the configuration.
When a client sends a DHCP message to the All_DHCP_Relay_Agents_and_Servers address, it SHOULD send the message through the interface for which configuration information is being requested. However, the client MAY send the message through another interface if the interface is a logical interface without direct link attachment or the client is certain that two interfaces are attached to the same link.
When a client sends a DHCP message directly to a server using unicast (after receiving the Server Unicast option from that server), the source address in the header of the IPv6 datagram MUST be an address assigned to the interface for which the client is interested in obtaining configuration and which is suitable for use by the server in responding to the client.
Delegated prefixes are not associated with a particular interface in the same way as addresses are for address assignment, and mentioned above.
When a client (acting as requesting router) sends a DHCP message for the purpose of prefix delegation, it SHOULD be sent on the interface associated with the upstream router (ISP network). The upstream interface is typically determined by configuration. This rule applies even in the case where a separate IA_PD is used for each downstream interface.
When a requesting router sends a DHCP message directly to a delegating router using unicast (after receiving the Server Unicast option from that delegating router), the source address SHOULD be an address from the upstream interface and which is suitable for use by the delegating router in responding to the requesting router.
This section describes how a client locates servers that will assign addresses and delegated prefixes to IAs belonging to the client.
The client is responsible for creating IAs and requesting that a server assign IPv6 addresses and/or delegated prefixes to the IAs. The client first creates the IAs and assigns IAIDs to them. The client then transmits a Solicit message containing the IA options describing the IAs. The client MUST NOT be using any of the addresses or delegated prefixes for which it tries to obtain the bindings by sending the Solicit message. In particular, if the client had some valid bindings and has chosen to start the server solicitation process to obtain the bindings from a different server, the client MUST stop using the addresses and delegated prefixes for the bindings it had obtained from the previous server, and which it is now trying to obtain from a new server.
Servers that can assign addresses or delegated prefixes to the IAs respond to the client with an Advertise message. The client then initiates a configuration exchange as described in Section 19.
If the client will accept a Reply message with committed leases assignments and other resources in response to the Solicit message, the client includes a Rapid Commit option (see Section 23.14) in the Solicit message.
A client uses the Solicit message to discover DHCP servers configured to assign leases or return other configuration parameters on the link to which the client is attached.
The client sets the "msg-type" field to SOLICIT. The client generates a transaction ID and inserts this value in the "transaction-id" field.
The client MUST include a Client Identifier option to identify itself to the server. The client includes IA options for any IAs to which it wants the server to assign leases.
The client MAY include addresses in the IA_NA and IA_TA options as hints to the server about the addresses for which the client has a preference.
The client MAY include values in the IA Prefix option encapsulated within IA_PD option as hints for the delegated prefix and/or prefix length for which the client has a preference.
The client MUST NOT include any other options in the Solicit message, except as specifically allowed in the definition of individual options.
The client uses IA_NA options to request the assignment of non-temporary addresses, IA_TA options to request the assignment of temporary addresses and IA_PD options to request prefix delegation. Either IA_NA, IA_TA or IA_PD options, or a combination of all, can be included in DHCP messages. In addition, multiple instances of any IA option type can be included.
The client MUST include an Option Request option (see Section 23.7) to request the SOL_MAX_RT option (see Section 23.23) and any other options the client is interested in receiving. The client MAY additionally include instances of those options that are identified in the Option Request option, with data values as hints to the server about parameter values the client would like to have returned.
The client includes a Reconfigure Accept option (see Section 23.20) if the client is willing to accept Reconfigure messages from the server.
The first Solicit message from the client on the interface MUST be delayed by a random amount of time between 0 and SOL_MAX_DELAY. In the case of a Solicit message transmitted when DHCP is initiated by IPv6 Neighbor Discovery, the delay gives the amount of time to wait after IPv6 Neighbor Discovery causes the client to invoke the stateful address autoconfiguration protocol (see section 5.5.3 of [RFC4862]). This random delay desynchronizes clients which start at the same time (for example, after a power outage).
The client transmits the message according to Section 15, using the following parameters:
If the client has included a Rapid Commit option in its Solicit message, the client terminates the waiting process as soon as a Reply message with a Rapid Commit option is received.
If the client is waiting for an Advertise message, the mechanism in Section 15 is modified as follows for use in the transmission of Solicit messages. The message exchange is not terminated by the receipt of an Advertise before the first RT has elapsed. Rather, the client collects Advertise messages until the first RT has elapsed. Also, the first RT MUST be selected to be strictly greater than IRT by choosing RAND to be strictly greater than 0.
A client MUST collect Advertise messages for the first RT seconds, unless it receives an Advertise message with a preference value of 255. The preference value is carried in the Preference option (Section 23.8). Any Advertise that does not include a Preference option is considered to have a preference value of 0. If the client receives an Advertise message that includes a Preference option with a preference value of 255, the client immediately begins a client-initiated message exchange (as described in Section 19) by sending a Request message to the server from which the Advertise message was received. If the client receives an Advertise message that does not include a Preference option with a preference value of 255, the client continues to wait until the first RT elapses. If the first RT elapses and the client has received an Advertise message, the client SHOULD continue with a client-initiated message exchange by sending a Request message.
If the client does not receive any Advertise messages before the first RT has elapsed, it begins the retransmission mechanism described in Section 15. The client terminates the retransmission process as soon as it receives any Advertise message, and the client acts on the received Advertise message without waiting for any additional Advertise messages.
A DHCP client SHOULD choose MRC and MRD to be 0. If the DHCP client is configured with either MRC or MRD set to a value other than 0, it MUST stop trying to configure the interface if the message exchange fails. After the DHCP client stops trying to configure the interface, it SHOULD restart the reconfiguration process after some external event, such as user input, system restart, or when the client is attached to a new link.
The client MUST process SOL_MAX_RT and INF_MAX_RT options in an Advertise message, even if the message contains a Status Code option indicating a failure, and the Advertise message will be discarded by the client.
The client MUST ignore any Advertise message that contains no addresses (IAADDR options encapsulated in IA_NA or IA_TA options) and no delegated prefixes (IAPREFIX options encapsulated in IA_PD options) with the exception that the client:
A client can display any associated status message(s) to the user or activity log.
The client ignoring this Advertise message MUST NOT restart the Solicit retransmission timer.
Upon receipt of one or more valid Advertise messages, the client selects one or more Advertise messages based upon the following criteria.
Once a client has selected Advertise message(s), the client will typically store information about each server, such as server preference value, addresses advertised, when the advertisement was received, and so on.
In practice, this means that the client will maintain independent per-IA state machines per each selected server.
If the client needs to select an alternate server in the case that a chosen server does not respond, the client chooses the next server according to the criteria given above.
If the client includes a Rapid Commit option in the Solicit message, it will expect a Reply message that includes a Rapid Commit option in response. The client discards any Reply messages it receives that do not include a Rapid Commit option. If the client receives a valid Reply message that includes a Rapid Commit option, it processes the message as described in Section 19.1.8. If it does not receive such a Reply message and does receive a valid Advertise message, the client processes the Advertise message as described in Section 18.1.3.
If the client subsequently receives a valid Reply message that includes a Rapid Commit option, it either:
A server sends an Advertise message in response to valid Solicit messages it receives to announce the availability of the server to the client.
The server determines the information about the client and its location as described in Section 12 and checks its administrative policy about responding to the client. If the server is not permitted to respond to the client, the server discards the Solicit message. For example, if the administrative policy for the server is that it may only respond to a client that is willing to accept a Reconfigure message, if the client does not include a Reconfigure Accept option (see Section 23.20) in the Solicit message, the servers discard the Solicit message.
If the client has included a Rapid Commit option in the Solicit message and the server has been configured to respond with committed lease assignments and other resources, the server responds to the Solicit with a Reply message as described in Section 18.2.3. Otherwise, the server ignores the Rapid Commit option and processes the remainder of the message as if no Rapid Commit option were present.
The server sets the "msg-type" field to ADVERTISE and copies the contents of the transaction-id field from the Solicit message received from the client to the Advertise message. The server includes its server identifier in a Server Identifier option and copies the Client Identifier from the Solicit message into the Advertise message.
The server MAY add a Preference option to carry the preference value for the Advertise message. The server implementation SHOULD allow the setting of a server preference value by the administrator. The server preference value MUST default to zero unless otherwise configured by the server administrator.
The server includes a Reconfigure Accept option if the server wants to require that the client accept Reconfigure messages.
The server includes options the server will return to the client in a subsequent Reply message. The information in these options may be used by the client in the selection of a server if the client receives more than one Advertise message. If the client has included an Option Request option in the Solicit message, the server includes options in the Advertise message containing configuration parameters for all of the options identified in the Option Request option that the server has been configured to return to the client. The server MAY return additional options to the client if it has been configured to do so. The server must be aware of the recommendations on packet sizes and the use of fragmentation in section 5 of [RFC2460].
If the Solicit message from the client included one or more IA options, the server MUST include IA options in the Advertise message containing any addresses and/or delegated prefixes that would be assigned to IAs contained in the Solicit message from the client. If the client has included addresses in the IA in the Solicit message, the server MAY use those addresses as hints about the addresses that the client would like to receive. If the client has included IA Prefix option in the IA_PD, the server MAY use the prefix contained in the IPv6 prefix field and/or the prefix length contained in the "prefix-length" field as a hints about the prefixes the client would like to receive. If the server is not going to assign an address or delegated prefix received as a hint in the Solicit message, the server MUST NOT include this address or delegated prefix in the Advertise message
If the server will not assign any addresses to an IA (IA_NA or IA_IA) in subsequent Request from the client, the server MUST include the IA in the Advertise message with no addresses in the IA and a Status Code option encapsulated in the IA containing status code NoAddrsAvail.
If the server will not assign any prefixes to an IA_PD in subsequent Request from the client, the server MUST include the IA_PD in the Advertise message with no prefixes in the IA and a Status Code option encapsulated in the IA_PD containing status code NoPrefixAvail.
If the Solicit message was received directly by the server, the server unicasts the Advertise message directly to the client using the address in the source address field from the IP datagram in which the Solicit message was received. The Advertise message MUST be unicast on the link from which the Solicit message was received.
If the Solicit message was received in a Relay-forward message, the server constructs a Relay-reply message with the Advertise message in the payload of a "relay-message" option. If the Relay-forward messages included an Interface-id option, the server copies that option to the Relay-reply message. The server unicasts the Relay-reply message directly to the relay agent using the address in the source address field from the IP datagram in which the Relay-forward message was received.
The server MUST commit the assignment of any addresses or other configuration information message before sending a Reply message to a client in response to a Solicit message.
DISCUSSION:
The server includes a Rapid Commit option in the Reply message to indicate that the Reply is in response to a Solicit message.
The server includes a Reconfigure Accept option if the server wants to require that the client accept Reconfigure messages.
The server produces the Reply message as though it had received a Request message, as described in Section 19.2.1. The server transmits the Reply message as described in Section 19.2.8.
A client initiates a message exchange with a server or servers to acquire or update configuration information of interest. The client may initiate the configuration exchange as part of the operating system configuration process, when requested to do so by the application layer, when required by Stateless Address Autoconfiguration or as required to extend the lifetime of address(es) and/or delegated prefix(es), using Renew and Rebind messages.
According to a terminology for the prefix delegation, a client requesting a delegation of a prefix is referred to as a requesting router and a server delegating the prefix is referred to as a delegating router. The requesting router and the delegating router use the IA_PD Prefix option to exchange information about prefix(es) in much the same way as IA Address options are used for assigned addresses. Typically, a single DHCP session is used to exchange information about addresses and prefixes, i.e. IA_NA and IA_PD options are carried in the same message.
