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PROPOSED STANDARD
Network Working Group                                         S. Farrell
Request for Comments: 3185                        Baltimore Technologies
Category: Standards Track                                      S. Turner
                                                                    IECA
                                                            October 2001


                  Reuse of CMS Content Encryption Keys

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.

Copyright Notice

   Copyright (C) The Internet Society (2001).  All Rights Reserved.

Abstract

   This document describes a way to include a key identifier in a CMS
   (Cryptographic Message Syntax) enveloped data structure, so that the
   content encryption key can be re-used for further enveloped data
   packets.

Table Of Contents

   1. Introduction...................................................  2
   2. Applicability..................................................  2
   3. How to do it...................................................  3
   4. Using different CEK and KEK algorithms.........................  4
   5. Conformance....................................................  5
   6. Security Considerations........................................  5
   7. References.....................................................  6
   Authors' Addresses................................................  6
   Appendix A: ASN.1 Module..........................................  7
   Full Copyright Statement.......................................... 10











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1. Introduction

   CMS [CMS] specifies EnvelopedData.  EnvelopedData supports data
   encryption using either symmetric or asymmetric key management
   techniques.  Since asymmetric key establishment is relatively
   expensive, it is desirable in some environments to re-use a shared
   content-encryption key established using asymmetric mechanisms for
   encryption operations in subsequent messages.

   The basic idea here is to reuse the content-encryption key (CEK) from
   a message (say MSG1) to derive the key-encryption key (KEK) for a
   later message, (MSG2), by including a reference value for the CEK in
   message 1, and that same value as the KEKIdentifier for message 2.
   The CEK from message 1 is called the "referenced CEK".

   The key words "MUST", "REQUIRED", "SHOULD", "RECOMMENDED", and "MAY"
   in this document are to be interpreted as described in [RFC2119].

2. Applicability

   This specification is intended to be used to provide more efficient
   selective field confidentiality between communicating peers, in
   particular in the cases where:

   -  The originator is a client that wishes to send a number of fields
      to a server (the recipient) in a single transaction, where the
      referenced CEK is used for the separate encryption of each field.

   -  The originator and recipient are servers that communicate very
      frequently and use this specification purely for efficiency.

   This specification is not intended to be applicable in all cases.  It
   is suited for use where:

   -  Its use is further scoped: that is, this specification doesn't
      define a protocol but merely a trick that can be used in a larger
      context and additional specification will be needed for each such
      case.  In particular, in order to use this specification, it is
      REQUIRED to define the originators' and recipients' behavior where
      a referenced CEK has been "lost".

   -  This specification is not suitable for general group key
      management.








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   -  The underlying cryptographic API is suitable: it is very likely
      that any cryptographic API that completely "hides" the bits of
      cryptographic keys from the CMS layer will prevent reuse of a
      referenced CEK (since they won't have a primitive that allows
      MSG1.CEK to be transformed to MSG2.KEK).

   -  The algorithms for content and key encryption have compatible key
      values and strengths, that is, if MSG1.contentEncryptionAlgorithm
      is a 40bit cipher and MSG2.keyEncryptionAlgorithm requires 168
      bits of keying material, then this specification SHOULD NOT be
      used.

   There are other ways that could be envisaged to establish the
   required symmetric keying material, e.g., by leveraging a group
   keying scheme or by defining a content type that contains a KEK
   value.  Although this scheme is much simpler than generic group key
   management, if an implementation already supports group key
   management then this scheme doesn't add value.  This scheme is also
   suitable for inclusion in CMS libraries (though the addition of new
   state might be a problem for some implementations), which can offer
   some advantages over application layer schemes (e.g., where the
   content includes MSG2.KEK).

3. How to do it

   In order to reference the content-encryption key (CEK) used in an
   EnvelopedData, a key identifier can be included in the
   unprotectedAttrs field of MSG1.  This key can then be used to derive
   the key-encryption key (KEK) for other instances of EnvelopedData or
   for other purposes.  If the CEK from MSG1 is to be used to derive the
   KEK for MSG2 then MSG1 MUST contain an unprotectedAttrs Attribute of
   type id-aa-CEKReference with a single value using the CEKReference
   syntax.

