From 4bfd864f10b68b71482b35c818559068ef8d5797 Mon Sep 17 00:00:00 2001 From: Thomas Voss Date: Wed, 27 Nov 2024 20:54:24 +0100 Subject: doc: Add RFC documents --- doc/rfc/rfc4584.txt | 1403 +++++++++++++++++++++++++++++++++++++++++++++++++++ 1 file changed, 1403 insertions(+) create mode 100644 doc/rfc/rfc4584.txt (limited to 'doc/rfc/rfc4584.txt') diff --git a/doc/rfc/rfc4584.txt b/doc/rfc/rfc4584.txt new file mode 100644 index 0000000..6d19f45 --- /dev/null +++ b/doc/rfc/rfc4584.txt @@ -0,0 +1,1403 @@ + + + + + + +Network Working Group S. Chakrabarti +Request for Comments: 4584 E. Nordmark +Category: Informational Sun Microsystems + July 2006 + + + Extension to Sockets API for Mobile IPv6 + +Status of This Memo + + This memo provides information for the Internet community. It does + not specify an Internet standard of any kind. Distribution of this + memo is unlimited. + +Copyright Notice + + Copyright (C) The Internet Society (2006). + +Abstract + + This document describes data structures and API support for Mobile + IPv6 as an extension to the Advanced Socket API for IPv6. + + Just as the Advanced Sockets API for IPv6 gives access to various + extension headers and the ICMPv6 protocol, this document specifies + the same level of access for Mobile IPv6 components. It specifies a + mechanism for applications to retrieve and set information for + Mobility Header messages, Home Address destination options, and + Routing Header Type 2 extension headers. It also specifies the + common data structures and definitions that might be used by certain + advanced Mobile IPv6 socket applications. + + + + + + + + + + + + + + + + + + + + +Chakrabarti & Nordmark Informational [Page 1] + +RFC 4584 Sockets for API for Mobile IPv6 July 2006 + + +Table of Contents + + 1. Introduction ....................................................3 + 2. Applicability ...................................................4 + 3. Overview ........................................................5 + 4. Common Structures and Definitions ...............................6 + 4.1. The Mobility Header Data Structures ........................6 + 4.1.1. The ip6_mh Structure ................................6 + 4.1.2. Binding Refresh Request Mobility Message ............7 + 4.1.3. Home Address Test Init (HoTI) Message ...............7 + 4.1.4. Care-of Address Test Init (CoTI) Message ............7 + 4.1.5. Home Address Test (HOT) Message .....................8 + 4.1.6. Care Of Address Test (COT) Message ..................8 + 4.1.7. Binding Update Mobility Message .....................8 + 4.1.8. Binding Acknowledgement Mobility Message ............9 + 4.1.9. Binding Error Mobility Message ......................9 + 4.1.10. Mobility Option TLV data structure .................9 + 4.1.11. Mobility Option Data Structures ...................10 + 4.1.11.1. Binding Refresh Advice ...................10 + 4.1.11.2. Alternate Care-of Address ................10 + 4.1.11.3. Nonce Indices ............................10 + 4.1.11.4. Binding Authorization Data ...............10 + 4.2. Mobility Header Constants .................................10 + 4.3. IPv6 Home Address Destination Option ......................12 + 4.4. Type 2 Routing Header .....................................12 + 4.5. New ICMP Messages for Mobile IPv6 .........................13 + 4.6. IPv6 Neighbor Discovery Changes ...........................14 + 5. Access to Home Address Destination Option and Routing Headers ..15 + 5.1. Routing Header Access Functions ...........................17 + 5.2. Content of Type 2 Routing Header ..........................18 + 5.3. Order of Extension Headers for Home Address + Destination Options .......................................19 + 5.4. Home Address Destination Option Access Functions ..........20 + 5.5. Content of Home Address Destination Option ................20 + 6. Mobility Protocol Headers ......................................21 + 6.1. Receiving and Sending Mobility Header Messages ............21 + 7. Protocols File .................................................22 + 8. IPv4-Mapped IPv6 Addresses .....................................23 + 9. Security Considerations ........................................23 + 10. IANA Considerations ...........................................23 + 11. Acknowledgements ..............................................23 + 12. References ....................................................24 + 12.1. Normative References .....................................24 + 12.2. Informative References ...................................24 + + + + + + + +Chakrabarti & Nordmark Informational [Page 2] + +RFC 4584 Sockets for API for Mobile IPv6 July 2006 + + +1. Introduction + + Mobility Support in IPv6 [2] defines a new Mobility Protocol header, + a Home Address destination option and a new Routing Header type. It + is expected that Mobile IPv6 user-level implementations and some + special applications will need to access and process these IPv6 + extension headers. This document is an extension to the existing + Advanced Sockets API document [1]; it addresses the Advanced IPv6 + Sockets API for these new protocol elements defined by Mobile IPv6. + + The applicability of this API mainly targets user-level applications. + However, it has also been shown to be useful within some Mobile IPv6 + implementations; for instance, where part of the Mobile IPv6 protocol + is implemented at user-level and part in the kernel. It is up to any + such implementations to architect which part of the Mobile IPv6 and + IP Security (IPSec) packet processing should be done at the user- + level in order to meet the design needs of the particular platform + and operating system. + + The target user-level applications for this socket API are believed + to be debugging and diagnostic applications and some policy + applications that would like to receive copies of protocol + information at the application layer. + + The packet information and access to the extension headers (Routing + header and Destination options) are specified using the "ancillary + data" fields that were added to the 4.3BSD Reno