Host Identity Protocol                                           M. Komu
Internet-Draft                        Helsinki Institute for Information
Intended status: Standards Track                              Technology
Expires: May 25, September 8, 2007                                 March 7, 2007                                         Technology
                                                       November 21, 2006

   Native Application Programming Interfaces for SHIM Layer Prococols

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Copyright Notice

   Copyright (C) The Internet Society (2006). IETF Trust (2007).


   This document proposes extensions to the current networking APIs for
   protocols based on identifier/locator split.  Currently, the document
   focuses on HIP, but the extensions can be used also by other
   protocols similar "shim" layer protocols. implementing identifier locator split.  Using the API
   extensions, new SHIM aware applications can gain a better control of
   the SHIM layer and endpoint identifiers.  For example, the
   applications can query and set SHIM related attributes, or specify
   their own endpoint identifiers for a host.  In addition, a new
   indirection element called endpoint descriptor is defined for SHIM
   aware applications. applications that can be used for implementing opportunistic
   mode in a clean way.

Table of Contents

   1.  Introduction . . . . . . . . . . . . . . . . . . . . . . . . .  3

   2.  Design Architecture  . . . . . . . . . . . . . . . . . . . . .  4
     2.1.  Endpoint Descriptor  . . . . . . . . . . . . . . . . . . .  4
     2.2.  Layering Model . . . . . . . . . . . . . . . . . . . . . .  4
     2.3.  Namespace Model  . . . . . . . . . . . . . . . . . . . . .  5
     2.4.  Socket Bindings  . . . . . . . . . . . . . . . . . . . . .  6

   3.  Interface Syntax and Description . . . . . . . . . . . . . . .  7
     3.1.  Data Structures  . . . . . . . . . . . . . . . . . . . . .  8
     3.2.  Functions  . . . . . . . . . . . . . . . . . . . . . . . . 10
       3.2.1.  Resolver Interface . . . . . . . . . . . . . . . . . . 11
       3.2.2.  Application Specified Identities . . . . . . . . . . . 11
       3.2.3.  Querying Endpoint Related Information  . . . . . . . . 13
       3.2.4.  HIP Related Policy Attributes  . . . . . . . . . . . . 14

   4.  IANA Considerations  . . . . . . . . . . . . . . . . . . . . . 15

   5.  Security Considerations  . . . . . . . . . . . . . . . . . . . 15

   6.  Acknowledgements . . . . . . . . . . . . . . . . . . . . . . . 15

   7.  References . . . . . . . . . . . . . . . . . . . . . . . . . . 15
     7.1.  Normative References . . . . . . . . . . . . . . . . . . . 15
     7.2.  Informative References . . . . . . . . . . . . . . . . . . 16

   Author's Address . . . . . . . . . . . . . . . . . . . . . . . . . 16
   Intellectual Property and Copyright Statements . . . . . . . . . . 18

1.  Introduction

   The extensions defined in this draft can be used also by other
   protocols based on the identifier/locator split.  For example, SHIM6
   and BTNS are possible such candidates.  Related WG API drafts are
   draft-sugimoto-multihome-shim-api and [6].  However, this draft
   documented focuses on mainly to HIP.

   Host Identity Protocol proposes a new cryptographic namespace and a
   new layer to the TCP/IP architecture.  Applications can see these new
   changes in the networking stacks with varying degrees of visibility.
   [I-D.henderson-hip-applications] discusses the lowest levels of
   visibility in which applications are either completely or partially
   unaware of HIP.  In this document, we discuss about the highest level
   of visibility.  The applications are completely HIP aware and are given more can
   control over the HIP layer and identifiers. Host Identifiers.  The applications are allowed to query aquery
   configure set security related attributes and even specify create their own Host

   Legacy HIP

   Existing applications can already use be used with HIP as described in
   [I-D.henderson-hip-applications].  The reason why HIP can be used in
   a variety backwards compatible way lies in the identifiers.  A HIP enabled
   system can support the use of identifiers,
   like LSIs, HITs and even IP addresses as described in [5].  The
   upper layer identifiers to accomodate varying
   number application
   requirements.  However, these types of identifiers can are not forwards
   compatible.  The length of HIT may turn out insecure in the future.
   There may be all a need to change the HITs on the fly to an already
   connected socket for dynamic session mobility.  Or, the socket is
   going to be used associated to multiple HITs for HIP based networking multicast.