   MSG2.KEK is to be derived by reversing the bytes of MSG1.CEK.  The
   byte reversal is to avoid an attack where the attacker has a known
   plaintext and the related ciphertext (encrypted with MSG1.CEK) that
   (otherwise) could be directly used as a MSG2.KEK.

   The application MUST ensure that the relevant algorithms are
   compatible.  That is, a CEKReference attribute alone can only be used
   where the content-encryption algorithm from MSG1 employs the same
   type of symmetric key as the key-encryption algorithm from MSG2.








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   Notes:

   1) There is nothing to prevent inclusion of a CEKReference attribute
      in MSG2 as well as in MSG1.  That is, an originator could "roll"
      the referenced CEK with every message.

   2) The CEKReference attribute can occur with any of the choices for
      RecipientInfo: ktri, kari or kekri.  Implementors MUST NOT assume
      that CEKReference can only occur where ktri or kari is used.

   id-aa-CEKReference OBJECT IDENTIFIER ::= { id-aa 30 }
   CEKReference ::= OCTET STRING

   id-aa is an object identifier defined in [CMS-MSG].

   In order to allow the originator of MSG1 to indicate the "lifetime"
   of the CEK, the originator MAY include a CEKMaxDecrypts attribute,
   also in the unprotectedAttrs field of EnvelopedData.  This attribute
   has an INTEGER syntax (the value MUST be >=1 and maximally 2^31), and
   indicates to the recipient the maximum number of messages (excluding
   MSG1) that will use the referenced CEK.  This Attribute MUST only be
   sent when a CEKReference attribute is also included.

   The recipient SHOULD maintain the CEKReference information (minimally
   the key identifier and the CEK value) while less than maxDecrypt
   messages have been successfully received.  Recipients SHOULD delete
   the CEKReference information after some locally configured period.

   When this attribute is not present, originators and recipients SHOULD
   behave as if a value of one had been sent.

   id-aa-CEKMaxDecrypts OBJECT IDENTIFIER ::= { id-aa 31 }
   CEKMaxDecrypts ::= INTEGER

   If CEKMaxDecrypts is missing, or has the value one, then each CEK
   will be re-used once as the KEK for the next message.  This means
   that MSG[n].KEK is the byte-reversal of MSG[n-1].CEK; subsequently
   MSG[n+1].KEK will be the byte-reversal of MSG[n].CEK.  Note that
   MSG[n-1].CEK has no impact whatsoever to MSG[n+1], so long as CEKs
   are generated randomly (and not e.g., derived from KEKs somehow).

4. Using different CEK and KEK algorithms

   Where MSG1.content-encryption algorithm and MSG2.key-encryption
   algorithm are the same then the MSG2.KEK is the byte-reverse of
   MSG1.CEK.  However, in general, these algorithms MAY differ, e.g.,
   requiring different key lengths.  This section specifies a generic
   way to derive MSG2.KEK for such cases.



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   Note: In some sense, the CEK and KEK algorithms are never the "same",
   e.g., id-alg-CMS3DESwrap and des-ede3-cbc differ.  However, for the
   purposes of this specification, all we care about is that the
   algorithms use the same format and size of keying material (see also
   security considerations) and that they do not differ significantly in
   terms of the resulting cryptographic "strength."  In that sense the
   two algorithms in the example above are the "same."

   Implementations MAY include this functionality.

   The basic approach is to use the PBKDF2 key derivation function
   defined in PKCS#5 [RFC2898], but using MSG1.CEK as input instead of a
   password.  The output of the PBKDF2 function is MSG2.KEK.  To this
   end, a new attribute type is defined which allows passing of the
   required parameters.

   id-aa-KEKDerivationAlg OBJECT IDENTIFIER ::= { id-aa 32 }
   KEKDerivationAlgorithm ::= SEQUENCE {
         kekAlg          AlgorithmIdentifier,
         pbkdf2Param     PBKDF2-params
   }

   kekAlg is the algorithm identifier (and associated parameters, if
   any), for the MSG2 key encryption algorithm.  Note that it is not
   necessary to protect this field since modification of keyAlg only
   represents a denial-of-service attack.