sockets API in 1990. + The reason is that these ancillary data fields are part of the + Posix.1g standard and should therefore be adopted by most vendors. + This document is consistent with Advanced Sockets API for IPv6 [1] in + structure definitions, header files, and function definitions. Thus, + the implementors of this API document are assumed to be familiar with + the data structures, data sending and receiving procedures, and the + IPv6 extension header access functions described in the Advanced + Sockets API for IPv6 [1]. + + Non-goals + + This document does not address application access to either the + Authentication Header or the Encapsulating Security Payload header. + This document also does not address any API that might be necessary + for Mobile Network [4] specific needs. Furthermore, note that this + API document excludes discussion on application-level API. It + assumes that address selection socket API [5] takes care of selection + of care-of address or home address as the source address by the + application, when source address selection is required due to the + nature of the application. + + + + +Chakrabarti & Nordmark Informational [Page 3] + +RFC 4584 Sockets for API for Mobile IPv6 July 2006 + + + Providing mobility "awareness" to applications, such as applications' + being able to tell whether the host is at home or not, is out of + scope for this API. + +2. Applicability + + This API document can be applied in the following cases: + + 1. User-level debugging and monitoring tools: This socket API is + useful for accessing Mobility Headers, Home Address destination + options and Type 2 Routing Headers . For example, mh-ping might + be a monitoring tool that can process mobility headers on the + receiving side to check binding status. + + 2. Partial user-level implementation of Mobile IPv6: We assume that + some implementations may choose to do the Mobility header + processing at user level. In that case, this document recommends + implementing at least the handling of Home Address destination + options and Type 2 Routing Header in the main IP processing paths + in the kernel. The API can then be used to send and receive the + Mobility Header packets used for Mobile IPv6 signaling. + + 3. Complete header processing at the kernel-level: Many + implementations of Mobile IPv6 [2] perform processing of Home + Address destination options, Type 2 Routing Headers, and Mobility + headers at the kernel level. However, the kernel keeps a copy of + the received extension headers and passes them up to the API, + which is used by the user-level applications purely for + monitoring and debugging Mobile IPv6 packets. + + On an IPv6 host that does not implement Mobile IPv6, the IPv6 + specification [3] requires that packets with the Home Address option + or Type 2 Routing Header (where segments left is non-zero) be dropped + on receipt. This means that it is not possible to implement Mobile + IPv6 as an application on such a system. Thus, on such a system, the + applicability of this API is limited to the first case above, + enabling debugging and monitoring applications (such as tcpdump) to + parse and interpret Mobile IPv6 packets. + + + + + + + + + + + + + +Chakrabarti & Nordmark Informational [Page 4] + +RFC 4584 Sockets for API for Mobile IPv6 July 2006 + + +3. Overview + + This document can be divided into the following parts: + + 1. Definitions of constants and structures for C programs that + capture the Mobile IPv6 packet formats on the wire. A common + definition of these is useful at least for packet snooping + applications. This is captured in Section 4. In addition, + Section 4 also defines data structures for Home Address + destination option, Type 2 Routing Header, and new ICMPv6 + messages related to Mobile IPv6. + + 2. Notes on how to use the IPv6 Advanced API to access Home Address + options and Type 2 Routing Headers. This is captured in Section + 5. + + 3. Notes on how user-level applications can observe MH (Mobility + Header) packets using raw sockets (in Section 6). The IPv6 RAW + socket interface described in this document allows applications + to receive MH packets whether or not the system's MH processing + takes place in the "kernel" or at the "user space". + + 4. A name is suggested for IPv6 Mobility Header protocol in /etc/ + protocols (in Section 7). + + All examples in this document omit error checking in favor of + brevity, as it is following the same style as the Advanced Socket API + [1]. + + Note that many of the functions and socket options defined in this + document may have error returns that are not defined in this + document. + + Data types in this document follow the Posix.1g format: intN_t means + a signed integer of exactly N bits (e.g., int16_t), and uintN_t means + an unsigned integer of exactly N bits (e.g., uint32_t). + + Once the API specification becomes mature and is deployed, it may be + formally standardized by a more appropriate body, as has been done + with the Basic API [6]. However, since this specification largely + builds upon the Advanced Socket API [1], such standardization would + make sense only if the Advanced Socket API [1] were also + standardized. + + The key words "MUST", "MUST NOT", "REQUIRED", "SHALL", "SHALL NOT", + "SHOULD", "SHOULD NOT", "RECOMMENDED", "MAY", and "OPTIONAL" in this + document are to be interpreted as described in RFC 2119. + + + + +Chakrabarti & Nordmark Informational [Page 5] + +RFC 4584 Sockets for API for Mobile IPv6 July 2006 + + +4. Common Structures and Definitions + + In this section, the structures are specified in a way so that they + maximize the probability that the compiler-layout of data structures + are identical to the packet formats on the wire. However, ANSI-C + provides few guarantees about the size and alignment of data + structures. + + The assumption is that the Advanced Socket API [1] will pass up the + actual packet content (the wire format) in the buffer and in the + ancillary data objects. Thus, if an implementor has to handle a + system where the ANSI-C compiler does not and can not lay out these + structures to match