A client uses Request, Renew, Rebind, Release and Decline messages during the normal life cycle of addresses and delegated prefixes. When a client detects it may have moved to a new link, it uses Confirm if it only has addresses and Rebind if it has delegated prefixes (and addresses). It uses Information-request messages when it needs configuration information but no addresses and no prefixes.
If the client has a source address of sufficient scope that can be used by the server as a return address, and the client has received a Server Unicast option (Section 23.12) from the server, the client SHOULD unicast any Request, Renew, Release and Decline messages to the server.
DISCUSSION:
The client uses a Request message to populate IAs with leases and obtain other configuration information. The client includes one or more IA options in the Request message. The server then returns leases and other information about the IAs to the client in IA options in a Reply message.
The client generates a transaction ID and inserts this value in the "transaction-id" field.
The client places the identifier of the destination server in a Server Identifier option.
The client MUST include a Client Identifier option to identify itself to the server. The client adds any other appropriate options, including one or more IA options (if the client is requesting that the server assign it some network addresses or delegated prefixes).
The client MUST include an Option Request option (see Section 23.7) to indicate the options the client is interested in receiving. The client MAY include options with data values as hints to the server about parameter values the client would like to have returned.
The client includes a Reconfigure Accept option (see Section 23.20) indicating whether or not the client is willing to accept Reconfigure messages from the server.
The client transmits the message according to Section 15, using the following parameters:
If the message exchange fails, the client takes an action based on the client's local policy. Examples of actions the client might take include:
Whenever a client may have moved to a new link, the prefixes/addresses assigned to the interfaces on that link may no longer be appropriate for the link to which the client is attached. Examples of times when a client may have moved to a new link include:
In any situation when a client may have moved to a new link and the client does not have any delegated prefixes obtained from the DHCP server from which it has obtained the addresses, the client SHOULD initiate a Confirm/Reply message exchange. The client includes any IAs assigned to the interface that may have moved to a new link, along with the addresses associated with those IAs, in its Confirm message. Any responding servers will indicate whether those addresses are appropriate for the link to which the client is attached with the status in the Reply message it returns to the client.
If the client has any valid delegated prefixes obtained from the DHCP server from which it has obtained the addresses, the client initiates Rebind/Reply exchange as described in Section 19.1.9 instead of sending the Confirm message.
The client sets the "msg-type" field to CONFIRM. The client generates a transaction ID and inserts this value in the "transaction-id" field.
The client MUST include a Client Identifier option to identify itself to the server. The client includes IA options for all of the IAs assigned to the interface for which the Confirm message is being sent. The IA options include all of the addresses the client currently has associated with those IAs. The client SHOULD set the T1 and T2 fields in any IA_NA options and the preferred-lifetime and valid-lifetime fields in the IA Address options to 0, as the server will ignore these fields.
The first Confirm message from the client on the interface MUST be delayed by a random amount of time between 0 and CNF_MAX_DELAY. The client transmits the message according to Section 15, using the following parameters:
If the client receives no responses before the message transmission process terminates, as described in Section 15, the client SHOULD continue to use any IP addresses, using the last known lifetimes for those addresses, and SHOULD continue to use any other previously obtained configuration parameters.
To extend the valid and preferred lifetimes for the leases assigned to the IAs, the client sends a Renew message to the server from which the leases were obtained, which includes IA options for the IAs whose lease lifetimes are to be extended. The client includes IA Address options within IA_NA and IA_TA options for the addresses assigned to the IAs. The client includes IA Prefix options within IA_PD options for the delegated prefixes assigned to the IAs. The server determines new lifetimes for the leases according to the administrative configuration of the server. The server may also add leases to the IAs. The server can remove leases from the IAs by returning IA Address options (for IA_NA and IA_TA) and IA Prefix options (for IA_PD) with preferred and valid lifetimes set to 0.
The server controls the time at which the client contacts the server to extend the lifetimes on assigned leases through the T1 and T2 parameters assigned to an IA. However, as the client Renews/Rebinds all IAs from the server at the same time, the client MUST select a T1 and T2 time from all IA options, which will guarantee that the client will send Renew/Rebind messages not later than at the T1/T2 times associated with any of the client's bindings.
At time T1, the client initiates a Renew/Reply message exchange to extend the lifetimes on any leases in the IA.
If T1 or T2 had been set to 0 by the server (for an IA_NA or IA_PD) or there are no T1 or T2 times (for an IA_TA) in a previous Reply, the client may send a Renew or Rebind message, respectively, at the client's discretion. The client MUST follow the rules defined in Section 14.2.
The client sets the "msg-type" field to RENEW. The client generates a transaction ID and inserts this value in the "transaction-id" field.
The client places the identifier of the destination server in a Server Identifier option.
The client MUST include a Client Identifier option to identify itself to the server. The client adds any appropriate options, including one or more IA options.
For IAs to which leases have been assigned, the client includes a corresponding IA option containing an IA Address option for each address assigned to the IA and IA Prefix option for each prefix assigned to the IA. The client MUST NOT include addresses and prefixes in any IA option that the client did not obtain from the server or that are no longer valid (that have a valid lifetime of 0).
The client MAY include an IA option for each binding it desires but has been unable to obtain. In this case, if the client includes the IA_PD option to request prefix delegation, the client MAY include the IA Prefix option encapsulated within the IA_PD option, with the IPv6 prefix field set to 0 and the "prefix-length" field set to the desired length of the prefix to be delegated. The server MAY use this value as a hint for the prefix length. The client SHOULD NOT include IA Prefix option with the IPv6 prefix field set to 0 unless it is supplying a hint for the prefix length.
The client MUST include an Option Request option (see Section 23.7) to indicate the options the client is interested in receiving. The client MAY include options with data values as hints to the server about parameter values the client would like to have returned.
The client transmits the message according to Section 15, using the following parameters:
The message exchange is terminated when time T2 is reached (see Section 19.1.4), at which time the client begins a Rebind message exchange.
At time T2 (which will only be reached if the server to which the Renew message was sent at time T1 has not responded), the client initiates a Rebind/Reply message exchange with any available server.
The client constructs the Rebind message as described in Section 18.1.3 with the following differences:
The client transmits the message according to Section 15, using the following parameters:
If all leases for an IA have expired, the client may choose to include this IA in subsequent Rebind messages to indicate that the client is interested in assignment of the leases to this IA.
The message exchange is terminated when the valid lifetimes of all leases across all IAs have expired, at which time the client uses the Solicit message to locate a new DHCP server and sends a Request for the expired IAs to the new server.
The client uses an Information-request message to obtain configuration information without having addresses and/or delegated prefixes assigned to it.
The client sets the "msg-type" field to INFORMATION-REQUEST. The client generates a transaction ID and inserts this value in the "transaction-id" field.
The client SHOULD include a Client Identifier option to identify itself to the server. If the client does not include a Client Identifier option, the server will not be able to return any client-specific options to the client, or the server may choose not to respond to the message at all. The client MUST include a Client Identifier option if the Information-request message will be authenticated.
The client MUST include an Option Request option (see Section 23.7) to request the INF_MAX_RT option (see Section 23.24) and any other options the client is interested in receiving. The client MAY include options with data values as hints to the server about parameter values the client would like to have returned.
The first Information-request message from the client on the interface MUST be delayed by a random amount of time between 0 and INF_MAX_DELAY. The client transmits the message according to Section 15, using the following parameters:
To release one or more leases, a client sends a Release message to the server.
The client sets the "msg-type" field to RELEASE. The client generates a transaction ID and places this value in the "transaction-id" field.
The client places the identifier of the server that allocated the lease(s) in a Server Identifier option.
The client MUST include a Client Identifier option to identify itself to the server. The client includes options containing the IAs for the leases it is releasing in the "options" field. The leases to be released MUST be included in the IAs. Any leases for the IAs the client wishes to continue to use MUST NOT be added to the IAs.
The client MUST NOT use any of the addresses it is releasing as the source address in the Release message or in any subsequently transmitted message.
Because Release messages may be lost, the client should retransmit the Release if no Reply is received. However, there are scenarios where the client may not wish to wait for the normal retransmission timeout before giving up (e.g., on power down). Implementations SHOULD retransmit one or more times, but MAY choose to terminate the retransmission procedure early.
The client transmits the message according to Section 15, using the following parameters:
The client MUST stop using all of the leases being released before the client begins the Release message exchange process. For an address, this means the address MUST have been removed from the interface. For a delegated prefix, this means the prefix MUST have been advertised with a Preferred Lifetime and a Valid Lifetime of zero in a Router Advertisement message as described in Section 5.5.3, (e) of [RFC4862] - also see L-13 in Section 4.3 of [RFC7084].
If leases are released but the Reply from a DHCP server is lost, the client will retransmit the Release message, and the server may respond with a Reply indicating a status of NoBinding. Therefore, the client does not treat a Reply message with a status of NoBinding in a Release message exchange as if it indicates an error.
Note that if the client fails to release the lease, each lease assigned to the IA will be reclaimed by the server when the valid lifetime of that lease expires.
If a client detects that one or more addresses assigned to it by a server are already in use by another node, the client sends a Decline message to the server to inform it that the address is suspect.
The Decline message is not used in prefix delegation and thus the client MUST NOT include IA_PD options in the Decline message.
The client sets the "msg-type" field to DECLINE. The client generates a transaction ID and places this value in the "transaction-id" field.
The client places the identifier of the server that allocated the address(es) in a Server Identifier option.
The client MUST include a Client Identifier option to identify itself to the server. The client includes options containing the IAs for the addresses it is declining in the "options" field. The addresses to be declined MUST be included in the IAs. Any addresses for the IAs the client wishes to continue to use should not be in added to the IAs.
The client MUST NOT use any of the addresses it is declining as the source address in the Decline message or in any subsequently transmitted message.
The client transmits the message according to Section 15, using the following parameters:
If addresses are declined but the Reply from a DHCP server is lost, the client will retransmit the Decline message, and the server may respond with a Reply indicating a status of NoBinding. Therefore, the client does not treat a Reply message with a status of NoBinding in a Decline message exchange as if it indicates an error.
The client SHOULD NOT send a Release message for other bindings it may have received just because it sent a Decline message. The client SHOULD retain the non-conflicting bindings. The client SHOULD treat the failure to acquire a binding as a result of the conflict, to be equivalent to not having received the binding, insofar as it behaves when sending Renew and Rebind messages.
Upon the receipt of a valid Reply message in response to a Solicit (with a Rapid Commit option), Request, Confirm, Renew, Rebind, or Information-request message, the client extracts the top-level Status Code option if present.
If the client receives a Reply message with a status code of UnspecFail, the server is indicating that it was unable to process the message due to an unspecified failure condition. If the client retransmits the original message to the same server to retry the desired operation, the client MUST limit the rate at which it retransmits the message and limit the duration of the time during which it retransmits the message (see Section 14.1).
If the client receives a Reply message with a status code of UseMulticast, the client records the receipt of the message and sends subsequent messages to the server through the interface on which the message was received using multicast. The client resends the original message using multicast.
Otherwise (no status code or another status code), the client processes the Reply as described below based on the original message for which the Reply was received.
The client MAY choose to report any status code or message from the Status Code option in the Reply message.
If the client receives a NotOnLink status from the server in response to a Solicit (with a Rapid Commit option) or a Request, the client can either re-issue the message without specifying any addresses or restart the DHCP server discovery process (see Section 18).
