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[dragonfly.git] / crypto / heimdal-0.6.3 / doc / standardisation / rfc2203.txt

Network Working Group                                          M. Eisler
Request for Comments: 2203                                       A. Chiu
Category: Standards Track                                        L. Ling
                                                          September 1997


                   RPCSEC_GSS Protocol Specification

Status of this Memo

   This document specifies an Internet standards track protocol for the
   Internet community, and requests discussion and suggestions for
   improvements.  Please refer to the current edition of the "Internet
   Official Protocol Standards" (STD 1) for the standardization state
   and status of this protocol.  Distribution of this memo is unlimited.

Abstract

   This memo describes an ONC/RPC security flavor that allows RPC
   protocols to access the Generic Security Services Application
   Programming Interface (referred to henceforth as GSS-API).

Table of Contents

   1.  Introduction . . . . . . . . . . . . . . . . . . . . . . . . . 2
   2.  The ONC RPC Message Protocol . . . . . . . . . . . . . . . . . 2
   3.  Flavor Number Assignment . . . . . . . . . . . . . . . . . . . 3
   4.  New auth_stat Values . . . . . . . . . . . . . . . . . . . . . 3
   5.  Elements of the RPCSEC_GSS Security Protocol . . . . . . . . . 3
   5.1.  Version Selection  . . . . . . . . . . . . . . . . . . . . . 5
   5.2.  Context Creation . . . . . . . . . . . . . . . . . . . . . . 5
   5.2.1.  Mechanism and QOP Selection  . . . . . . . . . . . . . . . 5
   5.2.2.  Context Creation Requests  . . . . . . . . . . . . . . . . 6
   5.2.3.  Context Creation Responses . . . . . . . . . . . . . . . . 8
   5.2.3.1.  Context Creation Response - Successful Acceptance  . . . 8
   5.2.3.1.1.  Client Processing of Successful Context Creation
               Responses  . . . . . . . . . . . . . . . . . . . . . . 9
   5.2.3.2.  Context Creation Response - Unsuccessful Cases . . . . . 9
   5.3.  RPC Data Exchange  . . . . . . . . . . . . . . . . . . . .  10
   5.3.1.  RPC Request Header . . . . . . . . . . . . . . . . . . .  10
   5.3.2.  RPC Request Data . . . . . . . . . . . . . . . . . . . .  11
   5.3.2.1.  RPC Request Data - No Data Integrity . . . . . . . . .  11
   5.3.2.2.  RPC Request Data - With Data Integrity . . . . . . . .  11
   5.3.2.3.  RPC Request Data - With Data Privacy . . . . . . . . .  12
   5.3.3.  Server Processing of RPC Data Requests . . . . . . . . .  12
   5.3.3.1.  Context Management . . . . . . . . . . . . . . . . . .  12
   5.3.3.2.  Server Reply - Request Accepted  . . . . . . . . . . .  14
   5.3.3.3.  Server Reply - Request Denied  . . . . . . . . . . . .  15



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   5.3.3.4.  Mapping of GSS-API Errors to Server Responses  . . . .  16
   5.3.3.4.1.  GSS_GetMIC() Failure . . . . . . . . . . . . . . . .  16
   5.3.3.4.2.  GSS_VerifyMIC() Failure  . . . . . . . . . . . . . .  16
   5.3.3.4.3.  GSS_Unwrap() Failure . . . . . . . . . . . . . . . .  16
   5.3.3.4.4.  GSS_Wrap() Failure . . . . . . . . . . . . . . . . .  16
   5.4.  Context Destruction  . . . . . . . . . . . . . . . . . . .  17
   6.  Set of GSS-API Mechanisms  . . . . . . . . . . . . . . . . .  17
   7.  Security Considerations  . . . . . . . . . . . . . . . . . .  18
   7.1.  Privacy of Call Header . . . . . . . . . . . . . . . . . .  18
   7.2.  Sequence Number Attacks  . . . . . . . . . . . . . . . . .  18
   7.2.1.  Sequence Numbers Above the Window  . . . . . . . . . . .  18
   7.2.2.  Sequence Numbers Within or Below the Window  . . . . . .  18
   7.3.  Message Stealing Attacks . . . . . . . . . . . . . . . . .  19
   Appendix A. GSS-API Major Status Codes . . . . . . . . . . . . .  20
   Acknowledgements . . . . . . . . . . . . . . . . . . . . . . . .  22
   Authors' Addresses . . . . . . . . . . . . . . . . . . . . . . .  23

1.  Introduction

   This document describes the protocol used by the RPCSEC_GSS security
   flavor.  Security flavors have been called authentication flavors for
   historical reasons. This memo recognizes that there are two other
   security services besides authentication, integrity, and privacy, and
   so defines a new RPCSEC_GSS security flavor.

   The protocol is described using the XDR language [Srinivasan-xdr].
   The reader is assumed to be familiar with ONC RPC and the security
   flavor mechanism [Srinivasan-rpc].  The reader is also assumed to be
   familiar with the GSS-API framework [Linn].  The RPCSEC_GSS security
   flavor uses GSS-API interfaces to provide security services that are
   independent of the underlying security mechanism.