the wire formats in RFC 3775 [2], the structures + defined by this API can not be supported on such a system. + + The constants and structures shown below are in network byte order, + so an application needs to perform the appropriate byte order + conversion (ntohs(), etc) when necessary. + + The structures and constants below will be included when the (new) + header file is included : + +4.1. The Mobility Header Data Structures + +4.1.1. The ip6_mh Structure + + The following structure is defined as a result of including + . This is the fixed part of the Mobility Header. + Different Mobility message types are defined in Mobile IPv6 [2]. For + portability and alignment reasons, each mobility message type + includes the mobility header fields instead of including the ip6_mh + structure, followed by the message-specific fields. + + struct ip6_mh { + uint8_t ip6mh_proto; /* NO_NXTHDR by default */ + uint8_t ip6mh_hdrlen; /* Header Len in unit of 8 Octets + excluding the first 8 Octets */ + uint8_t ip6mh_type; /* Type of Mobility Header */ + uint8_t ip6mh_reserved; /* Reserved */ + uint16_t ip6mh_cksum; /* Mobility Header Checksum */ + /* Followed by type specific messages */ + }; + + + + + + + + + +Chakrabarti & Nordmark Informational [Page 6] + +RFC 4584 Sockets for API for Mobile IPv6 July 2006 + + +4.1.2. Binding Refresh Request Mobility Message + + struct ip6_mh_binding_request { + uint8_t ip6mhbr_proto; + uint8_t ip6mhbr_hdrlen; + uint8_t ip6mhbr_type; + uint8_t ip6mhbr_reserved; + uint16_t ip6mhbr_cksum; + uint16_t ip6mhbr_reserved2; + /* Followed by optional Mobility Options */ + }; + +4.1.3. Home Address Test Init (HoTI) Message + + struct ip6_mh_home_test_init { + uint8_t ip6mhhti_proto; + uint8_t ip6mhhti_hdrlen; + uint8_t ip6mhhti_type; + uint8_t ip6mhhti_reserved; + uint16_t ip6mhhti_cksum; + uint16_t ip6mhhti_reserved2; + uint32_t ip6mhhti_cookie[2]; /* 64 bit Cookie by MN */ + /* Followed by optional Mobility Options */ + }; + +4.1.4. Care-of Address Test Init (CoTI) Message + + struct ip6_mh_careof_test_init { + uint8_t ip6mhcti_proto; + uint8_t ip6mhcti_hdrlen; + uint8_t ip6mhcti_type; + uint8_t ip6mhcti_reserved; + uint16_t ip6mhcti_cksum; + uint16_t ip6mhcti_reserved2; + uint32_t ip6mhcti_cookie[2]; /* 64 bit Cookie by MN */ + /* Followed by optional Mobility Options */ + }; + + + + + + + + + + + + + + +Chakrabarti & Nordmark Informational [Page 7] + +RFC 4584 Sockets for API for Mobile IPv6 July 2006 + + +4.1.5. Home Address Test (HOT) Message + + struct ip6_mh_home_test { + uint8_t ip6mhht_proto; + uint8_t ip6mhht_hdrlen; + uint8_t ip6mhht_type; + uint8_t ip6mhht_reserved; + uint16_t ip6mhht_cksum; + uint16_t ip6mhht_nonce_index; + uint32_t ip6mhht_cookie[2]; /* Cookie from HOTI msg */ + uint32_t ip6mhht_keygen[2]; /* 64 Bit Key by CN */ + /* Followed by optional Mobility Options */ + }; + +4.1.6. Care Of Address Test (COT) Message + + struct ip6_mh_careof_test { + uint8_t ip6mhct_proto; + uint8_t ip6mhct_hdrlen; + uint8_t ip6mhct_type; + uint8_t ip6mhct_reserved; + uint16_t ip6mhct_cksum; + uint16_t ip6mhct_nonce_index; + uint32_t ip6mhct_cookie[2]; /* Cookie from COTI message */ + uint32_t ip6mhct_keygen[2]; /* 64bit key by CN */ + /* Followed by optional Mobility Options */ + }; + +4.1.7. Binding Update Mobility Message + + struct ip6_mh_binding_update { + uint8_t ip6mhbu_proto; + uint8_t ip6mhbu_hdrlen; + uint8_t ip6mhbu_type; + uint8_t ip6mhbu_reserved; + uint16_t ip6mhbu_cksum; + uint16_t ip6mhbu_seqno; /* Sequence Number */ + uint16_t ip6mhbu_flags; + uint16_t ip6mhbu_lifetime; /* Time in unit of 4 sec */ + /* Followed by optional Mobility Options */ + }; + + /* Binding Update Flags, in network byte-order */ + #define IP6_MH_BU_ACK 0x8000 /* Request a binding ack */ + #define IP6_MH_BU_HOME 0x4000 /* Home Registration */ + #define IP6_MH_BU_LLOCAL 0x2000 /* Link-local compatibility */ + #define IP6_MH_BU_KEYM 0x1000 /* Key management mobility */ + + + + +Chakrabarti & Nordmark Informational [Page 8] + +RFC 4584 Sockets for API for Mobile IPv6 July 2006 + + +4.1.8. Binding Acknowledgement Mobility Message + + struct ip6_mh_binding_ack { + uint8_t ip6mhba_proto; + uint8_t ip6mhba_hdrlen; + uint8_t ip6mhba_type; + uint8_t ip6mhba_reserved; + uint16_t ip6mhba_cksum; + uint8_t ip6mhba_status; /* Status code */ + uint8_t ip6mhba_flags; + uint16_t ip6mhba_seqno; + uint16_t ip6mhba_lifetime; + /* Followed by optional Mobility Options */ + }; + + /* Binding Acknowledgement Flags */ + #define IP6_MH_BA_KEYM 0x80 /* Key management mobility */ + +4.1.9. Binding Error Mobility Message + + struct ip6_mh_binding_error { + uint8_t ip6mhbe_proto; + uint8_t ip6mhbe_hdrlen; + uint8_t ip6mhbe_type; + uint8_t ip6mhbe_reserved; + uint16_t ip6mhbe_cksum; + uint8_t ip6mhbe_status; /* Error Status */ + uint8_t ip6mhbe_reserved2; + struct in6_addr ip6mhbe_homeaddr; + /* Followed by optional Mobility Options */ + }; + +4.1.10. Mobility Option TLV data structure + + struct ip6_mh_opt { + uint8_t ip6mhopt_type; /* Option Type */ + uint8_t ip6mhopt_len; /* Option Length */ + /* Followed by variable length Option Data in bytes */ + }; + + + + + + + + + + + + +Chakrabarti & Nordmark Informational [Page 9] + +RFC 4584 Sockets for API for Mobile IPv6 July 2006 + + +4.1.11. Mobility Option Data Structures + +4.1.11.1. Binding Refresh Advice + + struct ip6_mh_opt_refresh_advice { + uint8_t ip6mora_type; + uint8_t ip6mora_len; + uint16_t ip6mora_interval; /* Refresh interval in 4 sec */ + }; + +4.1.11.2. Alternate Care-of Address + + struct ip6_mh_opt_altcoa { + uint8_t ip6moa_type; + uint8_t ip6moa_len; + struct in6_addr ip6moa_addr; /* Alternate CoA */ + }; + +4.1.11.3. Nonce Indices + + struct ip6_mh_opt_nonce_index { + uint8_t ip6moni_type; + uint8_t ip6moni_len; + uint16_t ip6moni_home_nonce; + uint16_t ip6moni_coa_nonce; + }; + +4.1.11.4. Binding Authorization Data + + struct ip6_mh_opt_auth_data { + uint8_t ip6moad_type; + uint8_t ip6moad_len; + uint8_t ip6moad_data[12]; + }; + +4.2. Mobility Header Constants + + IPv6 Next Header Value for Mobility: + + + + + #define IPPROTO_MH 135 /* IPv6 Mobility Header: IANA */ + + + + + + + + +Chakrabarti & Nordmark Informational [Page 10] + +RFC 4584 Sockets for API for Mobile IPv6 July 2006 + + + Mobility Header Message Types: + + + + #define IP6_MH_TYPE_BRR 0 /* Binding Refresh Request */ + #define IP6_MH_TYPE_HOTI 1 /* HOTI Message */ + #define IP6_MH_TYPE_COTI 2 /* COTI Message */ + #define IP6_MH_TYPE_HOT 3 /* HOT Message */ + #define IP6_MH_TYPE_COT 4 /* COT Message */ + #define IP6_MH_TYPE_BU 5 /* Binding Update */ + #define IP6_MH_TYPE_BACK 6 /* Binding ACK */ + #define IP6_MH_TYPE_BERROR 7 /* Binding Error */ + + Mobility Header Message Option Types: + + + + #define IP6_MHOPT_PAD1 0x00 /* PAD1 */ + #define IP6_MHOPT_PADN 0x01 /* PADN */ + #define IP6_MHOPT_BREFRESH 0x02 /* Binding Refresh */ + #define IP6_MHOPT_ALTCOA 0x03 /* Alternate COA */ + #define IP6_MHOPT_NONCEID 0x04 /* Nonce Index */ + #define IP6_MHOPT_BAUTH 0x05 /* Binding Auth Data */ + + Status values accompanied with Mobility Binding Acknowledgement: + + + + #define IP6_MH_BAS_ACCEPTED 0 /* BU accepted */ + #define IP6_MH_BAS_PRFX_DISCOV 1 /* Accepted, but prefix + discovery Required */ + #define IP6_MH_BAS_UNSPECIFIED 128 /* Reason unspecified */ + #define IP6_MH_BAS_PROHIBIT 129 /* Administratively + prohibited */ + #define IP6_MH_BAS_INSUFFICIENT 130 /* Insufficient + resources */ + #define IP6_MH_BAS_HA_NOT_SUPPORTED 131 /* HA registration not + supported */ + #define IP6_MH_BAS_NOT_HOME_SUBNET 132 /* Not Home subnet */ + #define IP6_MH_BAS_NOT_HA 133 /* Not HA for this + mobile node */ + #define IP6_MH_BAS_DAD_FAILED 134 /* DAD failed */ + #define IP6_MH_BAS_SEQNO_BAD 135 /* Sequence number out + of range */ + + + + + + + +Chakrabarti & Nordmark Informational [Page 11] + +RFC 4584 Sockets for API for Mobile IPv6 July 2006 + + + #define IP6_MH_BAS_HOME_NI_EXPIRED 136 /* Expired Home nonce + index */ + #define IP6_MH_BAS_COA_NI_EXPIRED 137 /* Expired Care-of + nonce index */ + #define IP6_MH_BAS_NI_EXPIRED 138 /* Expired Nonce + Indices */ + #define IP6_MH_BAS_REG_NOT_ALLOWED 139 /* Registration type + change disallowed */ + + Status values for the Binding Error mobility messages: + + + + #define IP6_MH_BES_UNKNOWN_HAO 1 /* Unknown binding for HOA */ + #define IP6_MH_BES_UNKNOWN_MH 2 /* Unknown MH Type */ + +4.3. IPv6 Home Address Destination Option + + Due to alignment issues in the compiler, and the alignment + requirements for this option, the included IPv6 address must be + specified as an array of 16 octets. + + + + /* Home Address Destination Option */ + struct ip6_opt_home_address { + uint8_t ip6oha_type; + uint8_t ip6oha_len; + uint8_t ip6oha_addr[16]; /* Home Address */ + }; + + Option Type Definition: + + #define IP6OPT_HOME_ADDRESS 0xc9 /* 11 0 01001 */ + +4.4. Type 2 Routing Header + + + + /* Type 2 Routing header for Mobile IPv6 */ + struct ip6_rthdr2 { + uint8_t ip6r2_nxt; /* next header */ + uint8_t ip6r2_len; /* length : always 2 */ + uint8_t ip6r2_type; /* always 2 */ + uint8_t ip6r2_segleft; /* segments left: always 1 */ + uint32_t ip6r2_reserved; /* reserved field */ + struct in6_addr ip6r2_homeaddr; /* Home Address */ + }; + + + +Chakrabarti & Nordmark Informational [Page 12] + +RFC 4584 Sockets for API for Mobile IPv6 July 2006 + + +4.5. New ICMP Messages for Mobile IPv6 + + ICMP message types and definitions for Mobile IPv6 are defined in + . + + #define MIP6_HA_DISCOVERY_REQUEST 144 + #define MIP6_HA_DISCOVERY_REPLY 145 + #define MIP6_PREFIX_SOLICIT 146 + #define MIP6_PREFIX_ADVERT 147 + + The following data structures can be used for the ICMP message types + discussed in Sections 6.5 through 6.8 in the base Mobile IPv6 [2] + specification. + + struct mip6_dhaad_req { /* Dynamic HA Address Discovery */ + struct icmp6_hdr mip6_dhreq_hdr; + }; + + #define mip6_dhreq_type mip6_dhreq_hdr.icmp6_type + #define mip6_dhreq_code mip6_dhreq_hdr.icmp6_code + #define mip6_dhreq_cksum mip6_dhreq_hdr.icmp6_cksum + #define mip6_dhreq_id mip6_dhreq_hdr.icmp6_data16[0] + #define mip6_dhreq_reserved mip6_dhreq_hdr.icmp6_data16[1] + + + struct mip6_dhaad_rep { /* HA Address Discovery Reply */ + struct icmp6_hdr mip6_dhrep_hdr; + /* Followed by Home Agent IPv6 addresses */ + }; + + #define mip6_dhrep_type mip6_dhrep_hdr.icmp6_type + #define mip6_dhrep_code mip6_dhrep_hdr.icmp6_code + #define mip6_dhrep_cksum mip6_dhrep_hdr.icmp6_cksum + #define mip6_dhrep_id mip6_dhrep_hdr.icmp6_data16[0] + #define mip6_dhrep_reserved mip6_dhrep_hdr.icmp6_data16[1] + + + struct mip6_prefix_solicit { /* Mobile Prefix Solicitation */ + struct icmp6_hdr mip6_ps_hdr; + }; + + #define mip6_ps_type mip6_ps_hdr.icmp6_type + #define mip6_ps_code mip6_ps_hdr.icmp6_code + #define mip6_ps_cksum mip6_ps_hdr.icmp6_cksum + #define mip6_ps_id mip6_ps_hdr.icmp6_data16[0] + #define mip6_ps_reserved mip6_ps_hdr.icmp6_data16[1] + + + + + +Chakrabarti & Nordmark Informational [Page 13] + +RFC 4584 Sockets for API for Mobile IPv6 July 2006 + + + struct mip6_prefix_advert { /* Mobile Prefix Advertisements */ + struct icmp6_hdr mip6_pa_hdr; + /* Followed by one or more PI options */ + }; + + #define mip6_pa_type mip6_pa_hdr.icmp6_type + #define mip6_pa_code mip6_pa_hdr.icmp6_code + #define mip6_pa_cksum mip6_pa_hdr.icmp6_cksum + #define mip6_pa_id mip6_pa_hdr.icmp6_data16[0] + #define mip6_pa_flags_reserved mip6_pa_hdr.icmp6_data16[1] + + + /* Mobile Prefix Advertisement Flags in network-byte order */ + #define MIP6_PA_FLAG_MANAGED 0x8000 + #define MIP6_PA_FLAG_OTHER 0x4000 + + + Prefix options are defined in IPv6 Advanced Socket API [1]. The + Mobile IPv6 Base specification [2] describes the modified behavior in + the 'Modifications to IPv6 Neighbor Discovery' section. Prefix + Options for Mobile IP are defined in the following section. + +4.6. IPv6 Neighbor Discovery Changes + + IPv6 Neighbor Discovery changes are also defined in + . + + New 'Home Agent' flag in router advertisement: #define + ND_RA_FLAG_HOMEAGENT 0x20 /* Home Agent flag in RA */ + + New Router flag with prefix information of the home agent: + #define ND_OPT_PI_FLAG_ROUTER 0x20 /* Router flag in PI */ + + As per the Mobile IPv6 specification [2], Section 7.2, a Home Agent + MUST include at least one prefix option with the