If the Reply was received in response to a Solicit (with a Rapid Commit option), Request, Renew, or Rebind message, the client updates the information it has recorded about IAs from the IA options contained in the Reply message:
If the client can operate with the addresses and/or prefixes obtained from the server:
Management of the specific configuration information is detailed in the definition of each option in Section 23.
If the Reply message contains any IAs, but the client finds no usable addresses and/or delegated prefixes in any of these IAs, the client may either try another server (perhaps restarting the DHCP server discovery process) or use the Information-request message to obtain other configuration information only.
When the client receives a Reply message in response to a Renew or Rebind message, the client:
Whenever a client restarts the DHCP server discovery process or selects an alternate server, as described in Section 18.1.3, the client SHOULD stop using all the addresses and delegated prefixes for which it has the bindings and try to obtain all required leases from the new server. This facilitates the client using a single state machine for all bindings.
When the client receives a valid Reply message in response to a Release message, the client considers the Release event completed, regardless of the Status Code option(s) returned by the server.
When the client receives a valid Reply message in response to a Decline message, the client considers the Decline event completed, regardless of the Status Code option(s) returned by the server.
When the client receives a NotOnLink status from the server in response to a Confirm message, the client performs DHCP server solicitation, as described in Section 18, and client-initiated configuration, as described in Section 19. If the client receives any Reply messages that indicate a success status (explicit or implicit), the client can use the addresses in the IA and ignore any messages that indicate a NotOnLink status.
In some circumstances the requesting router may need verification that the delegating router still has a valid binding for the requesting router. Examples of times when a requesting router may ask for such verification include:
If such verification is needed the requesting router MUST initiate a Rebind/Reply message exchange as described in Section 19.1.4, with the exception that the retransmission parameters should be set as for the Confirm message, described in Section 19.1.2. The requesting router includes any IA_PDs, along with prefixes associated with those IA_PDs in its Rebind message.
For this discussion, the Server is assumed to have been configured in an implementation specific manner with configuration of interest to clients.
In most instances, the server will send a Reply in response to a client message. This Reply message MUST always contain the Server Identifier option containing the server's DUID and the Client Identifier option from the client message if one was present.
In most Reply messages, the server includes options containing configuration information for the client. The server must be aware of the recommendations on packet sizes and the use of fragmentation in section 5 of [RFC2460]. If the client included an Option Request option in its message, the server includes options in the Reply message containing configuration parameters for all of the options identified in the Option Request option that the server has been configured to return to the client. The server MAY return additional options to the client if it has been configured to do so.
When the server receives a Request message via unicast from a client to which the server has not sent a unicast option (or is not currently configured to send a unicast option to the client), the server discards the Request message and responds with a Reply message containing a Status Code option with the value UseMulticast, a Server Identifier option containing the server's DUID, the Client Identifier option from the client message, and no other options.
When the server receives a valid Request message, the server creates the bindings for that client according to the server's policy and configuration information and records the IAs and other information requested by the client.
The server constructs a Reply message by setting the "msg-type" field to REPLY, and copying the transaction ID from the Request message into the transaction-id field.
The server MUST include a Server Identifier option containing the server's DUID and the Client Identifier option from the Request message in the Reply message.
The server examines all IAs in the message from the client.
For each IA_NA and IA_TA the server checks if the prefixes on included IP addresses are appropriate for the link to which the client is connected. If any of the prefixes on the included IP addresses is not appropriate for the link to which the client is connected, the server MUST return the IA to the client with a Status Code option with the value NotOnLink. If the server does not send the NotOnLink status code but it cannot assign any IP addresses to an IA, the server MUST return the IA in the Reply message with no addresses in the IA and a Status Code option containing status code NoAddrsAvail.
For any IA_PD to which the server cannot assign any delegated prefixes, the server MUST return the IA_PD option in the Reply message with the Status Code option containing status code NoPrefixAvail.
The server MAY assign different addresses and/or delegated prefixes to an IA than included in the IA within the Request message sent by the client.
For all IAs to which the server can assign addresses or delegated prefixes, the server includes the IAs with addresses (for IA_NA and IA_TA), prefixes (for IA_PD) and other configuration parameters, and records the IA as a new client binding. The server MUST NOT include any addresses or delegated prefixes in the IA which the server does not assign to the client.
The server includes a Reconfigure Accept option if the server wants to require that the client accept Reconfigure messages.
The server includes other options containing configuration information to be returned to the client as described in Section 19.2.
If the server finds that the client has included an IA in the Request message for which the server already has a binding that associates the IA with the client, the server sends a new Reply message with existing bindings, possibly with updated lifetimes. The server may update the bindings according to its local policies, but the server SHOULD generate the response again and not simply retransmit previously sent information, even if the transaction-id matches previous transmission. The server MUST NOT cache its responses.
When the server receives a Confirm message, the server determines whether the addresses in the Confirm message are appropriate for the link to which the client is attached. If all of the addresses in the Confirm message pass this test, the server returns a status of Success. If any of the addresses do not pass this test, the server returns a status of NotOnLink. If the server is unable to perform this test (for example, the server does not have information about prefixes on the link to which the client is connected), or there were no addresses in any of the IAs sent by the client, the server MUST NOT send a Reply to the client.
The server ignores the T1 and T2 fields in the IA options and the preferred-lifetime and valid-lifetime fields in the IA Address options.
The server constructs a Reply message by setting the "msg-type" field to REPLY, and copying the transaction ID from the Confirm message into the transaction-id field.
The server MUST include a Server Identifier option containing the server's DUID and the Client Identifier option from the Confirm message in the Reply message. The server includes a Status Code option indicating the status of the Confirm message.
When the server receives a Renew message via unicast from a client to which the server has not sent a unicast option (or is not currently configured to send a unicast option to the client), the server discards the Renew message and responds with a Reply message containing a Status Code option with the value UseMulticast, a Server Identifier option containing the server's DUID, the Client Identifier option from the client message, and no other options.
For each IA in the Renew message from a client, the server locates the client's binding and verifies that the information in the IA from the client matches the information stored for that client.
If the server finds the client entry for the IA, the server sends back the IA to the client with new lifetimes and, if applicable, T1/T2 times. If the server is unable to extend the lifetimes of an address or delegated prefix in the IA, the server MAY choose not to include the IA Address or IA Prefix option for this address or delegated prefix.
The server may choose to change the list of addresses or delegated prefixes and the lifetimes in IAs that are returned to the client.
If the server finds that any of the addresses in the IA are not appropriate for the link to which the client is attached, the server returns the address to the client with lifetimes of 0.
If the server finds that any of the delegated prefixes in the IA are not appropriate for the link to which the client is attached, the server returns the delegated prefix to the client with lifetimes of 0.
For each IA for which the server cannot find a client entry, the server has the following choices depending on the server's policy and configuration information:
The server constructs a Reply message by setting the "msg-type" field to REPLY and copying the transaction ID from the Renew message into the "transaction-id" field.
The server MUST include a Server Identifier option containing the server's DUID and the Client Identifier option from the Renew message in the Reply message.
The server includes other options containing configuration information to be returned to the client as described in Section 19.2.
The T1/T2 times set in each applicable IA option for a Reply MUST be the same values across all IAs. The server MUST determine the T1/T2 times across all of the applicable client's bindings in the Reply. This facilitates the client being able to renew all of the bindings at the same time.
When the server receives a Rebind message that contains an IA option from a client, it locates the client's binding and verifies that the information in the IA from the client matches the information stored for that client.
If the server finds the client entry for the IA and the server determines that the addresses or delegated prefixes in the IA are appropriate for the link to which the client's interface is attached according to the server's explicit configuration information, the server SHOULD send back the IA to the client with new lifetimes and, if applicable, T1/T2 times. If the server is unable to extend the lifetimes of an address in the IA, the server MAY choose not to include the IA Address option for this address. If the server is unable to extend the lifetimes of a delegated prefix in the IA, the server MAY choose not to include the IA Prefix option for this prefix.
If the server finds that the client entry for the IA and any of the addresses or delegated prefixes are no longer appropriate for the link to which the client's interface is attached according to the server's explicit configuration information, the server returns the address or delegated prefix to the client with lifetimes of 0.
If the server cannot find a client entry for the IA, the server checks if the IA contains addresses (for IA_NA and IA_TA) or delegated prefixes (for IA_PD). The server checks if the addresses and delegated prefixes are appropriate for the link to which the client's interface is attached according to the server's explicit configuration information. For any address which is not appropriate for the link to which the client's interface is attached, the server MAY include the IA Address option with the lifetimes of 0. For any delegated prefix which is not appropriate for the link to which the client's interface is attached, the server MAY include the IA Prefix option with the lifetimes of 0. The Reply with lifetimes of 0 constitutes an explicit notification to the client that the specific addresses and delegated prefixes are no longer valid and MUST NOT be used by the client. In this situation, if the server does not send a Reply message, it silently discards the Rebind message.
Otherwise, for each IA for which the server cannot find a client entry, the server has the following choices depending on the server's policy and configuration information:
When the server creates new bindings for the IA, it is possible that other servers also create bindings as a result of receiving the same Rebind message. This is the same issue as in the Discussion under "Rapid Commit Option"; see Section 23.14. Therefore, the server SHOULD only create new bindings during processing of a Rebind message if the server is configured to respond with a Reply message to a Solicit message containing the Rapid Commit option.
The server constructs a Reply message by setting the "msg-type" field to REPLY and copying the transaction ID from the Rebind message into the "transaction-id" field.
The server MUST include a Server Identifier option containing the server's DUID and the Client Identifier option from the Rebind message in the Reply message.
The server includes other options containing configuration information to be returned to the client as described in Section 19.2.
The T1/T2 times set in each applicable IA option for a Reply MUST be the same values across all IAs. The server MUST determine the T1/T2 times across all of the applicable client's bindings in the Reply. This facilitates the client being able to renew all of the bindings at the same time.
When the server receives an Information-request message, the client is requesting configuration information that does not include the assignment of any leases. The server determines all configuration parameters appropriate to the client, based on the server configuration policies known to the server.
The server constructs a Reply message by setting the "msg-type" field to REPLY, and copying the transaction ID from the Information-request message into the transaction-id field.
The server MUST include a Server Identifier option containing the server's DUID in the Reply message. If the client included a Client Identification option in the Information-request message, the server copies that option to the Reply message.
The server includes options containing configuration information to be returned to the client as described in Section 19.2.
If the Information-request message received from the client did not include a Client Identifier option, the server SHOULD respond with a Reply message containing any configuration parameters that are not determined by the client's identity. If the server chooses not to respond, the client may continue to retransmit the Information-request message indefinitely.
When the server receives a Release message via unicast from a client to which the server has not sent a unicast option (or is not currently configured to send a unicast option to the client), the server discards the Release message and responds with a Reply message containing a Status Code option with value UseMulticast, a Server Identifier option containing the server's DUID, the Client Identifier option from the client message, and no other options.
Upon the receipt of a valid Release message, the server examines the IAs and the leases in the IAs for validity. If the IAs in the message are in a binding for the client, and the leases in the IAs have been assigned by the server to those IAs, the server deletes the leases from the IAs and makes the leases available for assignment to other clients. The server ignores leases not assigned to the IA, although it may choose to log an error.