2.  The ONC RPC Message Protocol

   This memo refers to the following XDR types of the ONC RPC protocol,
   which are described in the document entitled Remote Procedure Call
   Protocol Specification Version 2 [Srinivasan-rpc]:

      msg_type
      reply_stat
      auth_flavor
      accept_stat
      reject_stat
      auth_stat
      opaque_auth
      rpc_msg
      call_body
      reply_body



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      accepted_reply
      rejected_reply

3.  Flavor Number Assignment

   The RPCSEC_GSS security flavor has been assigned the value of 6:

      enum auth_flavor {
          ...
          RPCSEC_GSS = 6      /* RPCSEC_GSS security flavor */
      };

4.  New auth_stat Values

   RPCSEC_GSS requires the addition of two new values to the auth_stat
   enumerated type definition:

      enum auth_stat {
              ...
              /*
               * RPCSEC_GSS errors
               */
              RPCSEC_GSS_CREDPROBLEM = 13,
              RPCSEC_GSS_CTXPROBLEM = 14
      };

   The descriptions of these two new values are defined later in this
   memo.

5.  Elements of the RPCSEC_GSS Security Protocol

   An RPC session based on the RPCSEC_GSS security flavor consists of
   three phases: context creation, RPC data exchange, and context
   destruction.  In the following discussion, protocol elements for
   these three phases are described.

   The following description of the RPCSEC_GSS protocol uses some of the
   definitions within XDR language description of the RPC protocol.

   Context creation and destruction use control messages that are not
   dispatched to service procedures registered by an RPC server.  The
   program and version numbers used in these control messages are the
   same as the RPC service's program and version numbers.  The procedure
   number used is NULLPROC (zero).  A field in the credential
   information (the gss_proc field which is defined in the
   rpc_gss_cred_t structure below) specifies whether a message is to be
   interpreted as a control message or a regular RPC message.  If this
   field is set to RPCSEC_GSS_DATA, no control action is implied; in



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   this case, it is a regular data message.  If this field is set to any
   other value, a control action is implied.  This is described in the
   following sections.

   Just as with normal RPC data exchange messages, the transaction
   identifier (the xid field in struct rpc_msg), should be set to unique
   values on each call for context creation and context destruction.

   The following definitions are used for describing the protocol.

      /* RPCSEC_GSS control procedures */


      enum rpc_gss_proc_t {
              RPCSEC_GSS_DATA = 0,
              RPCSEC_GSS_INIT = 1,
              RPCSEC_GSS_CONTINUE_INIT = 2,
              RPCSEC_GSS_DESTROY = 3
      };

      /* RPCSEC_GSS services */

      enum rpc_gss_service_t {
          /* Note: the enumerated value for 0 is reserved. */
          rpc_gss_svc_none = 1,
          rpc_gss_svc_integrity = 2,
          rpc_gss_svc_privacy = 3
      };

      /* Credential */

      /*
       * Note: version 0 is reserved for possible future
       * definition of a version negotiation protocol
       *
       */
      #define RPCSEC_GSS_VERS_1 1

      struct rpc_gss_cred_t {
          union switch (unsigned int version) { /* version of
                                                      RPCSEC_GSS */
          case RPCSEC_GSS_VERS_1:
              struct {
                  rpc_gss_proc_t gss_proc;  /* control procedure */
                  unsigned int seq_num;   /* sequence number */
                  rpc_gss_service_t service; /* service used */
                  opaque handle<>;       /* context handle */
              } rpc_gss_cred_vers_1_t;



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          }
      };

      /* Maximum sequence number value */

      #define MAXSEQ 0x80000000

5.1.  Version Selection

   This document defines just one protocol version (RPCSEC_GSS_VERS_1).
   The client should assume that the server supports RPCSEC_GSS_VERS_1
   and issue a Context Creation message (as described in the section
   RPCSEC_GSS_VERS_1, the RPC response will have a reply_stat of
   MSG_DENIED, a rejection status of AUTH_ERROR, and an auth_stat of
   AUTH_REJECTED_CRED.

5.2.  Context Creation

   Before RPC data is exchanged on a session using the RPCSEC_GSS
   flavor, a context must be set up between the client and the server.
   Context creation may involve zero or more RPC exchanges.  The number
   of exchanges depends on the security mechanism.

5.2.1.  Mechanism and QOP Selection

   There is no facility in the RPCSEC_GSS protocol to negotiate GSS-API
   mechanism identifiers or QOP values. At minimum, it is expected that
   implementations of the RPCSEC_GSS protocol provide a means to:

   *    specify mechanism identifiers, QOP values, and RPCSEC_GSS
        service values on the client side, and to

   *    enforce mechanism identifiers, QOP values, and RPCSEC_GSS
        service values on a per-request basis on the server side.

   It is necessary that above capabilities exist so that applications
   have the means to conform the required set of required set of
   <mechanism, QOP, service> tuples (See the section entitled Set of
   GSS-API Mechanisms).  An application may negotiate <mechanism, QOP,
   service> selection within its protocol or via an out of band
   protocol. Hence it may be necessary for RPCSEC_GSS implementations to
   provide programming interfaces for the specification and enforcement
   of <mechanism, QOP, service>.

   Additionally, implementations may depend on negotiation schemes
   constructed as pseudo-mechanisms under the GSS-API.  Because such
   schemes are below the GSS-API layer, the RPCSEC_GSS protocol, as
   specified in this document, can make use of them.



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5.2.2.  Context Creation Requests

   The first RPC request from the client to the server initiates context
   creation.  Within the RPC message protocol's call_body structure,
   rpcvers is set to 2. prog and vers are always those for the service
   being accessed.  The proc is always set to NULLPROC (zero).