   The PBKDF2 algorithm parameters are to be handled as follows:

   -  The salt MUST use the "specified" element of the CHOICE.
   -  The message originator selects the iterationCount.
   -  The value of keyLength is determined by the kekAlg and MUST be
      present.
   -  The prf field MUST use the default algorithm specified in
      [RFC2898] which is algid-hmacWithSHA1 (and so the prf field MUST
      be omitted).

5. Conformance

   This specification only applies to messages where the CEKReference
   attribute is present.  All attributes specified here SHOULD be
   ignored unless they are present in a message containing a valid, new
   or recognized, existing value of CEKReference.  The CEKMaxDecrypts
   attribute is to be treated by the recipient as a hint, but MUST be
   honored by the originator.






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   The optional to implement KEKDerivationAlgorithm attribute MUST only
   be present when MSG1.content-encryption algorithm differs from
   MSG2.key-encryption algorithm, in which case it MUST be present.
   Implementations that recognize this attribute, but do not support the
   functionality SHOULD ignore the attribute.

   Ignoring attributes as discussed above, will lead to decryption
   failures.  CMS implementations SHOULD be able to signal the
   particular reason for this failure to the calling application.

6. Security Considerations

   Encryption does not provide authentication, for example, if the
   encryptedContent is essentially random then recipients MUST NOT
   assume that "knowing" a CEKReference value proves anything - anyone
   could have created the EnvelopedData.  This is relevant both for
   security (the recovered plaintext should not be entirely random) and
   for avoiding denial of service (the recipient MUST NOT assume that
   using the right CEKReference means that message originator is
   genuine).

   Similarly, using the correct CEKReference does not mean that a
   message has not been replayed or inserted, and recipients MUST NOT
   assume that replay has been avoided.

   The maxDecrypts field presents a potential denial-of-service attack
   if a very large value is included by an originator in an attempt to
   get a recipient to consume memory by storing the referenced CEKs for
   a long period or if the originator never sends the indicated number
   of ciphertexts.  Recipients SHOULD therefore drop referenced CEKs
   where the maxDecrypts value is too large (according to local
   configuration) or the referenced CEK has been held for too long a
   period.

   Suppose MSG1 is sent to a set S1 of users.  In the case where MSG2 is
   sent to only a subset of users in S1, all users from S1 will still be
   able to decrypt MSG2 (since MSG2.KEK is computed only from MSG1.CEK).
   Implementers should be aware that in such cases, all members of the
   original set of recipients (S1) can access the plaintext of MSG2 and
   subsequent messages.

   The reason for the byte reversal is as follows: without the byte
   reversal, an attacker knowing some of MSG1.plaintext (a prefix in a
   field for instance) can use the corresponding ciphertext block as the
   next encrypted CEK, i.e., as MSG2.KEKRecipientInfo.encryptedKey.  Now
   the attacker knows the next CEK.  This attacks something this note is
   not claiming to protect (origin authentication), but is easily
   avoided using the byte reversal.  Byte-reversal was chosen over bit-



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   reversal since bit-reversal would cause parity bits from MSG1.CEK to
   be used as keying bits for MSG2.KEK for DES-based algorithms.  Note
   that byte reversal would similarly affect parity if parity checks
   spanned more than one octet, however no well-known algorithms operate
   in this way.

   Implementations should be very careful with this scheme if MSG[n].KEK
   is used to derive MSG[n].CEK, e.g., if MSG[n].CEK were the byte-
   reversal of MSG[n].KEK, then this scheme could result in a fixed key
   being unexpectedly used.

7. References

   [CMS]     Housley, R., "Cryptographic Message Syntax", RFC 2630, June
             1999.

   [CMS-MSG] Ramsdell, B. "S/MIME Version 3 Message Specification", RFC
             2633, June 1999.