After all the leases have been processed, the server generates a Reply message and includes a Status Code option with value Success, a Server Identifier option with the server's DUID, and a Client Identifier option with the client's DUID. For each IA in the Release message for which the server has no binding information, the server adds an IA option using the IAID from the Release message, and includes a Status Code option with the value NoBinding in the IA option. No other options are included in the IA option.
A server may choose to retain a record of assigned leases and IAs after the lifetimes on the leases have expired to allow the server to reassign the previously assigned leases to a client.
When the server receives a Decline message via unicast from a client to which the server has not sent a unicast option (or is not currently configured to send a unicast option to the client), the server discards the Decline message and responds with a Reply message containing a Status Code option with the value UseMulticast, a Server Identifier option containing the server's DUID, the Client Identifier option from the client message, and no other options.
Upon the receipt of a valid Decline message, the server examines the IAs and the addresses in the IAs for validity. If the IAs in the message are in a binding for the client, and the addresses in the IAs have been assigned by the server to those IAs, the server deletes the addresses from the IAs. The server ignores addresses not assigned to the IA (though it may choose to log an error if it finds such an address).
The client has found any addresses in the Decline messages to be already in use on its link. Therefore, the server SHOULD mark the addresses declined by the client so that those addresses are not assigned to other clients, and MAY choose to make a notification that addresses were declined. Local policy on the server determines when the addresses identified in a Decline message may be made available for assignment.
After all the addresses have been processed, the server generates a Reply message and includes a Status Code option with the value Success, a Server Identifier option with the server's DUID, and a Client Identifier option with the client's DUID. For each IA in the Decline message for which the server has no binding information, the server adds an IA option using the IAID from the Decline message and includes a Status Code option with the value NoBinding in the IA option. No other options are included in the IA option.
If the original message was received directly by the server, the server unicasts the Reply message directly to the client using the address in the source address field from the IP datagram in which the original message was received. The Reply message MUST be unicast through the interface on which the original message was received.
If the original message was received in a Relay-forward message, the server constructs a Relay-reply message with the Reply message in the payload of a Relay Message option (see Section 23.10). If the Relay-forward messages included an Interface-id option, the server copies that option to the Relay-reply message. The server unicasts the Relay-reply message directly to the relay agent using the address in the source address field from the IP datagram in which the Relay-forward message was received.
A server initiates a configuration exchange to cause DHCP clients to obtain new addresses and other configuration information. For example, an administrator may use a server-initiated configuration exchange when links in the DHCP domain are to be renumbered. Other examples include changes in the location of directory servers, addition of new services such as printing, and availability of new software.
A server sends a Reconfigure message to cause a client to initiate immediately a Renew/Reply or Information-request/Reply message exchange with the server.
The server sets the "msg-type" field to RECONFIGURE. The server sets the transaction-id field to 0. The server includes a Server Identifier option containing its DUID and a Client Identifier option containing the client's DUID in the Reconfigure message.
The server MAY include an Option Request option to inform the client of what information has been changed or new information that has been added. In particular, the server specifies the IA option in the Option Request option if the server wants the client to obtain new address information. If the server identifies the IA option in the Option Request option, the server MUST include an IA option to identify each IA that is to be reconfigured on the client. The IA options included by the server MUST NOT contain any options.
Because of the risk of denial of service attacks against DHCP clients, the use of a security mechanism is mandated in Reconfigure messages. The server MUST use DHCP authentication in the Reconfigure message.
The server MUST include a Reconfigure Message option (defined in Section 23.19) to select whether the client responds with a Renew message, a Rebind message, or an Information-request message.
The server MUST NOT include any other options in the Reconfigure except as specifically allowed in the definition of individual options.
A server sends each Reconfigure message to a single DHCP client, using an IPv6 unicast address of sufficient scope belonging to the DHCP client. If the server does not have an address to which it can send the Reconfigure message directly to the client, the server uses a Relay-reply message (as described in Section 21.3) to send the Reconfigure message to a relay agent that will relay the message to the client. The server may obtain the address of the client (and the appropriate relay agent, if required) through the information the server has about clients that have been in contact with the server, or through some external agent.
To reconfigure more than one client, the server unicasts a separate message to each client. The server may initiate the reconfiguration of multiple clients concurrently; for example, a server may send a Reconfigure message to additional clients while previous reconfiguration message exchanges are still in progress.
The Reconfigure message causes the client to initiate a Renew/Reply, a Rebind/Reply, or Information-request/Reply message exchange with the server. The server interprets the receipt of a Renew, a Rebind, or Information-request message (whichever was specified in the original Reconfigure message) from the client as satisfying the Reconfigure message request.
If the server does not receive a Renew, Rebind, or Information-request message from the client in REC_TIMEOUT milliseconds, the server retransmits the Reconfigure message, doubles the REC_TIMEOUT value and waits again. The server continues this process until REC_MAX_RC unsuccessful attempts have been made, at which point the server SHOULD abort the reconfigure process for that client.
Default and initial values for REC_TIMEOUT and REC_MAX_RC are documented in Section 6.5.
In response to a Renew message, the server generates and sends a Reply message to the client as described in Section 19.2.3 and Section 19.2.8, including options for configuration parameters.
In response to a Rebind message, the server generates and sends a Reply message to the client as described in Section 19.2.4 and Section 19.2.8, including options for configuration parameters.
The server MAY include options containing the IAs and new values for other configuration parameters in the Reply message, even if those IAs and parameters were not requested in the Renew or Rebind message from the client.
The server generates and sends a Reply message to the client as described in Section 19.2.5 and Section 19.2.8, including options for configuration parameters.
The server MAY include options containing new values for other configuration parameters in the Reply message, even if those parameters were not requested in the Information-request message from the client.
A client receives Reconfigure messages sent to the UDP port 546 on interfaces for which it has acquired configuration information through DHCP. These messages may be sent at any time. Since the results of a reconfiguration event may affect application layer programs, the client SHOULD log these events, and MAY notify these programs of the change through an implementation-specific interface.
Upon receipt of a valid Reconfigure message, the client responds with either a Renew message, a Rebind message, or an Information-request message as indicated by the Reconfigure Message option (as defined in Section 23.19). The client ignores the transaction-id field in the received Reconfigure message. While the transaction is in progress, the client discards any Reconfigure messages it receives.
DISCUSSION:
When responding to a Reconfigure, the client creates and sends the Renew message in exactly the same manner as outlined in Section 19.1.3, with the exception that the client copies the Option Request option and any IA options from the Reconfigure message into the Renew message. The client MUST include a Server Identifier option in the Renew message, identifying the server with which the client most recently communicated.
When responding to a Reconfigure, the client creates and sends the Rebind message in exactly the same manner as outlined in Section 19.1.4, with the exception that the client copies the Option Request option and any IA options from the Reconfigure message into the Rebind message.
If a client is currently sending Rebind messages, as described in Section 19.1.3, the client ignores any received Reconfigure messages.
When responding to a Reconfigure, the client creates and sends the Information-request message in exactly the same manner as outlined in Section 19.1.5, with the exception that the client includes a Server Identifier option with the identifier from the Reconfigure message to which the client is responding.
The client uses the same variables and retransmission algorithm as it does with Renew, Rebind, or Information-request messages generated as part of a client-initiated configuration exchange. See Section 19.1.3, Section 19.1.4, and Section 19.1.5 for details. If the client does not receive a response from the server by the end of the retransmission process, the client ignores and discards the Reconfigure message.
Upon the receipt of a valid Reply message, the client processes the options and sets (or resets) configuration parameters appropriately. The client records and updates the lifetimes for any addresses specified in IAs in the Reply message.
This section describes prefix delegation in Reconfigure message exchanges.
The delegating router initiates a configuration message exchange with a requesting router, as described in Section 20, by sending a Reconfigure message (acting as a DHCP server) to the requesting router, as described in Section 20.1. The delegating router specifies the IA_PD option in the Option Request option to cause the requesting router to include an IA_PD option to obtain new information about delegated prefix(es).
The requesting router responds to a Reconfigure message, acting as a DHCP client, received from a delegating router as described in Section 20.4 The requesting router MUST include the IA_PD Prefix option(s) (in an IA_PD option) for prefix(es) that have been delegated to the requesting router by the delegating router from which the Reconfigure message was received.
The relay agent MAY be configured to use a list of destination addresses, which MAY include unicast addresses, the All_DHCP_Servers multicast address, or other addresses selected by the network administrator. If the relay agent has not been explicitly configured, it MUST use the All_DHCP_Servers multicast address as the default.
If the relay agent relays messages to the All_DHCP_Servers multicast address or other multicast addresses, it sets the Hop Limit field to 32.
If the relay agent receives a message other than Relay-forward and Relay-reply and the relay agent does not recognize its message type, it MUST forward them as described in Section 21.1.1.
A relay agent relays both messages from clients and Relay-forward messages from other relay agents. When a relay agent receives a valid message (for a definition of a valid message, see Section 4.1 of [RFC7283]) to be relayed, it constructs a new Relay-forward message. The relay agent copies the source address from the header of the IP datagram in which the message was received to the peer-address field of the Relay-forward message. The relay agent copies the received DHCP message (excluding any IP or UDP headers) into a Relay Message option in the new message. The relay agent adds to the Relay-forward message any other options it is configured to include.
[RFC6221] defines a Lightweight DHCPv6 Relay Agent (LDRA) that allows Relay Agent Information to be inserted by an access node that performs a link- layer bridging (i.e., non-routing) function.
If the relay agent received the message to be relayed from a client, the relay agent places a global, ULA [RFC4193] or site-scoped address with a prefix assigned to the link on which the client should be assigned an address in the link-address field. If not addresses of other scopes are available the relay agent may fill in the link-address field with a link-local address from the interface the original message was received on. That is not recommended as it requires additional information to be provided in the server configuration. See Section 3.2 of [I-D.ietf-dhc-topo-conf] for detailed discussion.
This address will be used by the server to determine the link from which the client should be assigned an address and other configuration information. The hop-count in the Relay-forward message is set to 0.
If the relay agent cannot use the address in the link-address field to identify the interface through which the response to the client will be relayed, the relay agent MUST include an Interface-id option (see Section 23.18) in the Relay-forward message. The server will include the Interface-id option in its Relay-reply message. The relay agent fills in the link-address field as described in the previous paragraph regardless of whether the relay agent includes an Interface-id option in the Relay-forward message.
If the message received by the relay agent is a Relay-forward message and the hop-count in the message is greater than or equal to HOP_COUNT_LIMIT, the relay agent discards the received message.
The relay agent copies the source address from the IP datagram in which the message was received from the relay agent into the peer-address field in the Relay-forward message and sets the hop-count field to the value of the hop-count field in the received message incremented by 1.
If the source address from the IP datagram header of the received message is a global or site-scoped address (and the device on which the relay agent is running belongs to only one site), the relay agent sets the link-address field to 0; otherwise the relay agent sets the link-address field to a global or site-scoped address assigned to the interface on which the message was received, or includes an Interface-ID option to identify the interface on which the message was received.
A relay agent forwards messages containing Prefix Delegation options in the same way as described earlier in this section.
If a delegating router communicates with a requesting router through a relay agent, the delegating router may need a protocol or other out-of-band communication to configure routing information for delegated prefixes on any router through which the requesting router may forward traffic.
The relay agent processes any options included in the Relay-reply message in addition to the Relay Message option, and then discards those options.
The relay agent extracts the message from the Relay Message option and relays it to the address contained in the peer-address field of the Relay-reply message. Relay agents MUST NOT modify the message.
If the Relay-reply message includes an Interface-id option, the relay agent relays the message from the server to the client on the link identified by the Interface-id option. Otherwise, if the link-address field is not set to zero, the relay agent relays the message on the link identified by the link-address field.