   Within the RPC message protocol's cred structure, flavor is set to
   RPCSEC_GSS (6).  The opaque data of the cred structure (the body
   field) constituting the credential encodes the rpc_gss_cred_t
   structure defined previously.

   The values of the fields contained in the rpc_gss_cred_t structure
   are set as follows.  The version field is set to the version of the
   RPCSEC_GSS protocol the client wants to use.  The remainder of this
   memo documents version RPCSEC_GSS_VERS_1 of RPCSEC_GSS, and so the
   version field would be set to RPCSEC_GSS_VERS_1.  The gss_proc field
   must be set to RPCSEC_GSS_INIT for the first creation request.  In
   subsequent creation requests, the gss_proc field must be set to
   RPCSEC_GSS_CONTINUE_INIT.  In a creation request, the seq_num and
   service fields are undefined and both must be ignored by the server.
   In the first creation request, the handle field is NULL (opaque data
   of zero length).  In subsequent creation requests, handle must be
   equal to the value returned by the server.  The handle field serves
   as the identifier for the context, and will not change for the
   duration of the context, including responses to
   RPCSEC_GSS_CONTINUE_INIT.

   The verifier field in the RPC message header is also described by the
   opaque_auth structure.  All creation requests have the NULL verifier
   (AUTH_NONE flavor with zero length opaque data).

   Following the verifier are the call data (procedure specific
   parameters).  Note that the proc field of the call_body structure is
   set to NULLPROC, and thus normally there would be zero octets
   following the verifier.  However, since there is no RPC data exchange
   during a context creation, it is safe to transfer information
   following the verifier.  It is necessary to "overload" the call data
   in this way, rather than pack the GSS-API token into the RPC header,
   because RPC Version 2 restricts the amount of data that can be sent
   in the header.  The opaque body of the credential and verifier fields
   can be each at most 400 octets long, and GSS tokens can be longer
   than 800 octets.








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   The call data for a context creation request is described by the
   following structure for all creation requests:

      struct rpc_gss_init_arg {
          opaque gss_token<>;
      };

   Here, gss_token is the token returned by the call to  GSS-API's
   GSS_Init_sec_context() routine, opaquely encoded.  The value of this
   field will likely be different in each creation request, if there is
   more than one creation request.  If no token is returned by the call
   to GSS_Init_sec_context(), the context must have been created
   (assuming no errors), and there will not be any more creation
   requests.

   When GSS_Init_sec_context() is called, the parameters
   replay_det_req_flag and sequence_req_flag must be turned off. The
   reasons for this are:

   *    ONC RPC can be used over unreliable transports and provides no
        layer to reliably re-assemble messages. Thus it is possible for
        gaps in message sequencing to occur, as well as out of order
        messages.

   *    RPC servers can be multi-threaded, and thus the order in which
        GSS-API messages are signed or wrapped can be different from the
        order in which the messages are verified or unwrapped, even if
        the requests are sent on reliable transports.

   *    To maximize convenience of implementation, the order in which an
        ONC RPC entity will verify the header and verify/unwrap the body
        of an RPC call or reply is left unspecified.

   The RPCSEC_GSS protocol provides for protection from replay attack,
   yet tolerates out-of-order delivery or processing of messages and
   tolerates dropped requests.















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5.2.3.  Context Creation Responses

5.2.3.1.  Context Creation Response - Successful Acceptance

   The response to a successful creation request has an MSG_ACCEPTED
   response with a status of SUCCESS.  The results field encodes a
   response with the following structure:

      struct rpc_gss_init_res {
              opaque handle<>;
              unsigned int gss_major;
              unsigned int gss_minor;
              unsigned int seq_window;
              opaque gss_token<>;
      };

   Here, handle is non-NULL opaque data that serves as the context
   identifier. The client must use this value in all subsequent requests
   whether control messages or otherwise).  The gss_major and gss_minor
   fields contain the results of the call to GSS_Accept_sec_context()
   executed by the server.  The values for the gss_major field are
   defined in Appendix A of this document.  The values for the gss_minor
   field are GSS-API mechanism specific and are defined in the
   mechanism's specification.  If gss_major is not one of GSS_S_COMPLETE
   or GSS_S_CONTINUE_NEEDED, the context setup has failed; in this case
   handle and gss_token must be set to NULL by the server.  The value of
   gss_minor is dependent on the value of gss_major and the security
   mechanism used.  The gss_token field contains any token returned by
   the GSS_Accept_sec_context() call executed by the server.  A token
   may be returned for both successful values of gss_major.  If the
   value is GSS_S_COMPLETE, it indicates that the server is not
   expecting any more tokens, and the RPC Data Exchange phase must begin
   on the subsequent request from the client. If the value is
   GSS_S_CONTINUE_NEEDED, the server is expecting another token.  Hence
   the client must send at least one more creation request (with
   gss_proc set to RPCSEC_GSS_CONTINUE_INIT in the request's credential)
   carrying the required token.

   In a successful response, the seq_window field is set to the sequence
   window length supported by the server for this context.  This window
   specifies the maximum number of client requests that may be
   outstanding for this context. The server will accept "seq_window"
   requests at a time, and these may be out of order.  The client may
   use this number to determine the number of threads that can
   simultaneously send requests on this context.






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   If gss_major is GSS_S_COMPLETE, the verifier's (the verf element in
   the response) flavor field is set to RPCSEC_GSS, and the body field
   set to the checksum of the seq_window (in network order). The QOP
   used for this checksum is 0 (zero), which is the default QOP.  For
   all other values of gss_major, a NULL verifier (AUTH_NONE flavor with
   zero-length opaque data) is used.