Router Address (R) + bit set. Advanced Socket API [1] defines data structure for prefix + option as follows: + + struct nd_opt_prefix_info { /* prefix information */ + uint8_t nd_opt_pi_type; + uint8_t nd_opt_pi_len; + uint8_t nd_opt_pi_prefix_len; + uint8_t nd_opt_pi_flags_reserved; + uint32_t nd_opt_pi_valid_time; + uint32_t nd_opt_pi_preferred_time; + uint32_t nd_opt_pi_reserved2; + struct in6_addr nd_opt_pi_prefix; + }; + + + +Chakrabarti & Nordmark Informational [Page 14] + +RFC 4584 Sockets for API for Mobile IPv6 July 2006 + + + New advertisement interval option and home agent information options + are defined in Mobile IPv6 [2] base specification. + + struct nd_opt_adv_interval { /* Advertisement interval option */ + uint8_t nd_opt_ai_type; + uint8_t nd_opt_ai_len; + uint16_t nd_opt_ai_reserved; + uint32_t nd_opt_ai_interval; + }; + + The option types for the new Mobile IPv6 specific options: + + #define ND_OPT_ADV_INTERVAL 7 /* Adv Interval Option */ + #define ND_OPT_HA_INFORMATION 8 /* HA Information option */ + + struct nd_opt_homeagent_info { /* Home Agent information */ + uint8_t nd_opt_hai_type; + uint8_t nd_opt_hai_len; + uint16_t nd_opt_hai_reserved; + uint16_t nd_opt_hai_preference; + uint16_t nd_opt_hai_lifetime; + }; + +5. Access to Home Address Destination Option and Routing Headers + + Applications that need to be able to access Home Address destination + option and Type 2 Routing Header information can do so by setting the + appropriate setsockopt option and using ancillary data objects. The + order of extension headers is defined in Mobile IPv6 [2] when an IPv6 + packet with a Home Address Destination Option is sent with other + possible extension headers. Section 5.3 elaborates on the extension + header order when all possible cases are present. + + This document does not recommend that the user-level program set the + Home Address destination option or Type 2 Routing Header option; + however, for clarity it defines the order of extension headers. See + Section 2 of this document for appropriate usage of sending and + receiving of Home Address destination options and Type 2 Routing + Header extension headers. + + This document defines a new socket option, IPV6_MIPDSTOPTS for + sending Home Address destination options. In order to receive a Home + Address destination option or Type 2 Route Header, applications must + call setsockopt() to turn on the corresponding flag as described in + IPv6 Advanced Socket API [1] ( for brevity, error checking is not + performed in the examples): + + + + + +Chakrabarti & Nordmark Informational [Page 15] + +RFC 4584 Sockets for API for Mobile IPv6 July 2006 + + + int on = 1; + + setsockopt(fd, IPPROTO_IPV6, IPV6_RECVRTHDR, &on, sizeof(on)); + setsockopt(fd, IPPROTO_IPV6, IPV6_RECVDSTOPTS, + &on, sizeof(on)); + + When any of these options are enabled, the corresponding data is + returned as control information by recvmsg(), as one or more + ancillary data objects. Receiving the above information for TCP + applications is not defined in this document (see Section 4.1 of + Advanced Sockets API for IPv6 [1]). + + Note that if the IP implementation on the host does not implement the + handling of Type 2 Routing Headers or Home Address options, per RFC + 2460 [3] the IP stack is required to drop the packet. Thus, + receiving Home Address destination option and Type 2 Routing Header + at the application layer requires implementation of respective + extension headers at the IP layer in the kernel, as defined in + RFC3775 [2]. + + For receiving the Home Address destination option header, the Mobile + IPv6 implementation SHOULD follow the initial processing rules of the + Home Address destination option (Section 9.3.1 of Mobile IPv6 [2]) + before passing the information to the API level. This includes + initial processing of IPSec authentication data in a packet when it + exists. Each Destination options header is returned as one ancillary + data object described by a cmsghdr structure with cmsg_level set to + IPPROTO_IPV6 and cmsg_type set to IPV6_DSTOPTS. + + For sending the Home Address destination option, ancillary data can + be used to specify the option content for a single datagram. This + applies only to datagram and raw sockets, not to TCP sockets. The + Advanced API [1] document restricts one IPV6_xxx ancillary data + object for a particular extension header in the control buffer. + Thus, there would be a single ancillary data object for the Home + address destination option in an ancillary data buffer. If multiple + destination options are present, then the header order should be in + compliance with Section 6.3 and 9.3.2 of the Mobile IPv6 [2] base + specification. + + For TCP data packets with the Home Address destination option, the + "sticky" option may be used for all transmitted packets. The + application can remove the sticky Home Destination option header by + calling setsockopt() for IPV6_MIPDSTOPTS with a zero option length. + + Note that Section 2 of this document does not encourage setting the + Home Address destination option at the user level. A Mobile IPv6 + implementation should set and process the Home Address destination + + + +Chakrabarti & Nordmark Informational [Page 16] + +RFC 4584 Sockets for API for Mobile IPv6 July 2006 + + + option and Routing Header Type 2 at the kernel level. The setting of + Routing Header Type 2 and the Home Address destination option are + described in this document for completeness and flexibility to use + them in the future, if there is a need. + + The following socket option parameters and cmsghdr fields may be used + for sending (although not a recommended usage): + + opt level/ optname/ optval/ + cmsg_level cmsg_type cmsg_data[] + ------------ ------------ ------------------------ + IPPROTO_IPV6 IPV6_MIPDSTOPTS ip6_dest structure + IPPROTO_IPV6 IPV6_RTHDR ip6_rthdr structure + + Some IPv6 implementations may support "sticky" options [1] for the + IPv6 destination option for datagram and RAW sockets. + + Behavior of Legacy IPv6 Socket Applications: + + Legacy IPv6 applications/implementations using the Advanced Socket + API [1] mechanisms, upon receiving Home Address destination options + or Routing headers(Type 2), will discard the packet as per Sections + 4.2 and 4.4 of IPV6 Protocol [3] specification, respectively; + otherwise, they should properly handle the Home Address destination + option and the Routing Header Type 2 specified in this document. + +5.1. Routing Header Access Functions + + IPV6 Protocol [3] defines a Routing header extension header for Type + 0. Thus, in order to access the IPv6 Routing header Type 2 extension + header, one MUST use type = 2 and segment = 1. The following + existing functions defined in Advanced API for IPv6 Sockets [1] are + supported for Mobile IPv6 applications for sending and receiving + Routing Header Type 2 headers: + + For Sending: + + size_t inet6_rth_space(int type, int segments); + void *inet6_rth_init(void *bp, int bp_len, int type, int segments); + int inet6_rth_add(void *bp, const struct in6_addr *addr); + + For Receiving: + + int inet6_rth_segments(const void *bp); + struct in6_addr *inet6_rth_getaddr(const void *bp, int index); + + NOTE: Reversing operation is not possible using the Route Header Type + 2 extension header. Thus, inet6_rth_reverse() is not used. + + + +Chakrabarti & Nordmark Informational [Page 17] + +RFC 4584 Sockets for API for Mobile IPv6 July 2006 + + + Detailed descriptions and examples of accessing an IPv6 Routing + Header are discussed in the Advanced Sockets API for IPv6 [1]. + However, Section 7 of Advanced API for IPv6 Sockets [1] indicates + that multiple types of routing headers can be received as multiple + ancillary data objects to the application (with cmsg_type set to + IPV6_RTHDR). Currently, there are no API functions defined to return + the routing header type. However, this document does not define a + helper function, since it is easy to access the Routing Header Type + field just as easily as the ip6r_segleft field. An excerpt of a code + sample is provided for extracting the type of the received routing + header: + + if (msg.msg_controllen != 0 && + cmsgptr->cmsg_level == IPPROTO_IPV6 && + cmsgptr->cmsg_type == IPV6_RTHDR) { + struct in6_addr *in6; + char asciiname[INET6_ADDRSTRLEN]; + struct ip6_rthdr *rthdr; + int segments, route_type; + + rthdr = (struct ip6_rthdr *)extptr; + segments = inet6_rth_segments(extptr); + printf("route (%d segments, %d left): ", + segments, rthdr->ip6r_segleft); + route_type = rthdr->ip6r_type; + if (route_type == 2) { + printf ("Routing header Type 2 present\n"); + } + } + +5.2. Content of Type 2 Routing Header + + It is recommended that no portable applications send Type 2 Routing + Header ancillary data from the application layer, since many + implementations take care of that at the kernel layer and may not + support the API for sending Type 2 Routing Header. + + Mobile IPv6 [2] defines the Type 2 Routing Header to allow the packet + to be routed directly from a correspondent to the mobile node's + care-of address. The mobile node's care-of address is inserted into + the IPv6 Destination Address field. Once the packet arrives at the + care-of address, the mobile node retrieves its home address from the + routing header, and this is used as the final destination address for + the received IPv6 packet. + + + + + + + +Chakrabarti & Nordmark Informational [Page 18] + +RFC 4584 Sockets for API for Mobile IPv6 July 2006 + + + For user-level applications that receive Type 2 Routing Header, + inet6_rth_getaddr() returns the care-of address or on-the-wire + destination address of the received packet. This complies with the + existing Routing header Type=0 processing for IPv6 [1]. + + Thus, on the receive side, the socket application will always receive + data packets at its original home address. The implementations are + responsible for processing the Type 2 Routing Header packet as per + Mobile IPv6 RFC [2] before passing the Type 2 Routing Header + information to the Socket API. + + If a pure IPv6 [3] system receives the Routing Header Type 2 packets, + it will follow the process described in Section 4.4 of the IPv6 [3] + base specification. + +5.3. Order of Extension Headers for Home Address Destination Options + + Section 6.3 of Mobile IPV6 [2] defines the extension header order for + the Home address destination option. + + Routing Header + Home Address Destination Option + Fragment Header + AH/ESP Header + + IPv6 [3] specifies that the destination header can be either before + the Routing header or after the AH/ESP header if they are all + present. + + Thus, when the Home Address destination option is present along with + other extension headers, the order will be: + + Hop-by-Hop Options header + Destination Options header + Routing header + Destination Options [Home Address Option] + Fragment header + Authentication header + Encapsulating Security Payload header + Destination Options header + upper-layer header + + Any user-level implementation or application that sends the Home + address destination option through ancillary data objects should + follow the order extension header defined in this document when using + IPV6_MIPDSTOPTS socket options. + + + + + +Chakrabarti & Nordmark Informational [Page 19] + +RFC 4584 Sockets for API for Mobile IPv6 July 2006 + + +5.4. Home Address Destination Option Access Functions + + The application must enable the IPV6_RECVDSTOPTS socket option in + order to receive the Home Address destination option (error checking + is not performed in the example for brevity): + + int on = 1; + + setsockopt(fd, IPPROTO_IPV6, IPV6_RECVDSTOPTS, &on, sizeof(on)); + + Each Destination option header is returned as one ancillary data + object described by a cmsghdr structure, with cmsg_level set to + IPPROTO_IPV6 and cmsg_type set to IPV6_DSTOPTS. + + The received side Home Address destination option is further + processed by calling the inet6_opt_next(), inet6_opt_find(), and + inet6_opt_get_value() functions as defined in Advanced API for IPv6 + sockets [1]. + + This document assumes that portable Mobile IPv6 applications will not + send a Home Address Destination Option from the application level, as + the Mobile