If the relay agent receives a Relay-reply message, it MUST process the message as defined above, regardless of the type of message encapsulated in the Relay Message option.
A server uses a Relay-reply message to return a response to a client if the original message from the client was relayed to the server in a Relay-forward message or to send a Reconfigure message to a client if the server does not have an address it can use to send the message directly to the client.
A response to the client MUST be relayed through the same relay agents as the original client message. The server causes this to happen by creating a Relay-reply message that includes a Relay Message option containing the message for the next relay agent in the return path to the client. The contained Relay-reply message contains another Relay Message option to be sent to the next relay agent, and so on. The server must record the contents of the peer-address fields in the received message so it can construct the appropriate Relay-reply message carrying the response from the server.
For example, if client C sent a message that was relayed by relay agent A to relay agent B and then to the server, the server would send the following Relay-Reply message to relay agent B:
msg-type: RELAY-REPLY hop-count: 1 link-address: 0 peer-address: A Relay Message option, containing: msg-type: RELAY-REPLY hop-count: 0 link-address: address from link to which C is attached peer-address: C Relay Message option: <response from server>
Figure 8: Relay-reply Example
When sending a Reconfigure message to a client through a relay agent, the server creates a Relay-reply message that includes a Relay Message option containing the Reconfigure message for the next relay agent in the return path to the client. The server sets the peer-address field in the Relay-reply message header to the address of the client, and sets the link-address field as required by the relay agent to relay the Reconfigure message to the client. The server obtains the addresses of the client and the relay agent through prior interaction with the client or through some external mechanism.
Some network administrators may wish to provide authentication of the source and contents of DHCP messages. For example, clients may be subject to denial of service attacks through the use of bogus DHCP servers, or may simply be misconfigured due to unintentionally instantiated DHCP servers. Network administrators may wish to constrain the allocation of addresses to authorized hosts to avoid denial of service attacks in "hostile" environments where the network medium is not physically secured, such as wireless networks or college residence halls.
The DHCP authentication mechanism is based on the design of authentication for DHCPv4 [RFC3118].
Relay agents and servers that exchange messages securely use the IPsec mechanisms for IPv6 [RFC4301]. If a client message is relayed through multiple relay agents, each of the relay agents must have established independent, pairwise trust relationships. That is, if messages from client C will be relayed by relay agent A to relay agent B and then to the server, relay agents A and B must be configured to use IPsec for the messages they exchange, and relay agent B and the server must be configured to use IPsec for the messages they exchange.
Relay agents and servers that support secure relay agent to server or relay agent to relay agent communication use IPsec under the following conditions:
Authentication of DHCP messages is accomplished through the use of the Authentication option (see Section 23.11). The authentication information carried in the Authentication option can be used to reliably identify the source of a DHCP message and to confirm that the contents of the DHCP message have not been tampered with.
The Authentication option provides a framework for multiple authentication protocols. Two such protocols are defined here. Other protocols defined in the future will be specified in separate documents.
Any DHCP message MUST NOT include more than one Authentication option.
The protocol field in the Authentication option identifies the specific protocol used to generate the authentication information carried in the option. The algorithm field identifies a specific algorithm within the authentication protocol; for example, the algorithm field specifies the hash algorithm used to generate the message authentication code (MAC) in the authentication option. The replay detection method (RDM) field specifies the type of replay detection used in the replay detection field.
The Replay Detection Method (RDM) field determines the type of replay detection used in the Replay Detection field.
If the RDM field contains 0x00, the replay detection field MUST be set to the value of a strictly monotonically increasing counter. Using a counter value, such as the current time of day (for example, an NTP-format timestamp [RFC5905]), can reduce the danger of replay attacks. This method MUST be supported by all protocols.
The Reconfigure key authentication protocol provides protection against misconfiguration of a client caused by a Reconfigure message sent by a malicious DHCP server. In this protocol, a DHCP server sends a Reconfigure Key to the client in the initial exchange of DHCP messages. The client records the Reconfigure Key for use in authenticating subsequent Reconfigure messages from that server. The server then includes an HMAC computed from the Reconfigure Key in subsequent Reconfigure messages.
Both the Reconfigure Key sent from the server to the client and the HMAC in subsequent Reconfigure messages are carried as the Authentication information in an Authentication option. The format of the Authentication information is defined in the following section.
The Reconfigure Key protocol is used (initiated by the server) only if the client and server are not using any other authentication protocol and the client and server have negotiated to use Reconfigure messages.
The following fields are set in an Authentication option for the Reconfigure Key Authentication Protocol:
The format of the Authentication information for the Reconfigure Key Authentication Protocol is:
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 | Value (128 bits) | +-+-+-+-+-+-+-+-+ | . . . . . +-+-+-+-+-+-+-+-+ | | +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
Figure 9: RKAP Authentication Information
The server selects a Reconfigure Key for a client during the Request/Reply, Solicit/Reply or Information-request/Reply message exchange. The server records the Reconfigure Key and transmits that key to the client in an Authentication option in the Reply message.
The Reconfigure Key is 128 bits long, and MUST be a cryptographically strong random or pseudo-random number that cannot easily be predicted.
To provide authentication for a Reconfigure message, the server selects a replay detection value according to the RDM selected by the server, and computes an HMAC-MD5 of the Reconfigure message using the Reconfigure Key for the client. The server computes the HMAC-MD5 over the entire DHCP Reconfigure message, including the Authentication option; the HMAC-MD5 field in the Authentication option is set to zero for the HMAC-MD5 computation. The server includes the HMAC-MD5 in the authentication information field in an Authentication option included in the Reconfigure message sent to the client.
The client will receive a Reconfigure Key from the server in the initial Reply message from the server. The client records the Reconfigure Key for use in authenticating subsequent Reconfigure messages.
To authenticate a Reconfigure message, the client computes an HMAC-MD5 over the DHCP Reconfigure message, using the Reconfigure Key received from the server. If this computed HMAC-MD5 matches the value in the Authentication option, the client accepts the Reconfigure message.
Options are used to carry additional information and parameters in DHCP messages. Every option shares a common base format, as described in Section 23.1. All values in options are represented in network byte order.
This document describes the DHCP options defined as part of the base DHCP specification. Other options may be defined in the future in separate documents. See [RFC7227] for guidelines regarding new options definition.
Unless otherwise noted, each option may appear only in the options area of a DHCP message and may appear only once. If an option does appear multiple times, each instance is considered separate and the data areas of the options MUST NOT be concatenated or otherwise combined.
Options that are allowed to appear only once are called singleton options. The only non-singleton options defined in this document are IA_NA (see Section 23.4), IA_TA (see Section 23.5), and IA_PD (see Section 23.21) options. Also, IAAddress (see Section 23.6) and IAPrefix (see Section 23.22) may appear in their respective IA options more than once.
The format of DHCP options is:
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 +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+ | option-code | option-len | +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+ | option-data | | (option-len octets) | +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
Figure 10: Option Format
DHCPv6 options are scoped by using encapsulation. Some options apply generally to the client, some are specific to an IA, and some are specific to the addresses within an IA. These latter two cases are discussed in Section 23.4 and Section 23.6.
The Client Identifier option is used to carry a DUID (see Section 10) identifying a client between a client and a server. The format of the Client Identifier option is:
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 +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+ | OPTION_CLIENTID | option-len | +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+ . . . DUID . . (variable length) . . . +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
Figure 11: Client Identifier Option Format
The Server Identifier option is used to carry a DUID (see Section 10) identifying a server between a client and a server. The format of the Server Identifier option is:
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 +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+ | OPTION_SERVERID | option-len | +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+ . . . DUID . . (variable length) . . . +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
Figure 12: Server Identifier Option Format
The Identity Association for Non-temporary Addresses option (IA_NA option) is used to carry an IA_NA, the parameters associated with the IA_NA, and the non-temporary addresses associated with the IA_NA.
Addresses appearing in an IA_NA option are not temporary addresses (see Section 23.5).
The format of the IA_NA option is:
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 +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+ | OPTION_IA_NA | option-len | +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+ | IAID (4 octets) | +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+ | T1 | +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+ | T2 | +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+ | | . IA_NA-options . . . +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
Figure 13: Identity Association for Non-temporary Addresses Option Format
The IA_NA-options field encapsulates those options that are specific to this IA_NA. For example, all of the IA Address Options carrying the addresses associated with this IA_NA are in the IA_NA-options field.
Each IA_NA carries one "set" of non-temporary addresses; that is, at most one address from each prefix assigned to the link to which the client is attached.
An IA_NA option may only appear in the options area of a DHCP message. A DHCP message may contain multiple IA_NA options.
The status of any operations involving this IA_NA is indicated in a Status Code option in the IA_NA-options field.
Note that an IA_NA has no explicit "lifetime" or "lease length" of its own. When the valid lifetimes of all of the addresses in an IA_NA have expired, the IA_NA can be considered as having expired. T1 and T2 are included to give servers explicit control over when a client recontacts the server about a specific IA_NA.
In a message sent by a client to a server, the T1 and T2 fields SHOULD be set to 0. The server MUST ignore any values in these fields in messages received from a client.
In a message sent by a server to a client, the client MUST use the values in the T1 and T2 fields for the T1 and T2 parameters, unless those values in those fields are 0. The values in the T1 and T2 fields are the number of seconds until T1 and T2.
The server selects the T1 and T2 times to allow the client to extend the lifetimes of any addresses in the IA_NA before the lifetimes expire, even if the server is unavailable for some short period of time. Recommended values for T1 and T2 are .5 and .8 times the shortest preferred lifetime of the addresses in the IA that the server is willing to extend, respectively. If the "shortest" preferred lifetime is 0xffffffff ("infinity"), the recommended T1 and T2 values are also 0xffffffff. If the time at which the addresses in an IA_NA are to be renewed is to be left to the discretion of the client, the server sets T1 and T2 to 0. The client MUST follow the rules defined in Section 14.2.
If a server receives an IA_NA with T1 greater than T2, and both T1 and T2 are greater than 0, the server ignores the invalid values of T1 and T2 and processes the IA_NA as though the client had set T1 and T2 to 0.
If a client receives an IA_NA with T1 greater than T2, and both T1 and T2 are greater than 0, the client discards the IA_NA option and processes the remainder of the message as though the server had not included the invalid IA_NA option.
Care should be taken in setting T1 or T2 to 0xffffffff ("infinity"). A client will never attempt to extend the lifetimes of any addresses in an IA with T1 set to 0xffffffff. A client will never attempt to use a Rebind message to locate a different server to extend the lifetimes of any addresses in an IA with T2 set to 0xffffffff.
This option MAY appear in a Confirm message if the lifetimes on the non-temporary addresses in the associated IA have not expired.
The Identity Association for the Temporary Addresses (IA_TA) option is used to carry an IA_TA, the parameters associated with the IA_TA and the addresses associated with the IA_TA. All of the addresses in this option are used by the client as temporary addresses, as defined in [RFC4941]. The format of the IA_TA option is:
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 +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+ | OPTION_IA_TA | option-len | +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+ | IAID (4 octets) | +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+ | | . IA_TA-options . . . +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
Figure 14: Identity Association for Temporary Addresses Option Format
The IA_TA-Options field encapsulates those options that are specific to this IA_TA. For example, all of the IA Address Options carrying the addresses associated with this IA_TA are in the IA_TA-options field.
Each IA_TA carries one "set" of temporary addresses.