5.2.3.1.1.  Client Processing of Successful Context Creation Responses

   If the value of gss_major in the response is GSS_S_CONTINUE_NEEDED,
   then the client, per the GSS-API specification, must invoke
   GSS_Init_sec_context() using the token returned in gss_token in the
   context creation response. The client must then generate a context
   creation request, with gss_proc set to RPCSEC_GSS_CONTINUE_INIT.

   If the value of gss_major in the response is GSS_S_COMPLETE, and if
   the client's previous invocation of GSS_Init_sec_context() returned a
   gss_major value of GSS_S_CONTINUE_NEEDED, then the client, per the
   GSS-API specification, must invoke GSS_Init_sec_context() using the
   token returned in gss_token in the context creation response. If
   GSS_Init_sec_context() returns GSS_S_COMPLETE, the context is
   successfully set up, and the RPC data exchange phase must begin on
   the subsequent request from the client.

5.2.3.2.  Context Creation Response - Unsuccessful Cases

   An MSG_ACCEPTED reply (to a creation request) with an acceptance
   status of other than SUCCESS has a NULL verifier (flavor set to
   AUTH_NONE, and zero length opaque data in the body field), and is
   formulated as usual for different status values.

   An MSG_DENIED reply (to a creation request) is also formulated as
   usual.  Note that MSG_DENIED could be returned because the server's
   RPC implementation does not recognize the RPCSEC_GSS security flavor.
   RFC 1831 does not specify the appropriate reply status in this
   instance, but common implementation practice appears to be to return
   a rejection status of AUTH_ERROR with an auth_stat of
   AUTH_REJECTEDCRED. Even though two new values (RPCSEC_GSS_CREDPROBLEM
   and RPCSEC_GSS_CTXPROBLEM) have been defined for the auth_stat type,
   neither of these two can be returned in responses to context creation
   requests.  The auth_stat new values can be used for responses to
   normal (data) requests.  This is described later.

   MSG_DENIED might also be returned if the RPCSEC_GSS version number in
   the credential is not supported on the server. In that case, the
   server returns a rejection status of AUTH_ERROR, with an auth_stat of

   AUTH_REJECTED_CRED.



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5.3.  RPC Data Exchange

   The data exchange phase is entered after a context has been
   successfully set up. The format of the data exchanged depends on the
   security service used for the request.  Although clients can change
   the security service and QOP used on a per-request basis, this may
   not be acceptable to all RPC services; some RPC services may "lock"
   the data exchange phase into using the QOP and service used on the
   first data exchange message.  For all three modes of service (no data
   integrity, data integrity, data privacy), the RPC request header has
   the same format.

5.3.1.  RPC Request Header

   The credential has the opaque_auth structure described earlier.  The
   flavor field is set to RPCSEC_GSS.  The credential body is created by
   XDR encoding the rpc_gss_cred_t structure listed earlier into an
   octet stream, and then opaquely encoding this octet stream as the
   body field.

   Values of the fields contained in the rpc_gss_cred_t structure are
   set as follows.  The version field is set to same version value that
   was used to create the context, which within the scope of this memo
   will always be RPCSEC_GSS_VERS_1.  The gss_proc field is set to
   RPCSEC_GSS_DATA.  The service field is set to indicate the desired
   service (one of rpc_gss_svc_none, rpc_gss_svc_integrity, or
   rpc_gss_svc_privacy).  The handle field is set to the context handle
   value received from the RPC server during context creation.  The
   seq_num field can start at any value below MAXSEQ, and must be
   incremented (by one or more) for successive requests.  Use of
   sequence numbers is described in detail when server processing of the
   request is discussed.

   The verifier has the opaque_auth structure described earlier.  The
   flavor field is set to RPCSEC_GSS.  The body field is set as follows.
   The checksum of the RPC header (up to and including the credential)
   is computed using the GSS_GetMIC() call with the desired QOP.  This
   returns the checksum as an opaque octet stream and its length.  This
   is encoded into the body field.  Note that the QOP is not explicitly
   specified anywhere in the request.  It is implicit in the checksum or
   encrypted data.  The same QOP value as is used for the header
   checksum must also be used for the data (for checksumming or
   encrypting), unless the service used for the request is
   rpc_gss_svc_none.







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5.3.2.  RPC Request Data

5.3.2.1.  RPC Request Data - No Data Integrity

   If the service specified is rpc_gss_svc_none, the data (procedure
   arguments) are not integrity or privacy protected.  They are sent in
   exactly the same way as they would be if the AUTH_NONE flavor were
   used (following the verifier).  Note, however, that since the RPC
   header is integrity protected, the sender will still be authenticated
   in this case.

5.3.2.2.  RPC Request Data - With Data Integrity

   When data integrity is used, the request data is represented as
   follows:

      struct rpc_gss_integ_data {
          opaque databody_integ<>;
          opaque checksum<>;
      };

   The databody_integ field is created as follows.  A structure
   consisting of a sequence number followed by the procedure arguments
   is constructed. This is shown below as the type rpc_gss_data_t:

      struct rpc_gss_data_t {
          unsigned int seq_num;
          proc_req_arg_t arg;
      };

   Here, seq_num must have the same value as in the credential.  The
   type proc_req_arg_t is the procedure specific XDR type describing the
   procedure arguments (and so is not specified here).  The octet stream
   corresponding to the XDR encoded rpc_gss_data_t structure and its
   length are placed in the databody_integ field. Note that because the
   XDR type of databody_integ is opaque, the XDR encoding of
   databody_integ will include an initial four octet length field,
   followed by the XDR encoded octet stream of rpc_gss_data_t.