   To support forwards compatibility, we introduce a new, generalized
   identifier called the endpoint descriptor (ED).  The ED acts as a
   handle to the actual identifier that separates application layer
   indentifiers from the lower layer identifiers.

   The ED can already now be used for implementing HIP opportunistic
   mode in a easily deployable clean way.  The proposed extensions could problem with implementing HIP opportunistic
   mode is that e.g. sockets API connect() call should be as well
   based on one bound to a HIT
   in order to use HIP, but the HIT is unknown until the reception the
   R1 packet.  At this point it is too late to change the binding e.g.
   from a IP to HIT.  However, the ED has to property of late binding
   and therefore provides a cleaner way to implement the existing formats, like HITs or public keys, but
   they have their own problems.  For example, opportunistic

   The ED socket address structure does not reveal the HIT format may transport
   layerport number to the application even though it is possible to
   request it explicitly.  This makes it possible to change the port
   number dynamically without affecting the application.  Also, it seems
   that the port number is irrelevant, or even misleading, in todays
   NATted networks to the future, and long, variable length public keys are not directly
   applicable application.

   The document also introduces a new address family, PF_SHIM, for
   sockets that use EDs.  The new family is a direct consequence of
   introducing a new address type (ED) to the current sockets API.  In addition, there may  It can also
   be a need used for another new layer in the future, such as session layer, and
   choosing any quick detection of SHIM support in the existing identifier formats may introduce
   additional deployment problems for localhost.  This
   is especially useful discover when SHIM aware applications are tried
   on a new layer.  We therefore propose host that does not support SHIM.

   The ED concept is similar to Local Scope Identifier
   [I-D.henderson-hip-applications] in the sense that it is also valid
   only within a new, generalized identifier called host.  However, it has some differences.  A minor
   difference is that two LSIs are the endpoint descriptor (ED).
   The same when they refer to the same
   endpoint, but ED acts as does not have this constraint.  LSIs have a handle prefix
   to separate them from IP addresses, but ED do not.  However, the actual identifier main
   reason why ED is not denoted as LSI in this document is that separates
   application layer indentifiers from the lower layer identifiers. LSIs
   are bound to AF_INET sockets whereas EDs are bound to PF_SHIM

2.  Design Architecture

   In this section, the native SHIM API design is described from an
   architectural point of view.  We introduce the ED concept, which is a
   central idea in the API.  We describe the layering and namespace
   models along with the socket bindings.  We conclude the discussion
   with a description of the endpoint identifier resolution mechanism.

2.1.  Endpoint Descriptor

   The representation of endpoints is hidden from the applications.  The
   ED is a ``handle'' to a HI.  A given ED serves as a pointer to the
   corresponding HI entry in the HI database of the host.  It should be
   noticed that the ED cannot be used as a referral that is passed from
   one host to another because it has only local significance.

2.2.  Layering Model

   The application layer accesses the transport layer via the socket
   interface.  The application layer uses the traditional TCP/IP IPv4 or
   IPv6 interface, or the new native SHIM API interface provided by the
   socket layer.  The layering model is illustrated in Figure 1.  For
   simplicity, the IPsec layer has been excluded from the figure.

      Application Layer  |           Application          |
           Socket Layer  | IPv4 API | IPv6 API | SHIM API |
        Transport Layer  |      TCP      |      UDP       |
              SHIM Layer |       HIP and other SHIMs      |
          Network Layer  |     IPv4      |     IPv6       |
             Link Layer  |   Ethernet    |     Etc        |

                                 Figure 1

   The SHIM layer is as a shim/wedge layer between the transport and
   network layers.  The datagrams delivered between the transport and
   network layers are intercepted in the SHIM layer to see if the
   datagrams are SHIM related and require SHIM intervention.