IPv6 implementation underneath takes care of sending the + Home Address option and the routing header type 2 at the kernel. + However, some embedded software implementations may implement the + IPv6 packet processing/sending at the user-level; those + implementations may choose to provide the API support for sending a + home-address option at the application layer. In this case, the Home + Address destination options are normally constructed by using the + inet6_opt_init(), inet6_opt_append(), inet6_opt_finish(), and + inet6_opt_set_val() functions, described in Section 10 of the + Advanced sockets API for IPv6 [1]. + +5.5. Content of Home Address Destination Option + + The received ancillary data object for the Home Address destination + option SHOULD contain the care-of address of the mobile node. It is + assumed that the initial processing of the Home Address destination + option will verify the validity of the home address, as described in + Sections 6.3 and 9.5 of the Mobile IPv6 Specification [2], and swap + the source address of the packet (COA) with the contents of Home + Address destination option. + + Note that whether or not these new APIs are used, the sender's home + address is contained in the source address (which is passed to the + application using the socket-level functions recvfrom(), recvmsg(), + accept(), and getpeername()). This is necessary for: + + + + + +Chakrabarti & Nordmark Informational [Page 20] + +RFC 4584 Sockets for API for Mobile IPv6 July 2006 + + + maintaining consistency between simple user-level applications + running between mobile nodes and the diagnostic applications on + the home agent or correspondent node that use this API; + + obtaining the COA address of the mobile node when the Home Address + destination option is used; and + + maintaining consistency of existing IPv6 Socket APIs and + processing of the Home Address destination option. + + If an implementation supports send-side Home Address destination API, + then it must follow the same rule for data content as specified in + Mobile IPv6 RFC [2] for sending a home-address option. Thus, the + home-address option will contain the home address, and the + implementation will use the care-of address as the source address of + the outgoing packet. If the implementation uses IPSec, then it + should use the content of Home Address destination option as the + source address of the packet for security association. Note that + regular user applications must not set the home address destination + option. + +6. Mobility Protocol Headers + + Mobile IPv6 [2] defines a new IPv6 protocol header to carry mobility + messages between Mobile Nodes, Home Agents and Correspondent Nodes. + These protocol headers carry Mobile IPv6 Binding messages as well as + Return Routability [2] messages. Currently the specification [2] + does not allow transport packets (piggybacking) along with the + mobility messages. Thus the mobility protocol header can be accessed + through an IPv6 RAW socket. An IPv6 RAW socket that is opened for + protocol IPPROTO_MH should always be able to see all the MH (Mobility + Header) packets. It is possible that future applications may + implement part of Mobile IPv6 signal processing at the application + level. Having a RAW socket interface may also enable an application + to execute the Return Routability protocol or other future + authentication protocol involving the mobility header at the user- + level. + +6.1. Receiving and Sending Mobility Header Messages + + This specification recommends that the IPv6 RAW sockets mechanism + send and receive Mobility Header (MH) packets. The behavior is + similar to ICMPV6 processing, where the kernel passes a copy of the + mobility header packet to the receiving socket. Depending on the + implementation, the kernel may process the mobility header in + addition to passing the mobility header to the application. In order + to comply with the restriction in the Advanced Sockets API for IPv6 + [1], applications should set the IPV6_CHECKSUM socket option with + + + +Chakrabarti & Nordmark Informational [Page 21] + +RFC 4584 Sockets for API for Mobile IPv6 July 2006 + + + IPPROTO_MH protocol RAW Sockets. A Mobile IPv6 implementation that + supports the Mobile IPv6 API must implement Mobility Header API + checksum calculations by default at the kernel for both incoming and + outbound paths. A Mobile IPv6 implementation must not return error + on the IPV6_CHECKSUM socket option setting, even if the socket option + is a NO-OP function for that implementation because it verifies the + checksum at the kernel level. The Mobility Header checksum procedure + is described in the Mobile IPv6 Protocol [2] specification. Again, + for application portability it is recommended that the applications + set the IPV6_CHECKSUM socket option along with the RAW sockets for + IPPROTO_MH protocol. + + As an example, a program that wants to send or receive a mobility + header protocol(MH) could open a socket as follows (for brevity, the + error checking is not performed in the example below): + + fd = socket(AF_INET6, SOCK_RAW, IPPROTO_MH); + + int offset = 4; + setsockopt(fd, IPPROTO_IPV6, IPV6_CHECKSUM, &offset, + sizeof(offset)); + + For example, if an implementation likes to handle HOTI/HOT and COTI/ + COT message processing, it can do so by using IPv6 RAW Sockets for + IPPROTO_MH at the application layer. The same application may also + set the IPV6_RECVDSTOPTS socket option for receiving Home Address + destination option in a binding update [2] from the mobile node. + + IPv6 RAW sockets are described in Section 3 of the IPv6 Advanced + Socket API [1] specification. All data sent and received via raw + sockets must be in network byte order. The data structures that are + defined in this document are in network byte order, and they are + believed to be supported by most compilers to hold packet formats + directly for transmission on the wire. + + The usual send/recv functions for datagram should be used for the + Mobile IPv6 RAW sockets in order to send and receive data, + respectively. + +7. Protocols File + + Many hosts