   The checksum field represents the checksum of the XDR encoded octet
   stream corresponding to the XDR encoded rpc_gss_data_t structure
   (note, this is not the checksum of the databody_integ field).  This
   is obtained using the GSS_GetMIC() call, with the same QOP as was
   used to compute the header checksum (in the verifier). The







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   GSS_GetMIC() call returns the checksum as an opaque octet stream and
   its length. The checksum field of struct rpc_gss_integ_data has an
   XDR type of opaque. Thus the checksum length from GSS_GetMIC() is
   encoded as a four octet  length field, followed by the checksum,
   padded to a multiple of four octets.

5.3.2.3.  RPC Request Data - With Data Privacy

   When data privacy is used, the request data is represented as
   follows:

      struct rpc_gss_priv_data {
          opaque databody_priv<>
      };

   The databody_priv field is created as follows.  The rpc_gss_data_t
   structure described earlier is constructed again in the same way as
   for the case of data integrity.  Next, the GSS_Wrap() call is invoked
   to encrypt the octet stream corresponding to the rpc_gss_data_t
   structure, using the same value for QOP (argument qop_req to
   GSS_Wrap()) as was used for the header checksum (in the verifier) and
   conf_req_flag (an argument to GSS_Wrap()) of TRUE.  The GSS_Wrap()
   call returns an opaque octet stream (representing the encrypted
   rpc_gss_data_t structure) and its length, and this is encoded as the
   databody_priv field. Since databody_priv has an XDR type of opaque,
   the length returned by GSS_Wrap() is encoded as the four octet
   length, followed by the encrypted octet stream (padded to a multiple
   of four octets).

5.3.3.  Server Processing of RPC Data Requests

5.3.3.1.  Context Management

   When a request is received by the server, the following are verified
   to be acceptable:

   *    the version number in the credential

   *    the service specified in the credential

   *    the context handle specified in the credential

   *    the header checksum in the verifier (via GSS_VerifyMIC())

   *    the sequence number (seq_num) specified in the credential (more
        on this follows)





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   The gss_proc field in the credential must be set to RPCSEC_GSS_DATA
   for data requests (otherwise, the message will be interpreted as a
   control message).

   The server maintains a window of "seq_window" sequence numbers,
   starting with the last sequence number seen and extending backwards.
   If a sequence number higher than the last number seen is received
   (AND if GSS_VerifyMIC() on the header checksum from the verifier
   returns GSS_S_COMPLETE), the window is moved forward to the new
   sequence number.  If the last sequence number seen is N, the server
   is prepared to receive requests with sequence numbers in the range N
   through (N - seq_window + 1), both inclusive.  If the sequence number
   received falls below this range, it is silently discarded.  If the
   sequence number is within this range, and the server has not seen it,
   the request is accepted, and the server turns on a bit to "remember"
   that this sequence number has been seen.  If the server determines
   that it has already seen a sequence number within the window, the
   request is silently discarded. The server should select a seq_window
   value based on the number requests it expects to process
   simultaneously. For example, in a threaded implementation seq_window
   might be equal to the number of server threads. There are no known
   security issues with selecting a large window. The primary issue is
   how much space the server is willing to allocate to keep track of
   requests received within the window.

   The reason for discarding requests silently is that the server is
   unable to determine if the duplicate or out of range request was due
   to a sequencing problem in the client, network, or the operating
   system, or due to some quirk in routing, or a replay attack by an
   intruder.  Discarding the request allows the client to recover after
   timing out, if indeed the duplication was unintentional or well
   intended.  Note that a consequence of the silent discard is that
   clients may increment the seq_num by more than one. The effect of
   this is that the window will move forward more quickly. It is not
   believed that there is any benefit to doing this.

   Note that the sequence number algorithm requires that the client
   increment the sequence number even if it is retrying a request with
   the same RPC transaction identifier.  It is not infrequent for
   clients to get into a situation where they send two or more attempts
   and a slow server sends the reply for the first attempt. With
   RPCSEC_GSS, each request and reply will have a unique sequence
   number. If the client wishes to improve turn around time on the RPC
   call, it can cache the RPCSEC_GSS sequence number of each request it
   sends. Then when it receives a response with a matching RPC
   transaction identifier, it can compute the checksum of each sequence
   number in the cache to try to match the checksum in the reply's
   verifier.



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   The data is decoded according to the service specified in the
   credential.  In the case of integrity or privacy, the server ensures
   that the QOP value is acceptable, and that it is the same as that
   used for the header checksum in the verifier.  Also, in the case of
   integrity or privacy, the server will reject the message (with a
   reply status of MSG_ACCEPTED, and an acceptance status of
   GARBAGE_ARGS) if the sequence number embedded in the request body is
   different from the sequence number in the credential.

5.3.3.2.  Server Reply - Request Accepted

   An MSG_ACCEPTED reply to a request in the data exchange phase will
   have the verifier's (the verf element in the response) flavor field
   set to RPCSEC_GSS, and the body field set to the checksum (the output
   of GSS_GetMIC()) of the sequence number (in network order) of the
   corresponding request.  The QOP used is the same as the QOP used for
   the corresponding request.