2.3.  Namespace Model

   The namespace model is shown in from HIP view point.  The namespace
   identifiers are described in this section.

               | Layer             | Identifier            |
               | User Interface    | FQDN                  |
               |                   |                       |
               | Application Layer | ED, port and protocol |
               |                   |                       |
               | Transport Layer   | HI, port              |
               |                   |                       |
               | SHIM Layer        | HI                    |
               |                   |                       |
               | Network Layer     | IP address            |

                                  Table 1

   People prefer human-readable names when referring to network
   entities.  The most commonly used identifier in the User Interface is
   the FQDN, but there are also other ways to name network entities.
   The FQDN format is still the preferred UI level identifier in the
   context of the native SHIM API.

   In the current API, connection associations in the application layer
   are uniquely distinguished by the source IP address, destination IP
   address, source port, destination port, and protocol.  HIP changes
   this model by using HIT in the place of IP addresses.  The HIP model
   is further expanded in the native HIP API model by using ED instead
   of HITs.  Now, the application layer uses source ED, destination ED,
   source port, destination port, and transport protocol type, to
   distinguish between the different connection associations.

   Basically, the difference between the application and transport layer
   identifiers is that the transport layer uses HIs instead of EDs.  The
   TLI is named with source HI, destination HI, source port, and
   destination port at the transport layer.

   Correspondingly, the HIP layer uses HIs as identifiers.  The HIP
   security associations are based on source HI and destination HI

   The network layer uses IP addresses, i.e., locators, for routing
   purposes.  The network layer interacts with the HIP layer to exchange
   information about changes in the local interfaces addresses and peer

2.4.  Socket Bindings

   A HIP based SHIM socket is associated with one source and one
   destination ED, along with their port numbers and protocol type.  The
   relationship between a socket and ED is a many-to-one one.  Multiple
   EDs can be associated with a single HI.  Further, the source HI is
   associated with a set of network interfaces at the local host.  The
   destination HI, in turn, is associated with a set of destination
   addresses of the peer.  The socket bindings are visualized in
   Figure 2.

                        1 +---------+ *  1  * +--------+ *  * +-----------+
                      +---+ Src EID +------+ Src HI +------+ Src Iface |
      +--------+ *    |   +---------+ *  1      +--------+      +-----------+
      |  HIP   +------+
      |        |
      | Socket +------+
      +--------+ *    |   +---------+ *  1      +--------+ *  *      +-----------+
                      +---+ Dst EID +------+ Dst HI +------+  Dst IP   |
                        1 +---------+ *  1  * +--------+ *  * +-----------+

                                 Figure 2

   The relationship between a source ED and a source HI is always a
   many-to-one one.  However, there usually many-
   to-one one, but it can be also many-to-many on certain cases.  There
   are two refinements to the relationship.  First, a listening socket
   is allowed to accept connections from all local HIs of the host.
   Second, the opportunistic mode allows the base exchange to be
   initiated to an unknown destination HI.  In a way, the relationship
   between the local ED and local HI is a many-to-undefined relationship
   momentarily in both of the cases, but once the connection is
   established, the ED will be permanently associated with a certain HI.

   The DNS based endpoint discovery mechanism is illustrated in
   Figure 3.  The application calls the resolver (step a.) to resolve an
   FQDN (step b.).  The DNS server responds with a EID ED and a set of
   locators (step c.).  The resolver does not directly pass the EID ED and
   the locators to the application, but sends them to the SHIM module
   (step d.).  Finally, the resolver receives an ED from the SHIM module
   (step e.) and passes the ED to the application (step f.).