An IA_TA option may only appear in the options area of a DHCP message. A DHCP message may contain multiple IA_TA options.
The status of any operations involving this IA_TA is indicated in a Status Code option in the IA_TA-options field.
Note that an IA has no explicit "lifetime" or "lease length" of its own. When the valid lifetimes of all of the addresses in an IA_TA have expired, the IA can be considered as having expired.
An IA_TA option does not include values for T1 and T2. A client MAY request that the lifetimes on temporary addresses be extended by including the addresses in a IA_TA option sent in a Renew or Rebind message to a server. For example, a client would request an extension on the lifetime of a temporary address to allow an application to continue to use an established TCP connection.
The client obtains new temporary addresses by sending an IA_TA option with a new IAID to a server. Requesting new temporary addresses from the server is the equivalent of generating new temporary addresses as described in [RFC4941]. The server will generate new temporary addresses and return them to the client. The client should request new temporary addresses before the lifetimes on the previously assigned addresses expire.
A server MUST return the same set of temporary address for the same IA_TA (as identified by the IAID) as long as those addresses are still valid. After the lifetimes of the addresses in an IA_TA have expired, the IAID may be reused to identify a new IA_TA with new temporary addresses.
This option MAY appear in a Confirm message if the lifetimes on the temporary addresses in the associated IA have not expired.
The IA Address option is used to specify IPv6 addresses associated with an IA_NA or an IA_TA. The IA Address option must be encapsulated in the Options field of an IA_NA or IA_TA option. The Options fields of the IA_NA or IA_TA option encapsulates those options that are specific to this address.
The format of the IA Address option is:
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 +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+ | OPTION_IAADDR | option-len | +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+ | | | IPv6 address | | | | | +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+ | preferred-lifetime | +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+ | valid-lifetime | +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+ . . . IAaddr-options . . . +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
Figure 15: IA Address Option Format
In a message sent by a client to a server, the preferred and valid lifetime fields SHOULD be set to 0. The server MUST ignore any received values.
The client SHOULD NOT send the IA Address option with unspecified address (::).
In a message sent by a server to a client, the client MUST use the values in the preferred and valid lifetime fields for the preferred and valid lifetimes. The values in the preferred and valid lifetimes are the number of seconds remaining in each lifetime.
A client discards any addresses for which the preferred lifetime is greater than the valid lifetime. A server ignores the lifetimes set by the client if the preferred lifetime is greater than the valid lifetime and ignores the values for T1 and T2 set by the client if those values are greater than the preferred lifetime.
Care should be taken in setting the valid lifetime of an address to 0xffffffff ("infinity"), which amounts to a permanent assignment of an address to a client.
More than one IA Address Option can appear in an IA_NA option or an IA_TA option.
The status of any operations involving this IA Address is indicated in a Status Code option in the IAaddr-options field, as specified in Section 23.13.
The Option Request option is used to identify a list of options in a message between a client and a server. The format of the Option Request option is:
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 +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+ | OPTION_ORO | option-len | +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+ | requested-option-code-1 | requested-option-code-2 | +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+ | ... | +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
Figure 16: Option Request Option Format
A client MAY include an Option Request option in a Solicit, Request, Renew, Rebind, Confirm or Information-request message to inform the server about options the client wants the server to send to the client. A server MAY include an Option Request option in a Reconfigure message to indicate which options the client should request from the server. If there is a need to request encapsulated options, top-level Option Request option MUST be used for that purpose. There is no need request IAADDR or IAPREFIX.
The Preference option is sent by a server to a client to affect the selection of a server by the client.
The format of the Preference option is:
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 +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+ | OPTION_PREFERENCE | option-len | +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+ | pref-value | +-+-+-+-+-+-+-+-+
Figure 17: Preference Option Format
A server MAY include a Preference option in an Advertise message to control the selection of a server by the client. See Section 18.1.3 for the use of the Preference option by the client and the interpretation of Preference option data value.
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 +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+ | OPTION_ELAPSED_TIME | option-len | +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+ | elapsed-time | +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
Figure 18: Elapsed Time Option Format
A client MUST include an Elapsed Time option in messages to indicate how long the client has been trying to complete a DHCP message exchange. The elapsed time is measured from the time at which the client sent the first message in the message exchange, and the elapsed-time field is set to 0 in the first message in the message exchange. Servers and Relay Agents use the data value in this option as input to policy controlling how a server responds to a client message. For example, the elapsed time option allows a secondary DHCP server to respond to a request when a primary server has not answered in a reasonable time. The elapsed time value is an unsigned, 16 bit integer. The client uses the value 0xffff to represent any elapsed time values greater than the largest time value that can be represented in the Elapsed Time option.
The Relay Message option carries a DHCP message in a Relay-forward or Relay-reply message.
The format of the Relay Message option is:
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 +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+ | OPTION_RELAY_MSG | option-len | +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+ | | . DHCP-relay-message . . . . . +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
Figure 19: Relay Message Option Format
The Authentication option carries authentication information to authenticate the identity and contents of DHCP messages. The use of the Authentication option is described in Section 22. The format of the Authentication option is:
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 +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+ | OPTION_AUTH | option-len | +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+ | protocol | algorithm | RDM | | +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+ | | | | replay detection (64 bits) +-+-+-+-+-+-+-+-+ | | auth-info | +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+ | . authentication information . . (variable length) . +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
Figure 20: Authentication Option Format
The server sends this option to a client to indicate to the client that it is allowed to unicast messages to the server. The format of the Server Unicast option is:
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 +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+ | OPTION_UNICAST | option-len | +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+ | | | server-address | | | | | +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
Figure 21: Server Unicast Option Format
The server specifies the IPv6 address to which the client is to send unicast messages in the server-address field. When a client receives this option, where permissible and appropriate, the client sends messages directly to the server using the IPv6 address specified in the server-address field of the option.
When the server sends a Unicast option to the client, some messages from the client will not be relayed by Relay Agents, and will not include Relay Agent options from the Relay Agents. Therefore, a server should only send a Unicast option to a client when Relay Agents are not sending Relay Agent options. A DHCP server rejects any messages sent inappropriately using unicast to ensure that messages are relayed by Relay Agents when Relay Agent options are in use.
Details about when the client may send messages to the server using unicast are in Section 19.
This option returns a status indication related to the DHCP message or option in which it appears. The format of the Status Code option is:
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 +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+ | OPTION_STATUS_CODE | option-len | +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+ | status-code | | +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+ | . . . status-message . . . +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
Figure 22: Status Code Option Format
A Status Code option may appear in the options field of a DHCP message and/or in the options field of another option. If the Status Code option does not appear in a message in which the option could appear, the status of the message is assumed to be Success.
The status-codes values previously defined by [RFC3315] and [RFC3633] are:
Name | Code | Description |
---|---|---|
Success | 0 | Success. |
UnspecFail | 1 | Failure, reason unspecified; this status code is sent by either a client or a server to indicate a failure not explicitly specified in this document. |
NoAddrsAvail | 2 | Server has no addresses available to assign to the IA(s). |
NoBinding | 3 | Client record (binding) unavailable. |
NotOnLink | 4 | The prefix for the address is not appropriate for the link to which the client is attached. |
UseMulticast | 5 | Sent by a server to a client to force the client to send messages to the server using the All_DHCP_Relay_Agents_and_Servers address. |
NoPrefixAvail | 6 | Delegating router has no prefixes available to assign to the IAPD(s). |
The Rapid Commit option is used to signal the use of the two message exchange for address assignment. The format of the Rapid Commit option is:
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 +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+ | OPTION_RAPID_COMMIT | 0 | +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
Figure 23: Rapid Commit Option Format
A client MAY include this option in a Solicit message if the client is prepared to perform the Solicit-Reply message exchange described in Section 18.1.1.
A server MUST include this option in a Reply message sent in response to a Solicit message when completing the Solicit-Reply message exchange.
DISCUSSION:
The User Class option is used by a client to identify the type or category of user or applications it represents.
The format of the User Class option is:
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 +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+ | OPTION_USER_CLASS | option-len | +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+ . . . user-class-data . . . +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
Figure 24: User Class Option Format
The information contained in the data area of this option is contained in one or more opaque fields that represent the user class or classes of which the client is a member. A server selects configuration information for the client based on the classes identified in this option. For example, the User Class option can be used to configure all clients of people in the accounting department with a different printer than clients of people in the marketing department. The user class information carried in this option MUST be configurable on the client.
The data area of the user class option MUST contain one or more instances of user class data. Each instance of the user class data is formatted as follows:
+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-...-+-+-+-+-+-+-+ | user-class-len | opaque-data | +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-...-+-+-+-+-+-+-+
Figure 25: User Class Data Format
The user-class-len is two octets long and specifies the length of the opaque user class data in network byte order.
A server interprets the classes identified in this option according to its configuration to select the appropriate configuration information for the client. A server may use only those user classes that it is configured to interpret in selecting configuration information for a client and ignore any other user classes. In response to a message containing a User Class option, a server includes a User Class option containing those classes that were successfully interpreted by the server, so that the client can be informed of the classes interpreted by the server.
This option is used by a client to identify the vendor that manufactured the hardware on which the client is running. The information contained in the data area of this option is contained in one or more opaque fields that identify details of the hardware configuration. The format of the Vendor Class option is:
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 +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+ | OPTION_VENDOR_CLASS | option-len | +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+ | enterprise-number | +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+ . . . vendor-class-data . . . . . . +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
Figure 26: Vendor Class Option Format
The vendor-class-data is composed of a series of separate items, each of which describes some characteristic of the client's hardware configuration. Examples of vendor-class-data instances might include the version of the operating system the client is running or the amount of memory installed on the client.
Each instance of the vendor-class-data is formatted as follows:
+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-...-+-+-+-+-+-+-+ | vendor-class-len | opaque-data | +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-...-+-+-+-+-+-+-+
Figure 27: Vendor Class Data Format
The vendor-class-len is two octets long and specifies the length of the opaque vendor class data in network byte order.
Servers and clients MUST NOT include more than one instance of OPTION_VENDOR_CLASS with the same Enterprise Number. Each instance of OPTION_VENDOR_CLASS can carry multiple sub-options.
This option is used by clients and servers to exchange vendor-specific information.
The format of the Vendor-specific Information option is:
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 +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+ | OPTION_VENDOR_OPTS | option-len | +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+ | enterprise-number | +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+ . . . option-data . . . +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
Figure 28: Vendor-specific Information Option Format
The definition of the information carried in this option is vendor specific. The vendor is indicated in the enterprise-number field. Use of vendor-specific information allows enhanced operation, utilizing additional features in a vendor's DHCP implementation. A DHCP client that does not receive requested vendor-specific information will still configure the host device's IPv6 stack to be functional.
The encapsulated vendor-specific options field MUST be encoded as a sequence of code/length/value fields of identical format to the DHCP options field. The option codes are defined by the vendor identified in the enterprise-number field and are not managed by IANA. Each of the encapsulated options is formatted 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 +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+ | opt-code | option-len | +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+ . . . option-data . . . +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
Figure 29: Vendor-specific Options Format
Multiple instances of the Vendor-specific Information option may appear in a DHCP message. Each instance of the option is interpreted according to the option codes defined by the vendor identified by the Enterprise Number in that option. Servers and clients MUST NOT send more than one instance of Vendor-specific Information option with the same Enterprise Number. Each instance of Vendor-specific Information option MAY contain multiple encapsulated options.