   If the status of the reply is not SUCCESS, the rest of the message is
   formatted as usual.

   If the status of the message is SUCCESS, the format of the rest of
   the message depends on the service specified in the corresponding
   request message. Basically, what follows the verifier in this case
   are the procedure results, formatted in different ways depending on
   the requested service.

   If no data integrity was requested, the procedure results are
   formatted as for the AUTH_NONE security flavor.

   If data integrity was requested, the results are encoded in exactly
   the same way as the procedure arguments were in the corresponding
   request.  See the section 'RPC Request Data - With Data Integrity.'
   The only difference is that the structure representing the
   procedure's result - proc_res_arg_t - must be substituted in place of
   the request argument structure proc_req_arg_t.  The QOP used for the
   checksum must be the same as that used for constructing the reply
   verifier.

   If data privacy was requested, the results are encoded in exactly the
   same way as the procedure arguments were in the corresponding
   request.  See the section 'RPC Request Data - With Data Privacy.' The
   QOP used for  encryption must be the same as that used for
   constructing the reply verifier.







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5.3.3.3.  Server Reply - Request Denied

   An MSG_DENIED reply (to a data request) is formulated as usual.  Two
   new values (RPCSEC_GSS_CREDPROBLEM and RPCSEC_GSS_CTXPROBLEM) have
   been defined for the auth_stat type.  When the reason for denial of
   the request is a reject_stat of AUTH_ERROR, one of the two new
   auth_stat values could be returned in addition to the existing
   values.  These two new values have special significance from the
   existing reasons for denial of a request.

   The server maintains a list of contexts for the clients that are
   currently in session with it.  Normally, a context is destroyed when
   the client ends the session corresponding to it.  However, due to
   resource constraints, the server may destroy a context prematurely
   (on an LRU basis, or if the server machine is rebooted, for example).
   In this case, when a client request comes in, there may not be a
   context corresponding to its handle. The server rejects the request,
   with the reason RPCSEC_GSS_CREDPROBLEM in this case.  Upon receiving
   this error, the client must refresh the context - that is,
   reestablish it after destroying the old one - and try the request
   again.  This error is also returned if the context handle matches
   that of a different context that was allocated after the client's
   context was destroyed (this will be detected by a failure in
   verifying the header checksum).

   If the GSS_VerifyMIC() call on the header checksum (contained in the
   verifier) fails to return GSS_S_COMPLETE, the server rejects the
   request and returns an auth_stat of RPCSEC_GSS_CREDPROBLEM.

   When the client's sequence number exceeds the maximum the server will
   allow, the server will reject the request with the reason
   RPCSEC_GSS_CTXPROBLEM.  Also, if security credentials become stale
   while in use (due to ticket expiry in the case of the Kerberos V5
   mechanism, for example), the failures which result cause the
   RPCSEC_GSS_CTXPROBLEM reason to be returned.  In these cases also,
   the client must refresh the context, and retry the request.

   For other errors, retrying will not rectify the problem and the
   client must not refresh the context until the problem causing the
   client request to be denied is rectified.

   If the version field in the credential does not match the version of
   RPCSEC_GSS that was used when the context was created, the
   AUTH_BADCRED value is returned.

   If there is a problem with the credential, such a bad length, illegal
   control procedure, or an illegal service, the appropriate auth_stat
   status is AUTH_BADCRED.



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   Other errors can be returned as appropriate.

5.3.3.4.  Mapping of GSS-API Errors to Server Responses

   During the data exchange phase, the server may invoke GSS_GetMIC(),
   GSS_VerifyMIC(), GSS_Unwrap(), and GSS_Wrap(). If any of these
   routines fail to return GSS_S_COMPLETE, then various unsuccessful
   responses can be returned. The are described as follows for each of
   the aforementioned four interfaces.

5.3.3.4.1.  GSS_GetMIC() Failure

   When GSS_GetMIC() is called to generate the verifier in the response,
   a failure results in an RPC response with a reply status of
   MSG_DENIED, reject status of AUTH_ERROR and an auth status of
   RPCSEC_GSS_CTXPROBLEM.

   When GSS_GetMIC() is called to sign the call results (service is
   rpc_gss_svc_integrity), a failure results in no RPC response being
   sent. Since ONC RPC server applications will typically control when a
   response is sent, the failure indication will be returned to the
   server application and it can take appropriate action (such as
   logging the error).

5.3.3.4.2.  GSS_VerifyMIC() Failure

   When GSS_VerifyMIC() is called to verify the verifier in request, a
   failure results in an RPC response with a reply status of MSG_DENIED,
   reject status of AUTH_ERROR and an auth status of
   RPCSEC_GSS_CREDPROBLEM.

   When GSS_VerifyMIC() is called to verify the call arguments (service
   is rpc_gss_svc_integrity), a failure results in an RPC response with
   a reply status of MSG_ACCEPTED, and an acceptance status of
   GARBAGE_ARGS.

5.3.3.4.3.  GSS_Unwrap() Failure

   When GSS_Unwrap() is called to decrypt the call arguments (service is
   rpc_gss_svc_privacy), a failure results in an RPC response with a
   reply status of MSG_ACCEPTED, and an acceptance status of
   GARBAGE_ARGS.

5.3.3.4.4.  GSS_Wrap() Failure

   When GSS_Wrap() is called to encrypt the call results (service is
   rpc_gss_svc_privacy), a failure results in no RPC response being
   sent. Since ONC RPC server applications will typically control when a



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   response is sent, the failure indication will be returned to the
   application and it can take appropriate action (such as logging the
   error).