                                  |          |
                                  |   DNS    |
                                  |          |
                                      ^  |
                            b. <FQDN> |  | c. <EID, locator>
                                      |  v
       +-------------+ a. <FQDN>  +----------+
       |             |----------->|          |
       | Application |            | Resolver |
       |             |<-----------|          |
       +-------------+  f. <ED>   +----------+
                                      ^  |
                             e. <ED>  |  | d. <EID, locator>
                                      |  v
                                  |          |
                                  |   SHIM   |
                                  |          |

                                 Figure 3

   The application can also receive multiple EDs from the resolver when
   the FQDN is associated with multiple EIDs.  The endpoint discovery
   mechanism is still almost the same.  The difference is that the DNS
   returns a set of EIDs (along with the associated locators) to the
   resolver.  The resolver sends all of them to the SHIM module and
   receives a set of EDs in return, each ED corresponding to a single
   HI.  Finally, the EDs are sent to the application.

3.  Interface Syntax and Description

   In this section, we describe the native SHIM API using the syntax of
   the C programming language and present only the ``external''
   interfaces and data structures that are visible to the applications.
   We limit the description to those interfaces and data structures that
   are either modified or completely new, because the native SHIM API is
   otherwise identical to the sockets API [1]. [POSIX].

3.1.  Data Structures

   We introduce a new protocol family, PF_SHIM, for the sockets API.
   The AF_SHIM constant is an alias for it.  The use of the PF_SHIM
   constant is mandatory with the socket function if the native SHIM API
   is to be used in the application.  The PF_SHIM constant is given as
   the first argument (domain) to the socket function.

   The ED abstraction is realized in the sockaddr_ed structure, which is
   shown in figure Figure 4.  The family of the socket, ed_family, is set to
   PF_SHIM.  The port number ed_port is two octets and the ED value
   ed_val is four octets.  The ED value is just an opaque number to the
   application.  The application should not try to associate it directly
   to a EID or even compare it to other ED values, because there are
   separate functions for those purposes.  The ED family is stored in
   host byte order.  The port and the ED value are is stored in network byte order.  It
   should be noticed that the port number is not present in the socket
   address structure, but it can be queried with the functions in
   section Section 3.2.2.

         struct sockaddr_ed {
                 unsigned short int ed_family;
                 in_port_t ed_port;
                 sa_ed_t ed_val;

                                 Figure 4

   The ed_val field is usually set by special native SHIM API functions,
   which are described in the following section.  However, three special
   macros can be used to directly set a value into the ed_val field.
   They denote an ED value associated with a wildcard HI of any, public,
   or anonymous type.  They are useful to a ``server'' application that
   is willing to accept connections to all of the HIs of the host.  The
   macros correspond to the sockets API macros INADDR_ANY and
   IN6ADDR_ANY_INIT, but they are applicable on the SHIM layer.  It
   should be noted that only one process at a time can bind with the
   SHIM_ED_*ANY macro on a certain port to avoid ambiguous bindings.

   The native SHIM API has a new resolver function which is used for
   querying both endpoint identifiers and locators.  The resolver
   introduces a new data structure, which is used both as the input and
   output argument for the resolver.  We reuse the existing resolver
   datastructure shown in Figure 5.

          struct addrinfo {
              int    ai_flags;          /* e.g. AI_ED */
              int    ai_family;         /* e.g. PF_SHIM */
              int    ai_socktype;       /* e.g. SOCK_STREAM */
              int    ai_protocol;       /* usually just zero */
              size_t ai_addrlen;        /* length of the endpoint */
              struct sockaddr *ai_addr; /* endpoint socket address */
              char   *ai_canonname;     /* canon. name of the host */
              struct addrinfo *ai_next; /* next endpoint */

                                 Figure 5

   In addrinfo structures, the family field is set to PF_SHIM when the
   socket address structure contains an ED that refers to a SHIM
   identifier, such as HI.