A client that is interested in receiving a Vendor-specific Information Option:
Severs only return the Vendor-specific Information Options if specified in Option Request Options from clients and:
The relay agent MAY send the Interface-id option to identify the interface on which the client message was received. If a relay agent receives a Relay-reply message with an Interface-id option, the relay agent relays the message to the client through the interface identified by the option.
The format of the Interface ID option is:
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 +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+ | OPTION_INTERFACE_ID | option-len | +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+ . . . interface-id . . . +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
Figure 30: Interface-ID Option Format
The server MUST copy the Interface-Id option from the Relay-forward message into the Relay-reply message the server sends to the relay agent in response to the Relay-forward message. This option MUST NOT appear in any message except a Relay-forward or Relay-reply message.
Servers MAY use the Interface-ID for parameter assignment policies. The Interface-ID SHOULD be considered an opaque value, with policies based on exact match only; that is, the Interface-ID SHOULD NOT be internally parsed by the server. The Interface-ID value for an interface SHOULD be stable and remain unchanged, for example, after the relay agent is restarted; if the Interface-ID changes, a server will not be able to use it reliably in parameter assignment policies.
A server includes a Reconfigure Message option in a Reconfigure message to indicate to the client whether the client responds with a Renew message, a Rebind message, or an Information-request message. The format of this option is:
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 +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+ | OPTION_RECONF_MSG | option-len | +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+ | msg-type | +-+-+-+-+-+-+-+-+
Figure 31: Reconfigure Message Option Format
The Reconfigure Message option can only appear in a Reconfigure message.
A client uses the Reconfigure Accept option to announce to the server whether the client is willing to accept Reconfigure messages, and a server uses this option to tell the client whether or not to accept Reconfigure messages. The default behavior, in the absence of this option, means unwillingness to accept Reconfigure messages, or instruction not to accept Reconfigure messages, for the client and server messages, respectively. The following figure gives the format of the Reconfigure Accept option:
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 +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+ | OPTION_RECONF_ACCEPT | 0 | +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
Figure 32: Reconfigure Accept Option Format
The IA_PD option is used to carry a prefix delegation identity association, the parameters associated with the IA_PD and the prefixes associated with it.
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 +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+ | OPTION_IA_PD | option-length | +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+ | IAID (4 octets) | +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+ | T1 | +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+ | T2 | +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+ . . . IA_PD-options . . . +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
Figure 33: Identity Association for Prefix Delegation Option Format
The IA_PD-options field encapsulates those options that are specific to this IA_PD. For example, all of the IA_PD Prefix Options carrying the prefixes associated with this IA_PD are in the IA_PD-options field.
An IA_PD option may only appear in the options area of a DHCP message. A DHCP message may contain multiple IA_PD options.
The status of any operations involving this IA_PD is indicated in a Status Code option in the IA_PD-options field.
Note that an IA_PD has no explicit "lifetime" or "lease length" of its own. When the valid lifetimes of all of the prefixes in a IA_PD have expired, the IA_PD can be considered as having expired. T1 and T2 are included to give delegating routers explicit control over when a requesting router should contact the delegating router about a specific IA_PD.
In a message sent by a requesting router to a delegating router, the T1 and T2 fields SHOULD be set to 0. The delegating router MUST ignore any values in these fields in messages received from a requesting router.
In a message sent by a delegating router to a requesting router, the delegating router MUST use the values in the T1 and T2 fields for the T1 and T2 parameters, unless those values in those fields are 0. The values in the T1 and T2 fields are the number of seconds until T1 and T2.
The delegating router selects the T1 and T2 times to allow the requesting router to extend the lifetimes of any prefixes in the IA_PD before the lifetimes expire, even if the delegating router is unavailable for some short period of time. Recommended values for T1 and T2 are .5 and .8 times the shortest preferred lifetime of the prefixes in the IA_PD that the delegating router is willing to extend, respectively. If the time at which the prefixes in an IA_PD are to be renewed is to be left to the discretion of the requesting router, the delegating router sets T1 and T2 to 0. The requesting router MUST follow the rules defined in Section 14.2.
If a delegating router receives an IA_PD with T1 greater than T2, and both T1 and T2 are greater than 0, the delegating router ignores the invalid values of T1 and T2 and processes the IA_PD as though the requesting router had set T1 and T2 to 0.
If a requesting router receives an IA_PD with T1 greater than T2, and both T1 and T2 are greater than 0, the requesting router discards the IA_PD option and processes the remainder of the message as though the requesting router had not included the IA_PD option.
The IA_PD Prefix option is used to specify IPv6 address prefixes associated with an IA_PD. The IA_PD Prefix option must be encapsulated in the IA_PD-options field of an IA_PD option.
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 +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+ | OPTION_IAPREFIX | option-length | +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+ | preferred-lifetime | +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+ | valid-lifetime | +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+ | prefix-length | | +-+-+-+-+-+-+-+-+ IPv6 prefix | | (16 octets) | | | | | | | | +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+ | | . +-+-+-+-+-+-+-+-+ . . IAprefix-options . . . +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
Figure 34: IA Prefix Option Format
In a message sent by a requesting router to a delegating router, the preferred and valid lifetime fields SHOULD be set to 0. The server MUST ignore any received values in these lifetime fields.
A requesting router may set the IPv6 prefix field to zero and a given value in the prefix-length field to indicate a preference for the size of the prefix to be delegated.
In a message sent by a delegating router the preferred and valid lifetimes should be set to the values of AdvPreferredLifetime and AdvValidLifetime as specified in section 6.2.1, "Router Configuration Variables" of [RFC2461], unless administratively configured.
A requesting router discards any prefixes for which the preferred lifetime is greater than the valid lifetime. A delegating router ignores the lifetimes set by the requesting router if the preferred lifetime is greater than the valid lifetime and ignores the values for T1 and T2 set by the requesting router if those values are greater than the preferred lifetime.
The values in the preferred and valid lifetimes are the number of seconds remaining for each lifetime.
An IA_PD Prefix option may appear only in an IA_PD option. More than one IA_PD Prefix Option can appear in a single IA_PD option.
The status of any operations involving this IA_PD Prefix option is indicated in a Status Code option in the IAprefix-options field.
A DHCP server sends the SOL_MAX_RT option to a client to override the default value of SOL_MAX_RT. The value of SOL_MAX_RT in the option replaces the default value defined in Section 6.5. One use for the SOL_MAX_RT option is to set a longer value for SOL_MAX_RT, which reduces the Solicit traffic from a client that has not received a response to its Solicit messages.
The format of the SOL_MAX_RT option is:
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 +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+ | option-code | option-len | +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+ | SOL_MAX_RT value | +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
Figure 35: SOL_MAX_RT Option Format
A DHCP client MUST include the SOL_MAX_RT option code in any Option Request option (see Section 23.7) it sends.
The DHCP server MAY include the SOL_MAX_RT option in any response it sends to a client that has included the SOL_MAX_RT option code in an Option Request option. The SOL_MAX_RT option is sent in the main body of the message to client, not as an encapsulated option in, e.g., an IA_NA, IA_TA, or IA_PD option.
A DHCP client MUST ignore any SOL_MAX_RT option values that are less than 60 or more than 86400.
If a DHCP client receives a message containing a SOL_MAX_RT option that has a valid value for SOL_MAX_RT, the client MUST set its internal SOL_MAX_RT parameter to the value contained in the SOL_MAX_RT option. This value of SOL_MAX_RT is then used by the retransmission mechanism defined in Section 15 and Section 18.1.2.
Updated SOL_MAX_RT value applies only to the network interface on which the client received SOL_MAX_RT option.
A DHCP server sends the INF_MAX_RT option to a client to override the default value of INF_MAX_RT. The value of INF_MAX_RT in the option replaces the default value defined in Section 6.5. One use for the INF_MAX_RT option is to set a longer value for INF_MAX_RT, which reduces the Information-request traffic from a client that has not received a response to its Information-request messages.
The format of the INF_MAX_RT option is:
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 +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+ | option-code | option-len | +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+ | INF_MAX_RT value | +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
Figure 36: INF_MAX_RT Option Format
A DHCP client MUST include the INF_MAX_RT option code in any Option Request option (see Section 23.7) it sends.
The DHCP server MAY include the INF_MAX_RT option in any response it sends to a client that has included the INF_MAX_RT option code in an Option Request option. The INF_MAX_RT option is sent in the main body of the message to client, not as an encapsulated option in, e.g., an IA_NA, IA_TA, or IA_PD option.
A DHCP client MUST ignore any INF_MAX_RT option values that are less than 60 or more than 86400.
If a DHCP client receives a message containing an INF_MAX_RT option that has a valid value for INF_MAX_RT, the client MUST set its internal INF_MAX_RT parameter to the value contained in the INF_MAX_RT option. This value of INF_MAX_RT is then used by the retransmission mechanism defined in Section 15 and Section 19.1.5.
Updated INF_MAX_RT value applies only to the network interface on which the client received INF_MAX_RT option.
This section discusses security considerations that are not related to privacy. For dedicated privacy discussion, see Section 25.
The threat to DHCP is inherently an insider threat (assuming a properly configured network where DHCPv6 ports are blocked on the perimeter gateways of the enterprise). Regardless of the gateway configuration, however, the potential attacks by insiders and outsiders are the same.
Use of manually configured preshared keys for IPsec between relay agents and servers does not defend against replayed DHCP messages. Replayed messages can represent a DOS attack through exhaustion of processing resources, but not through mis-configuration or exhaustion of other resources such as assignable addresses.
One attack specific to a DHCP client is the establishment of a malicious server with the intent of providing incorrect configuration information to the client. The motivation for doing so may be to mount a "man in the middle" attack that causes the client to communicate with a malicious server instead of a valid server for some service such as DNS or NTP. The malicious server may also mount a denial of service attack through misconfiguration of the client that causes all network communication from the client to fail.
A malicious DHCP server might cause a client to set its SOL_MAX_RT and INF_MAX_RT parameters to an unreasonably high value with the SOL_MAX_RT and INF_MAX_RT options, which may cause an undue delay in a client completing its DHCP protocol transaction in the case no other valid response is received. Assuming the client also receives a response from a valid DHCP server, large values for SOL_MAX_RT and INF_MAX_RT will not have any effect.
There is another threat to DHCP clients from mistakenly or accidentally configured DHCP servers that answer DHCP client requests with unintentionally incorrect configuration parameters.
A DHCP client may also be subject to attack through the receipt of a Reconfigure message from a malicious server that causes the client to obtain incorrect configuration information from that server. Note that although a client sends its response (Renew or Information-request message) through a relay agent and, therefore, that response will only be received by servers to which DHCP messages are relayed, a malicious server could send a Reconfigure message to a client, followed (after an appropriate delay) by a Reply message that would be accepted by the client. Thus, a malicious server that is not on the network path between the client and the server may still be able to mount a Reconfigure attack on a client. The use of transaction IDs that are cryptographically sound and cannot easily be predicted will also reduce the probability that such an attack will be successful.
The threat specific to a DHCP server is an invalid client masquerading as a valid client. The motivation for this may be for theft of service, or to circumvent auditing for any number of nefarious purposes.
The threat common to both the client and the server is the resource "denial of service" (DoS) attack. These attacks typically involve the exhaustion of available addresses, or the exhaustion of CPU or network bandwidth, and are present anytime there is a shared resource.
In the case where relay agents add additional options to Relay Forward messages, the messages exchanged between relay agents and servers may be used to mount a "man in the middle" or denial of service attack.
This threat model does not consider the privacy of the contents of DHCP messages to be important. DHCP is not used to exchange authentication or configuration information that must be kept secret from other networks nodes.