5.4.  Context Destruction

   When the client is done using the session, it must send a control
   message informing the server that it no longer requires the context.
   This message is formulated just like a data request packet, with the
   following differences:  the credential has gss_proc set to
   RPCSEC_GSS_DESTROY, the procedure specified in the header is
   NULLPROC, and there are no procedure arguments.  The sequence number
   in the request must be valid, and the header checksum in the verifier
   must be valid, for the server to accept the message.  The server
   sends a response as it would to a data request.  The client and
   server must then destroy the context for the session.

   If the request to destroy the context fails for some reason, the
   client need not take any special action.  The server must be prepared
   to deal with situations where clients never inform the server that
   they no longer are in session and so don't need the server to
   maintain a context.  An LRU mechanism or an aging mechanism should be
   employed by the server to clean up in such cases.

6.  Set of GSS-API Mechanisms

   RPCSEC_GSS is effectively a "pass-through" to the GSS-API layer, and
   as such it is inappropriate for the RPCSEC_GSS specification to
   enumerate a minimum set of required security mechanisms and/or
   quality of protections.

   If an application protocol specification references RPCSEC_GSS, the
   protocol specification must list a mandatory set of { mechanism, QOP,
   service } triples, such that an implementation cannot claim
   conformance to the protocol specification unless it implements the
   set of triples. Within each triple, mechanism is a GSS-API security
   mechanism, QOP is a valid quality-of-protection within the mechanism,
   and service is either rpc_gss_svc_integrity or rpc_gss_svc_privacy.

   For example, a network filing protocol built on RPC that depends on
   RPCSEC_GSS for security, might require that Kerberos V5 with the
   default QOP using the rpc_gss_svc_integrity service be supported by
   implementations conforming to the network filing protocol
   specification.







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7.  Security Considerations

7.1.  Privacy of Call Header

   The reader will note that for the privacy option, only the call
   arguments and results are encrypted. Information about the
   application in the form of RPC program number, program version
   number, and program procedure number is transmitted in the clear.
   Encrypting these fields in the RPC call header would have changed the
   size and format of the call header. This would have required revising
   the RPC protocol which was beyond the scope of this proposal. Storing
   the encrypted numbers in the credential would have obviated a
   protocol change, but would have introduced more overloading of fields
   and would have made implementations of RPC more complex. Even if the
   fields were encrypted somehow, in most cases an attacker can
   determine the program number and version number by examining the
   destination address of the request and querying the rpcbind service
   on the destination host [Srinivasan-bind].  In any case, even by not
   encrypting the three numbers, RPCSEC_GSS still improves the state of
   security over what existing RPC services have had available
   previously. Implementors of new RPC services that are concerned about
   this risk may opt to design in a "sub-procedure" field that is
   included in the service specific call arguments.

7.2.  Sequence Number Attacks

7.2.1.  Sequence Numbers Above the Window

   An attacker cannot coax the server into raising the sequence number
   beyond the range the legitimate client is aware of (and thus engineer
   a denial of server attack) without constructing an RPC request that
   will pass the header checksum. If the cost of verifying the header
   checksum is sufficiently large (depending on the speed of the
   processor doing the checksum and the cost of checksum algorithm), it
   is possible to envision a denial of service attack (vandalism, in the
   form of wasting processing resources) whereby the attacker sends
   requests that are above the window. The simplest method might be for
   the attacker to monitor the network traffic and then choose a
   sequence number that is far above the current sequence number. Then
   the attacker can send bogus requests using the above window sequence
   number.

7.2.2.  Sequence Numbers Within or Below the Window

   If the attacker sends requests that are within or below the window,
   then even if the header checksum is successfully verified, the server
   will silently discard the requests because the server assumes it has
   already processed the request. In this case, a server can optimize by



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   skipping the header checksum verification if the sequence number is
   below the window, or if it is within the window, not attempt the
   checksum verification if the sequence number has already been seen.

7.3.  Message Stealing Attacks

   This proposal does not address attacks where an attacker can block or
   steal messages without being detected by the server. To implement
   such protection would be tantamount to assuming a state in the RPC
   service. RPCSEC_GSS does not worsen this situation.









































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Appendix A. GSS-API Major Status Codes

   The GSS-API definition [Linn] does not include numerical values for
   the various GSS-API major status codes. It is expected that this will
   be addressed in future RFC. Until then, this appendix defines the
   values for each GSS-API major status code listed in the GSS-API
   definition.  If in the future, the GSS-API definition defines values
   for the codes that are different than what follows, then implementors
   of RPCSEC_GSS will be obliged to map them into the values defined
   below. If in the future, the GSS-API definition defines additional
   status codes not defined below, then the RPCSEC_GSS definition will
   subsume those additional values.