provide the file /etc/protocols, which contains the names + of the various IP protocols and their protocol numbers. The protocol + numbers are obtained through function getprotoXXX() functions. + + The following addition should be made to the /etc/protocols file, in + addition to what is defined in Section 2.4 of the Advanced Sockets + API for IPv6 [1]. + + + +Chakrabarti & Nordmark Informational [Page 22] + +RFC 4584 Sockets for API for Mobile IPv6 July 2006 + + + The protocol number for Mobility Header: + (http://www.iana.org/assignments/protocol-numbers) + + ipv6-mh 135 # Mobility Protocol Header + +8. IPv4-Mapped IPv6 Addresses + + The various socket options and ancillary data specifications defined + in this document apply only to true IPv6 sockets. It is possible to + create an IPv6 socket that actually sends and receives IPv4 packets, + using IPv4-mapped IPv6 addresses, but the mapping of the options + defined in this document to an IPv4 datagram is beyond the scope of + this document. The above statement is in compliance with Section 13 + of the IPv6 Socket API [1]. + +9. Security Considerations + + The setting of the Home Address Destination option and Route Header + Type 2 IPV6_RTHDR socket option may not be allowed at the application + level in order to prevent denial-of-service attacks or man-in-the- + middle attacks by hackers. Sending and receiving of mobility header + messages are possible by IPv6 RAW sockets. Thus, it is assumed that + this operation is only possible by privileged users. However, this + API does not prevent the existing security threat from a hacker + sending a bogus mobility header or other IPv6 packets using the Home + Address option and Type 2 Routing Header extensions. + +10. IANA Considerations + + This document does not define a new protocol. However, it uses the + Mobility Header Protocol for IPv6 to define an API for the + /etc/protocols file. (ref: http://www.iana.org/assignments/protocol- + numbers) + +11. Acknowledgements + + Thanks to Brian Haley for the thorough review of this document and + many helpful comments. Keiichi Shima, Alexandru Petrescu, Ryuji + Wakikawa, Vijay Devarapalli, Jim Bound, Suvidh Mathur, Karen Nielsen, + Mark Borst, Vladislav Yasevich, and other mobile-ip working group + members provided valuable input. Antti Tuominen suggested the + routing header type function for this API document. During IESG + review, Bill Fenner suggested accessing the routing header type + directly for being consistent with RFC3542. A new socket option for + Home Address Destination Option is added per Bill Fenner's suggestion + for clarity of extension header orders. Thanks to Thomas Narten and + Jari Arkko for the review of this document. + + + + +Chakrabarti & Nordmark Informational [Page 23] + +RFC 4584 Sockets for API for Mobile IPv6 July 2006 + + +12. References + +12.1. Normative References + + [1] Stevens, W., Thomas, M., Nordmark, E., and T. Jinmei, "Advanced + Sockets Application Program Interface (API) for IPv6", RFC 3542, + May 2003. + + [2] Johnson, D., Perkins, C., and J. Arkko, "Mobility Support in + IPv6", RFC 3775, June 2004. + +12.2. Informative References + + [3] Deering, S. and R. Hinden, "Internet Protocol, Version 6 (IPv6) + Specification", RFC 2460, December 1998. + + [4] Devarapalli, V., Wakikawa, R., Petrescu, A., and P. Thubert, + "Network Mobility (NEMO) Basic Support Protocol", RFC 3963, + January 2005. + + [5] Nordmark, E., "IPv6 Socket API for source address selection", + Work in Progress, July 2005. + + [6] Gilligan, R., Thomson, S., Bound, J., McCann, J., and W. + Stevens, "Basic Socket Interface Extensions for IPv6", RFC 3493, + February 2003. + +Authors' Addresses + + Samita Chakrabarti + + EMail: samitac2@gmail.com + + + Erik Nordmark + Sun Microsystems + 17 Network Circle + Menlo Park, CA 94025 + USA + + Phone: +1 650 786 2921 + EMail: erik.nordmark@sun.com + + + + + + + + + +Chakrabarti & Nordmark Informational [Page 24] + +RFC 4584 Sockets for API for Mobile IPv6 July 2006 + + +Full Copyright Statement + + Copyright (C) The Internet Society (2006). + + This document is subject to the rights, licenses and restrictions + contained in BCP 78, and except as set forth therein, the authors + retain all their rights. + + This document and the information contained herein are provided on an + "AS IS" basis and THE CONTRIBUTOR, THE ORGANIZATION HE/SHE REPRESENTS + OR IS SPONSORED BY (IF ANY), THE INTERNET SOCIETY AND THE INTERNET + ENGINEERING TASK FORCE DISCLAIM ALL WARRANTIES, EXPRESS OR IMPLIED, + INCLUDING BUT NOT LIMITED TO ANY WARRANTY THAT THE USE OF THE + INFORMATION HEREIN WILL NOT INFRINGE ANY RIGHTS OR ANY IMPLIED + WARRANTIES OF MERCHANTABILITY OR FITNESS FOR A PARTICULAR PURPOSE. + +Intellectual Property + + The IETF takes no position regarding the validity or scope of any + Intellectual Property Rights or other rights that might be claimed to + pertain to the implementation or use of the technology described in + this document or the extent to which any license under such rights + might or might not be available; nor does it represent that it has + made any independent effort to identify any such rights. Information + on the procedures with respect to rights in RFC documents can be + found in BCP 78 and BCP 79. + + Copies of IPR disclosures made to the IETF Secretariat and any + assurances of licenses to be made available, or the result of an + attempt made to obtain a general license or permission for the use of + such proprietary rights by implementers or users of this + specification can be obtained from the IETF on-line IPR repository at + http://www.ietf.org/ipr. + + The IETF invites any interested party to bring to its attention any + copyrights, patents or patent applications, or other proprietary + rights that may cover technology that may be required to implement + this standard. Please address the information to the IETF at + ietf-ipr@ietf.org. + +Acknowledgement + + Funding for the RFC Editor function is provided by the IETF + Administrative Support Activity (IASA). + + + + + + + +Chakrabarti & Nordmark Informational [Page 25] + -- cgit v1.2.3