   The flags in the addrinfo structure control the behavior of the
   resolver and describe the attributes of the endpoints and locators:

   o  The flag AI_ED must be set, or otherwise the resolver does not
      return EDs to guarantee that legacy applications won't break.
      When AI_ED is set, the resolver returns a linked list which
      contains first the sockaddr_ed structures for SHIM identifiers if
      any was found.  After that, any other type of socket addresses are
      returned except that HITs in sockaddr_in6 format are excluded
      because they were already included in the returned sockaddr_ed

   o  When querying local identifiers, the AI_ED_ANON flag forces the
      resolver to query only local anonymous identifiers.  The default
      action is first to resolve the public endpoints and then the
      anonymous endpoints.

   o  Some applications may prefer configuring the locators manually and
      can set the AI_ED_NOLOCATORS flag to prohibit the resolver from
      resolving any locators.

   o  The AI_ED_ANY, AI_ED_ANY_PUB and AI_ED_ANY_ANON flags cause the
      resolver to output only a single socket address containing an ED
      that would be received using the corresponding SHIM_ED_*ANY macro.
      When these flags are used for resolving local addresses, they
      allow wildcard late binding to certain types of local idenfiers.
      When the flags are used for peer resolving, they allow to contact
      the peer using opportunistic mode.

   o  The getaddrinfo resolver does not return IP addresses belonging to
      a SHIM rendezvous server unless AI_ED is defined.  AI_ED_RVS, can
      appear both in the input and output arguments of the resolver.  In
      the input, it can be used for resolving only rendezvous server
      addresses.  On the output, it denotes that the address is a
      rendezvous rather than end-point address.

   Application specified endpoint identifiers are essentially private
   keys.  To support application specified identifiers in the API, we
   introduce new data structures for storing the private keys.  The
   private keys need an uniform format so that they can be easily used
   in the API calls.  The keys are stored in the endpoint structures as
   shown in figure Figure 6.

         struct endpoint {
                 se_length_t   length;
                 se_family_t   family;
         struct endpoint_hip {
                 se_length_t length;
                 se_family_t family; /* EF_HI in the case of HIP */
                 se_hip_flags_t flags;
                 union {
                         struct hip_host_id host_id;
                         hit_t hit;
                 } id;

                                 Figure 6

   The endpoint structure represents a generic endpoint and the
   endpoint_hip structure represents a HIP specific endpoint.  The
   family field distinguishes whether the identifier is HIP or other
   protocol related.  The HIP endpoint is public by default unless
   SHIM_ENDPOINT_FLAG_ANON flag is set in the structure to anonymize the
   endpoint.  The id union contains the HI in the host_id member in the
   format specified in [3]. [I-D.ietf-hip-base].  If the key is private, the
   material is appended to the host_id with the length adjusted
   accordingly.  The flag SHIM_ENDPOINT_FLAG_PRIVATE is also set.  The
   hit member of the union is used only when the SHIM_ENDPOINT_FLAG_HIT
   flag is set.

3.2.  Functions

   In this section, some existing sockets API functions are reintroduced
   along with their additions.  Also, some new auxiliary functions are

3.2.1.  Resolver Interface

   The native SHIM API does not introduce changes to the interface
   syntax of the primitive sockets API functions bind, connect, send,
   sendto, sendmsg, recv, recvfrom, and recvmsg.  However, the
   application usually calls the functions with sockaddr_ed structures
   instead of sockaddr_in or sockaddr_in6 structures.  The source of the
   sockaddr_ed structures in the native SHIM API is the resolver
   function getaddrinfo [2] [RFC3493] which is shown in Figure 7.

           int getaddrinfo(const char *nodename,
                           const char *servname,
                           const struct addrinfo *hints,
                           struct addrinfo **res)
           void free_addrinfo(struct addrinfo *res)

                                 Figure 7

   The getaddrinfo function takes the nodename, servname, and hints as
   its input arguments.  It places the result of the query into the res
   argument.  The return value is zero on success, or a non-zero error
   value on error.  The nodename argument specifies the host name to be
   resolved; a NULL argument denotes the local host.  The servname
   parameter sets the port number to be set in the socket addresses in
   the res output argument.  Both the nodename and servname cannot be