DHCP authentication provides for authentication of the identity of DHCP clients and servers, and for the integrity of messages delivered between DHCP clients and servers. DHCP authentication does not provide any privacy for the contents of DHCP messages.
Because of the opportunity for attack through the Reconfigure message, a DHCP client MUST discard any Reconfigure message that does not include authentication or that does not pass the validation process for the authentication protocol.
The Reconfigure Key protocol described in Section 22.4 provides protection against the use of a Reconfigure message by a malicious DHCP server to mount a denial of service or man-in-the-middle attack on a client. This protocol can be compromised by an attacker that can intercept the initial message in which the DHCP server sends the key to the client.
Communication between a server and a relay agent, and communication between relay agents, can be secured through the use of IPsec, as described in Section 22.1. The use of manual configuration and installation of static keys are acceptable in this instance because relay agents and the server will belong to the same administrative domain and the relay agents will require other specific configuration (for example, configuration of the DHCP server address) as well as the IPsec configuration.
A rogue delegating router can issue bogus prefixes to a requesting router. This may cause denial of service due to unreachability.
A malicious requesting router may be able to mount a denial of service attack by repeated requests for delegated prefixes that exhaust the delegating router's available prefixes.
To guard against attacks through prefix delegation, requesting routers and delegating routers SHOULD use DHCP authentication as described in Section 22. For point to point links, where one trusts that there is no man in the middle, or one trusts layer two authentication, DHCP authentication or IPsec may not be necessary. Because a requesting router and delegating routers must each have at least one assigned IPv6 address, the routers may be able to use IPsec for authentication of DHCPv6 messages. The details of using IPsec for DHCPv6 are under development.
Networks configured with delegated prefixes should be configured to preclude intentional or inadvertent inappropriate advertisement of these prefixes.
The following sections focuses on the server considerations. For extended discussion about privacy considerations for the client, see [I-D.ietf-dhc-dhcpv6-privacy]. It particular, Section 3 of said document discuss various identifiers that could be misused to track the client. Section 4 discusses existing mechanisms that may have an impact on client's privacy. Finally, Section 5 discusses potential attack vectors. For recommendations how to address or mitigate those issues, see [I-D.ietf-dhc-anonymity-profile].
This specification does not define any allocation strategies. Implementors are expected to develop their own algorithm for the server to choose a resource out of the available pool. Several possible allocation strategies are mentioned in Section 4.3 of [I-D.ietf-dhc-dhcpv6-privacy]. Please keep in mind that this list is not exhaustive and there are certainly possible other strategies. Here are some observations for the implementor to consider.
Assigning addresses using some kind of sequential algorithm (prefix::1, prefix::2, prefix::3,...) is fast, but greatly facilitate scanning of the network. Also, it makes any attacks that require guessing the next address much easier to conduct.
Deriving the IID (Interface Identifier) par of the addresses from the link layer address of the client exposes information about the client hardware and enables tracking the client across multiple subnets. Also, since the address will likely be used to access remote services, this tracking can be conducted remotely.
This document does not define any new DHCPv6 name spaces or definitions.
IANA is requested to update the http://www.iana.org/assignments/dhcpv6-parameters/dhcpv6-parameters.xhtml page to add a reference to this document for definitions previously created by [RFC3315], [RFC3633], and [RFC7083].
This specification of the DHCPv6 is mostly a corrected and cleaned up version of the original spec [RFC3315] along with numerous additions from later RFCs. However, there is a small number of mechanisms that didn't get much traction, were not widely deployed, underspecified or had other operational issues. Those mechanisms are now considered decprecated. Legacy implementations MAY support it, but implementations conformant to this document MUST NOT rely on them.
The following mechanism are now obsolete:
Delayed Authentication. This mechanism was underspecified and had significant operational burden. As a result, after 10 years its adoption was extremely limited at best.
Lifetime hints sent by a client. Client used to be allowed to send lifetime values as hints. This mechanism was not widely implemented and there were known misimplementations that sent remaining lifetimes rather than total lifetimes. That in turn was sometimes misunderstood by the servers as a request for ever decreasing lease lifetimes, which caused issues when values started approaching zero.
The following people are authors of the original RFC 3315: Ralph Droms, Jim Bound, Bernie Volz, Ted Lemon, Charles Perkins, and Mike Carney. The following people are authors of the original RFC 3633: Ole Troan and Ralph Droms. This document is merely a refinement of their work and would not be possible without their original work.
A number of additional people have contributed to identifying issues with RFC 3315 and RFC 3633 and proposed resolutions to these issues as reflected in this document (in no particular order): Ole Troan, Robert Marks, Leaf Yeh, Tim Winters, Michelle Cotton, Pablo Armando, John Brzozowski, Suresh Krishnan, Hideshi Enokihara, Alexandru Petrescu, Yukiyo Akisada, Tatuya Jinmei, Fred Templin and Christian Huitema. With special thanks to Ralph Droms for answering many questions related to the original RFC 3315 work.
The following acknowledgements are from the original RFC 3315 and RFC 3633:
Thanks to the DHC Working Group and the members of the IETF for their time and input into the specification. In particular, thanks also for the consistent input, ideas, and review by (in alphabetical order) Bernard Aboba, Bill Arbaugh, Thirumalesh Bhat, Steve Bellovin, A. K. Vijayabhaskar, Brian Carpenter, Matt Crawford, Steve Deering, Francis Dupont, Dave Forster, Brian Haberman, Richard Hussong, Tatuya Jinmei, Kim Kinnear, Fredrik Lindholm, Tony Lindstrom, Josh Littlefield, Gerald Maguire, Jack McCann, Shin Miyakawa, Thomas Narten, Erik Nordmark, Jarno Rajahalme, Yakov Rekhter, Pekka Savola, Mark Stapp, Matt Thomas, Sue Thomson, Tatuya Jinmei, Bernie Volz, Trevor Warwick, Phil Wells and Toshi Yamasaki.
Thanks to Steve Deering and Bob Hinden, who have consistently taken the time to discuss the more complex parts of the IPv6 specifications.
And, thanks to Steve Deering for pointing out at IETF 51 in London that the DHCPv6 specification has the highest revision number of any Internet Draft.
[I-D.ietf-dhc-anonymity-profile] | Huitema, C., Mrugalski, T. and S. Krishnan, "Anonymity profile for DHCP clients", Internet-Draft draft-ietf-dhc-anonymity-profile-06, January 2016. |
[I-D.ietf-dhc-dhcpv6-prefix-length-hint-issue] | Cui, Y., Li, T. and C. Liu, "DHCPv6 Prefix Length Hint Issues", Internet-Draft draft-ietf-dhc-dhcpv6-prefix-length-hint-issue-00, January 2016. |
[I-D.ietf-dhc-dhcpv6-privacy] | Krishnan, S., Mrugalski, T. and S. Jiang, "Privacy considerations for DHCPv6", Internet-Draft draft-ietf-dhc-dhcpv6-privacy-03, January 2016. |
[I-D.ietf-dhc-topo-conf] | Lemon, T. and T. Mrugalski, "Customizing DHCP Configuration on the Basis of Network Topology", Internet-Draft draft-ietf-dhc-topo-conf-06, October 2015. |
[IANA-PEN] | IANA, "Private Enterprise Numbers registry http://www.iana.org/assignments/enterprise-numbers" |
[RFC2461] | Narten, T., Nordmark, E. and W. Simpson, "Neighbor Discovery for IP Version 6 (IPv6)", RFC 2461, DOI 10.17487/RFC2461, December 1998. |
[RFC2462] | Thomson, S. and T. Narten, "IPv6 Stateless Address Autoconfiguration", RFC 2462, DOI 10.17487/RFC2462, December 1998. |
[RFC3041] | Narten, T. and R. Draves, "Privacy Extensions for Stateless Address Autoconfiguration in IPv6", RFC 3041, DOI 10.17487/RFC3041, January 2001. |
[RFC3162] | Aboba, B., Zorn, G. and D. Mitton, "RADIUS and IPv6", RFC 3162, DOI 10.17487/RFC3162, August 2001. |
[RFC3315] | Droms, R., Bound, J., Volz, B., Lemon, T., Perkins, C. and M. Carney, "Dynamic Host Configuration Protocol for IPv6 (DHCPv6)", RFC 3315, DOI 10.17487/RFC3315, July 2003. |
[RFC3633] | Troan, O. and R. Droms, "IPv6 Prefix Options for Dynamic Host Configuration Protocol (DHCP) version 6", RFC 3633, DOI 10.17487/RFC3633, December 2003. |
[RFC3736] | Droms, R., "Stateless Dynamic Host Configuration Protocol (DHCP) Service for IPv6", RFC 3736, DOI 10.17487/RFC3736, April 2004. |
[RFC3769] | Miyakawa, S. and R. Droms, "Requirements for IPv6 Prefix Delegation", RFC 3769, DOI 10.17487/RFC3769, June 2004. |
[RFC4193] | Hinden, R. and B. Haberman, "Unique Local IPv6 Unicast Addresses", RFC 4193, DOI 10.17487/RFC4193, October 2005. |
[RFC7084] | Singh, H., Beebee, W., Donley, C. and B. Stark, "Basic Requirements for IPv6 Customer Edge Routers", RFC 7084, DOI 10.17487/RFC7084, November 2013. |
[RFC7341] | Sun, Q., Cui, Y., Siodelski, M., Krishnan, S. and I. Farrer, "DHCPv4-over-DHCPv6 (DHCP 4o6) Transport", RFC 7341, DOI 10.17487/RFC7341, August 2014. |
[RFC7550] | Troan, O., Volz, B. and M. Siodelski, "Issues and Recommendations with Multiple Stateful DHCPv6 Options", RFC 7550, DOI 10.17487/RFC7550, May 2015. |
The following table indicates with a "*" the options are allowed in each DHCP message type:
Client Server IA_NA/ Elap. Relay Auth. Server ID ID IA_TA IA_PD ORO Pref Time Msg. Unicast Solicit * * * * * * Advert. * * * * * * Request * * * * * * * Confirm * * * * Renew * * * * * * * Rebind * * * * * * Decline * * * * * * Release * * * * * * Reply * * * * * * Reconf. * * * * Inform. * (see note) * * * R-forw. * R-repl. *
NOTE:
Only included in Information-request messages that are sent in response to a Reconfigure (see Section 20.4.3).
Status Rap. User Vendor Vendor Inter. Recon. Recon. SOL_MAX_RT Code Comm. Class Class Spec. ID Msg. Accept INF_MAX_RT Solicit * * * * * Advert. * * * * * * Request * * * * Confirm * * * Renew * * * * Rebind * * * * Decline * * * Release * * * Reply * * * * * * * Reconf. * Inform. * * * * R-forw. * * * * R-repl. * * * *
The following table indicates with a "*" where options can appear in the options field of other options:
Option IA_NA/ Relay Relay Field IA_TA IAADDR IA_PD IAPREFIX Forw. Reply Client ID * Server ID * IA_NA/IA_TA * IAADDR * IA_PD * IAPREFIX * ORO * Preference * Elapsed Time * Relay Message * * Authentic. * Server Uni. * Status Code * * * Rapid Comm. * User Class * Vendor Class * Vendor Info. * * * Interf. ID * * Reconf. MSG. * Reconf. Accept * SOL_MAX_RT * INF_MAX_RT *
Note: "Relay Forw" / "Relay Reply" options appear in the options field of the message but may only appear in these messages.