   Here are the definitions of each GSS_S_* major status that the
   implementor of RPCSEC_GSS can expect in the gss_major major field of
   rpc_gss_init_res.  These definitions are not in RPC description
   language form.  The numbers are in base 16 (hexadecimal):

      GSS_S_COMPLETE                  0x00000000
      GSS_S_CONTINUE_NEEDED           0x00000001
      GSS_S_DUPLICATE_TOKEN           0x00000002
      GSS_S_OLD_TOKEN                 0x00000004
      GSS_S_UNSEQ_TOKEN               0x00000008
      GSS_S_GAP_TOKEN                 0x00000010
      GSS_S_BAD_MECH                  0x00010000
      GSS_S_BAD_NAME                  0x00020000
      GSS_S_BAD_NAMETYPE              0x00030000
      GSS_S_BAD_BINDINGS              0x00040000
      GSS_S_BAD_STATUS                0x00050000
      GSS_S_BAD_MIC                   0x00060000
      GSS_S_BAD_SIG                   0x00060000
      GSS_S_NO_CRED                   0x00070000
      GSS_S_NO_CONTEXT                0x00080000
      GSS_S_DEFECTIVE_TOKEN           0x00090000
      GSS_S_DEFECTIVE_CREDENTIAL      0x000a0000
      GSS_S_CREDENTIALS_EXPIRED       0x000b0000
      GSS_S_CONTEXT_EXPIRED           0x000c0000
      GSS_S_FAILURE                   0x000d0000
      GSS_S_BAD_QOP                   0x000e0000
      GSS_S_UNAUTHORIZED              0x000f0000
      GSS_S_UNAVAILABLE               0x00100000
      GSS_S_DUPLICATE_ELEMENT         0x00110000
      GSS_S_NAME_NOT_MN               0x00120000
      GSS_S_CALL_INACCESSIBLE_READ    0x01000000
      GSS_S_CALL_INACCESSIBLE_WRITE   0x02000000
      GSS_S_CALL_BAD_STRUCTURE        0x03000000





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   Note that the GSS-API major status is split into three fields as
   follows:

        Most Significant Bit                     Least Significant Bit
        |------------------------------------------------------------|
        | Calling Error | Routine Error  |    Supplementary Info     |
        |------------------------------------------------------------|
      Bit 31           24 23            16 15                        0

   Up to one status in the Calling Error field can be logically ORed
   with up to one status in the Routine Error field which in turn can be
   logically ORed with zero or more statuses in the Supplementary Info
   field. If the resulting major status has a non-zero Calling Error
   and/or a non-zero Routine Error, then the applicable GSS-API
   operation has failed.  For purposes of RPCSEC_GSS, this means that
   the GSS_Accept_sec_context() call executed by the server has failed.

   If the major status is equal GSS_S_COMPLETE, then this indicates the
   absence of any Errors or Supplementary Info.

   The meanings of most of the GSS_S_* status are defined in the GSS-API
   definition, which the exceptions of:

   GSS_S_BAD_MIC       This code has the same meaning as GSS_S_BAD_SIG.

   GSS_S_CALL_INACCESSIBLE_READ
                        A required input parameter could not be read.

   GSS_S_CALL_INACCESSIBLE_WRITE
                        A required input parameter could not be written.

   GSS_S_CALL_BAD_STRUCTURE
                       A parameter was malformed.


















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Acknowledgements

   Much of the protocol was based on the AUTH_GSSAPI security flavor
   developed by Open Vision Technologies [Jaspan].  In particular, we
   acknowledge Barry Jaspan, Marc Horowitz, John Linn, and Ellen
   McDermott.

   Raj Srinivasan designed RPCSEC_GSS [Eisler] with input from Mike
   Eisler.  Raj, Roland Schemers, Lin Ling, and Alex Chiu contributed to
   Sun Microsystems' implementation of RPCSEC_GSS.

   Brent Callaghan, Marc Horowitz, Barry Jaspan, John Linn, Hilarie
   Orman, Martin Rex, Ted Ts'o, and John Wroclawski analyzed the
   specification and gave valuable feedback.

   Steve Nahm and Kathy Slattery reviewed various drafts of this
   specification.

   Much of content of Appendix A was excerpted from John Wray's Work in
   Progress on GSS-API Version 2 C-bindings.

References

   [Eisler]            Eisler, M., Schemers, R., and Srinivasan, R.
                       (1996).  "Security Mechanism Independence in ONC
                       RPC," Proceedings of the Sixth Annual USENIX
                       Security Symposium, pp. 51-65.

   [Jaspan]            Jaspan, B. (1995). "GSS-API Security for ONC
                       RPC," `95 Proceedings of The Internet Society
                       Symposium on Network and Distributed System
                       Security, pp. 144- 151.

   [Linn]              Linn, J., "Generic Security Service Application
                       Program Interface, Version 2", RFC 2078, January
                       1997.

   [Srinivasan-bind]   Srinivasan, R., "Binding Protocols for
                       ONC RPC Version 2", RFC 1833, August 1995.

   [Srinivasan-rpc]    Srinivasan, R., "RPC: Remote Procedure Call
                       Protocol Specification Version 2", RFC 1831,
                       August 1995.

   [Srinivasan-xdr]    Srinivasan, R., "XDR: External Data
                       Representation Standard", RFC 1832, August 1995.





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Authors' Addresses

   Michael Eisler
   Sun Microsystems, Inc.
   M/S UCOS03
   2550 Garcia Avenue
   Mountain View, CA 94043

   Phone: +1 (719) 599-9026
   EMail: mre@eng.sun.com


   Alex Chiu
   Sun Microsystems, Inc.
   M/S UMPK17-203
   2550 Garcia Avenue
   Mountain View, CA 94043

   Phone: +1 (415) 786-6465
   EMail: hacker@eng.sun.com


   Lin Ling
   Sun Microsystems, Inc.
   M/S UMPK17-201
   2550 Garcia Avenue
   Mountain View, CA 94043

   Phone: +1 (415) 786-5084
   EMail: lling@eng.sun.com





















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