   The output argument res is dynamically allocated by the resolver.
   The application must free res argument with the free_addrinfo
   function.  The res argument contains a linked list of the resolved
   endpoints.  The input argument hints acts like a filter that defines
   the attributes required from the resolved endpoints.  For example,
   setting the flag SHIM_ENDPOINT_FLAG_ANON in the hints forces the
   resolver to return only anonymous endpoints in the output argument
   res.  A NULL hints argument indicates that any kind of endpoints are

3.2.2.  Application Specified Identities

   Application specified local and peer endpoints can be retrieved from
   files using the function shown in Figure 8.  The function
   shim_endpoint_load_pem is used for retrieving a private or public key
   from a given file filename.  The file must be in PEM encoded format.
   The result is allocated dynamically and stored into the endpoint
   argument.  The return value of the function is zero on success, or a
   non-zero error value on failure.  The result is deallocated with the
   free system call.

           int shim_endpoint_pem_load(const char *filename,
                                      struct endpoint **endpoint)

                                 Figure 8

   Alternatively, the application can load the image directly from
   memory as shown in Figure 9

           int shim_endpoint_pem_load_str(const char *pem_str,
                                          struct endpoint **endpoint);

                                 Figure 9

   The endpoint structure cannot be used directly in the sockets API
   function calls.  The application must convert the endpoint into an ED
   first.  Local endpoints are converted with the getlocaled function
   and peer endpoints with getpeered function.  The functions are
   illustrated in Figure 9. 10.

        struct sockaddr_ed *getlocaled(const struct endpoint *endpoint,
                                      const char *servname,
                                      const struct addrinfo *addrs,
                                      const struct if_nameindex *ifaces,
                                      int flags)
        struct sockaddr_ed *getpeered(const struct endpoint *endpoint,
                                      const char *servname,
                                      const struct addrinfo *addrs,
                                      int flags)

                                 Figure 9 10

   The result of the conversion, an ED socket address, is returned by
   both of the functions.  A failure in the conversion causes a NULL
   return value to be returned and the errno to be set accordingly.  The
   caller of the functions is responsible of freeing the returned socket
   address structure.

   The application can retrieve the endpoint argument e.g. with the
   shim_endpoint_load_pem function.  If the endpoint is NULL, the system
   selects an arbitrary EID and associates it with the ED value of the
   return value.

   The servname argument is the service string.  The function converts
   it to a numeric port number and fills the port number into the
   returned ED socket structure for the convenience of the application.

   The addrs argument defines the initial IP addresses of the local host
   or peer host.  The argument is a pointer to a linked list of addrinfo
   structures containing the initial addresses of the peer.  The list
   pointer can be obtained with a getaddrinfo [2] [RFC3493] function call.
   A NULL pointer indicates that the application trusts the host to
   already know the locators of the peer.  We recommend that a NULL
   pointer is not given to the getpeered function to ensure reachability
   with the peer.

   The getlocaled function accepts also a list of network interface
   indexes in the ifaces argument.  The list can be obtained with the
   if_nameindex [2] [RFC3493] function call.  A NULL list pointer indicates
   all the interfaces of the local host.  Both the IP addresses and
   interfaces can be combined to select a specific address from a
   specific interface.

   The last argument is the flags.  The following flags are valid only
   for the getlocaled function:

      allow the EID (e.g. a large private key) to be reused for
      processes with the same UID, GID or any UID as the calling

   o  Flags SHIM_ED_IPV4 and SHIM_ED_IPV6 can be used for limiting the
      address family scope of the local interface.

   It should noticed that the SHIM_ED_ANY, SHIM_ED_ANY_PUB and
   SHIM_ED_ANY_ANON macros can be implemented as calls to the getlocaled
   call with a NULL endpoint, NULL interface, NULL address argument and
   the flag corresponding to the macro name set.