   [RFC2898] Kaliski, B., "PKCS #5: Password-Based Cryptography
             Specification Version 2.0", RFC 2898, September 2000.

   [RFC2026] Bradner, S., "The Internet Standards Process -- Revision
             3", BCP 9, RFC 2026, October 1996.

   [RFC2119] Bradner, S., "Key words for use in RFCs to Indicate
             Requirement Levels", BCP 14, RFC 2119, March 1997.

Authors' Addresses

   Stephen Farrell,
   Baltimore Technologies,
   39 Parkgate Street,
   Dublin 8
   IRELAND

   Phone: +353-1-881-6000
   EMail: stephen.farrell@baltimore.ie


   Sean Turner
   IECA, Inc.
   9010 Edgepark Road
   Vienna, VA 22182
   USA

   Phone: +1.703.628.3180
   EMail: turners@ieca.com



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Appendix A: ASN.1 Module

   SMIMERcek
      { iso(1) member-body(2) us(840) rsadsi(113549) pkcs(1) pkcs-9(9)
        smime(16) modules(0) rcek(13) }

     -- This module contains the definitions of the attributes
     -- used for re-using the content encryption key from a
     -- message in further messages.

     DEFINITIONS IMPLICIT TAGS ::=

     BEGIN
     -- EXPORTS ALL --

     IMPORTS

       AlgorithmIdentifier FROM
            AuthenticationFramework { joint-iso-itu-t ds(5)
                  module(1) authenticationFramework(7) 3 } ;

       -- [RFC2898] uses 1993 ASN.1 to define PBKDF2-params.  Since
       -- this specification only uses 1988 ASN.1, the definition is
       -- repeated here for completeness.

       -- The DEFAULT prf field value, MUST be used for this
       -- specification
       digestAlgorithm OBJECT IDENTIFIER ::=
            { iso(1) member-body(2) us(840) rsadsi(113549) 2}
       id-hmacWithSHA1 OBJECT IDENTIFIER ::= {digestAlgorithm 7}

       -- [RFC2898] defines PBKDF2-params using 1993 ASN.1, which
       -- results in the same encoding as produced by the definition
       -- below.  See [RFC2898] for that definition.

       PBKDF2-params ::= SEQUENCE {
         salt CHOICE {
             specified OCTET STRING, -- MUST BE USED
             otherSource AlgorithmIdentifier -- DO NOT USE THIS FIELD
         },
         iterationCount INTEGER (1..MAX),
         keyLength INTEGER (1..MAX) OPTIONAL
       }

        -- id-aa is the arc with all new authenticated and
        -- unauthenticated attributes produced the by S/MIME
        -- Working Group.  It is also defined in [CMS-MSG]




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        id-aa OBJECT IDENTIFIER ::=
                {iso(1) member-body(2) usa(840) rsadsi(113549)
                 pkcs(1) pkcs-9(9) smime(16) attributes(2)}

        -- This attribute contains what will be the key identifier
        -- for subsequent messages
        id-aa-CEKReference OBJECT IDENTIFIER ::= { id-aa 30 }
        CEKReference ::= OCTET STRING

        -- This attribute contains a "hint" to the recipient
        -- indicating how many times the originator will use
        -- the re-used CEK
        id-aa-CEKMaxDecrypts      OBJECT IDENTIFIER ::= { id-aa 31 }
        CEKMaxDecrypts ::= INTEGER

        -- This attribute specifies the key derivation function
        -- to be used when the default byte reversal operation cannot
        -- be used.

        id-aa-KEKDerivationAlg     OBJECT IDENTIFIER ::= { id-aa 32 }
        KEKDerivationAlgorithm ::= SEQUENCE {
            kekAlg          AlgorithmIdentifier,
            pbkdf2Param     PBKDF2-params }


     END

























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Full Copyright Statement

   Copyright (C) The Internet Society (2001).  All Rights Reserved.

   This document and translations of it may be copied and furnished to
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   The limited permissions granted above are perpetual and will not be
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Acknowledgement

   Funding for the RFC Editor function is currently provided by the
   Internet Society.



















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