3.2.3.  Querying Endpoint Related Information

   The getlocaled and getpeered functions have also their reverse
   counterparts.  Given an ED, the getlocaledinfo and getpeeredinfo
   functions search for the EID (e.g. a HI) and the current set of
   locators associated with the ED.  The first argument is the ED to be
   searched for.  The functions write the results of the search, the
   transport layer port number of the occupied by the correponding HIT,
   the HIs and locators, to the rest of the function arguments.  The
   function interfaces are depicted in Figure 10. 11.  The caller of the
   functions is responsible for freeing the memory reserved for the
   search results.

           int getlocaledinfo(const struct sockaddr_ed *my_ed,
                              struct in_port_t **port
                              struct endpoint **endpoint,
                              struct addrinfo **addrs,
                              struct if_nameindex **ifaces)
           int getpeeredinfo(const struct sockaddr_ed *peer_ed,
                             struct in_port_t **port
                             struct endpoint **endpoint,
                             struct addrinfo **addrs)

                                 Figure 10 11

   The getlocaledinfo and getpeeredinfo functions are especially useful
   for an advanced application that receives multiple EDs from the
   resolver.  The advanced application can query the properties of the
   EDs using getlocaledinfo and getpeeredinfo functions and select the
   ED that matches the desired properties.

3.2.4.  Socket Options

   Reading and writing of SHIM socket options is done using getsockopt
   and setsockopt functions.  The first argument, the level, must be
   specified as SOL_SHIM.

   A number of SHIM socket option names  HIP Related Policy Attributes

   Multihoming related attributes are listed defined in Table 2.  The
   length of the option must be natural word size of the underlying
   processor, typically 32 or 64 bits.  The purpose of the option value
   [I-D.ietf-shim6-multihome-shim-api].  It also specifies an event
   driven API for application, which can be interpreted used for listening for
   changes in context of locators.

   HIP related policy attributes are accessed using the protocol specifications [3]
   [4]. definitions in

   Some of the socket options policy attributes must be set before the hosts have
   established connection.  The implementation may refuse to accept the
   option when there is already an existing connection and dynamic
   renegotiation of the option is not possible.  In addition, the SHIM
   may return an error value if the corresponding SHIM protocol does not
   support the given option.

   Multihoming related socket options are defined in
   draft-sugimoto-multihome-shim-api.  It also specifies an event driven
   API for application, which can be used for listening for changes in

   | Socket Options                    | Purpose                       |
   | SO_SHIM_CHALLENGE_SIZE            | Puzzle challenge size         |
   |                                   |                               |
   | SO_SHIM_SHIM_TRANSFORMS           | Integer array of if the          |
   |                                   | preferred corresponding SHIM transforms     |
   |                                   |                               |
   | SO_SHIM_ESP_TRANSFORMS            | Integer array of protocol does not
   support the          |
   |                                   | preferred ESP transforms      |
   |                                   |                               |
   | SO_SHIM_DH_GROUP_IDS              | Integer array of given option.

   Table 2shows HIP related policy attributes that are accessed with the
   APIs defined in [I-D.komu-btns-api].

   | Attribute           | Purpose                                     | preferred Diffie-Hellman      |
   |                                   | group IDs                     |
   | IPSEC_ESP_TRANSFORM | Preferred ESP transform                     |
   | SO_SHIM_SA_LIFETIME IPSEC_SA_LIFETIME   | Preferred IPsec SA lifetime   |
   |                                   | in seconds      |
   | SHIM_PROTOCOL       |                               |
   | SO_SHIM_CTRL_RETRANS_INIT_TIMEOUT | SHIM initial retransmission   |
   |                                   | timeout for Get or set current SHIM control protocol. Currently |
   |                     | packets only PF_HIP is defined.                     |
   | SHIM_CHALLENGE_SIZE | Puzzle challenge size                       |
   | SO_SHIM_CTRL_RETRANS_INTERVAL SHIM_SHIM_TRANSFORM | Preferred SHIM retransmission interval  |
   |                                   | in seconds transform                    |
   |                                   |                               |
   | SO_SHIM_CTRL_RETRANS_ATTEMPTS     | Number of retransmission      |
   |                                   | attempts                      |
   |                                   |                               |
   | SO_SHIM_AF_FAMILY SHIM_DH_GROUP_IDS   | The preferred IP address Diffie-Hellman Group          |
   | SHIM_AF_FAMILY      | The preferred locator family. The default family is   |
   |                     | family is AF_ANY.                           |
   |                                   |                               |
   | SO_SHIM_PIGGYPACK SHIM_FAST_FALLBACK  | If set to one, HIP            |
   |                                   | piggy-packing to TCP packets  |
   |                                   | is used. Zero if              |
   |                                   | piggy-packing must not be     |
   |                                   | used.                         |
   |                                   |                               |
   | SO_SHIM_OPPORTUNISTIC             | Try SHIM use the extensions in opportunistic        |
   |                     | mode when only the locators [I-D.lindqvist-hip-opportunistic]           |
   | SHIM_FAST_HANDSHAKE | of If set to one, use the peer are known.        |
   |                                   |                               |
   | SO_SHIM_NAT_TRAVERSAL             | Enable NAT traversal mode for extensions in        |
   |                     | SHIM. [I-D.lindqvist-hip-tcp-piggybacking]        |

                                  Table 2

4.  IANA Considerations

   No IANA considerations.

5.  Security Considerations

   To be done.

6.  Acknowledgements

   Jukka Ylitalo and Pekka Nikander have contributed many ideas, time
   and effort to the native HIP API.  Thomas Henderson, Kristian Slavov,
   Julien Laganier, Jaakko Kangasharju, Mika Kousa, Jan Melen, Andrew
   McGregor, Sasu Tarkoma, Lars Eggert, Joe Touch, Antti Jaervinen and Jaervinen,
   Anthony Joseph Joseph, Teemu Koponen and Juha-Matti Tapio have also provided
   valuable ideas and feedback.

7.  References

7.1.  Normative References


              Henderson, T. and P. Nikander, "Using HIP with Legacy
              Applications", draft-henderson-hip-applications-03 (work
              in progress), May 2006.

              Moskowitz, R., "Host Identity Protocol",
              draft-ietf-hip-base-07 (work in progress), February 2007.

              Komu, M., "Socket Application Program Interface (API) for
              Multihoming Shim", draft-ietf-shim6-multihome-shim-api-01
              (work in progress), October 2006.

              Komu, M., "IPsec Application Programming Interfaces",
              draft-komu-btns-api-00 (work in progress), October 2006.

   [POSIX]    Institute of Electrical and Electronics Engineers, "IEEE
              Std. 1003.1-2001 Standard for Information Technology -
              Portable Operating System Interface (POSIX)", Dec 2001.


   [RFC3493]  Gilligan, R., Thomson, S., Bound, J., McCann, J., and W.
              Stevens, "Basic Socket Interface Extensions for IPv6",
              RFC 3493, February 2003.

   [3]  Moskowitz, R., "Host

7.2.  Informative References

              Lindqvist, J., "Establishing Host Identity Protocol", draft-ietf-hip-base-06 Protocol
              Opportunistic Mode with TCP Option",
              draft-lindqvist-hip-opportunistic-01 (work in progress), June
              March 2006.

   [4]  Nikander, P., "End-Host Mobility and Multihoming with the

              Lindqvist, J., "Piggybacking TCP to Host Identity
              Protocol", draft-ietf-hip-mm-03 (work in progress),
        March 2006.

   [5]  Henderson, T. and P. Nikander, "Using HIP with Legacy
        Applications", draft-henderson-hip-applications-03 (work in
        progress), May 2006.

7.2.  Informative References

   [6]  Richardson, M. and B. Sommerfeld, "Requirements for an IPsec
        API", draft-ietf-btns-ipsec-apireq-00 draft-lindqvist-hip-tcp-piggybacking-00 (work
              in progress),
        April July 2006.

Author's Address

   Miika Komu
   Helsinki Institute for Information Technology
   Tammasaarenkatu 3

   Phone: +358503841531
   Fax:   +35896949768

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