Keywords: [--------|p], rivest-sharmir-adleman, public key encryption







Network Working Group                                          B. Harris
Request for Comments: 4432                                    March 2006
Category: Standards Track


              RSA Key Exchange for the Secure Shell (SSH)
                        Transport Layer Protocol

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 (2006).

Abstract

   This memo describes a key-exchange method for the Secure Shell (SSH)
   protocol based on Rivest-Shamir-Adleman (RSA) public-key encryption.
   It uses much less client CPU time than the Diffie-Hellman algorithm
   specified as part of the core protocol, and hence is particularly
   suitable for slow client systems.

1.  Introduction

   Secure Shell (SSH) [RFC4251] is a secure remote-login protocol.  The
   core protocol uses Diffie-Hellman key exchange.  On slow CPUs, this
   key exchange can take tens of seconds to complete, which can be
   irritating for the user.  A previous version of the SSH protocol,
   described in [SSH1], uses a key-exchange method based on
   Rivest-Shamir-Adleman (RSA) public-key encryption, which consumes an
   order of magnitude less CPU time on the client, and hence is
   particularly suitable for slow client systems such as mobile devices.
   This memo describes a key-exchange mechanism for the version of SSH
   described in [RFC4251] that is similar to that used by the older
   version, and about as fast, while retaining the security advantages
   of the newer protocol.









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2.  Conventions Used in This Document

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

   The data types "byte", "string", and "mpint" are defined in Section 5
   of [RFC4251].

   Other terminology and symbols have the same meaning as in [RFC4253].

3.  Overview

   The RSA key-exchange method consists of three messages.  The server
   sends to the client an RSA public key, K_T, to which the server holds
   the private key.  This may be a transient key generated solely for
   this SSH connection, or it may be re-used for several connections.
   The client generates a string of random bytes, K, encrypts it using
   K_T, and sends the result back to the server, which decrypts it.  The
   client and server each hash K, K_T, and the various key-exchange
   parameters to generate the exchange hash, H, which is used to
   generate the encryption keys for the session, and the server signs H
   with its host key and sends the signature to the client.  The client
   then verifies the host key as described in Section 8 of [RFC4253].

   This method provides explicit server identification as defined in
   Section 7 of [RFC4253].  It requires a signature-capable host key.

4.  Details

   The RSA key-exchange method has the following parameters:

       HASH     hash algorithm for calculating exchange hash, etc.
       HLEN     output length of HASH in bits
       MINKLEN  minimum transient RSA modulus length in bits

   Their values are defined in Section 5 and Section 6 for the two
   methods defined by this document.

   The method uses the following messages.

   First, the server sends:

       byte      SSH_MSG_KEXRSA_PUBKEY
       string    server public host key and certificates (K_S)
       string    K_T, transient RSA public key






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   The key K_T is encoded according to the "ssh-rsa" scheme described in
   Section 6.6 of [RFC4253].  Note that unlike an "ssh-rsa" host key,
   K_T is used only for encryption, and not for signature.  The modulus
   of K_T MUST be at least MINKLEN bits long.

   The client generates a random integer, K, in the range
   0 <= K < 2^(KLEN-2*HLEN-49), where KLEN is the length of the modulus
   of K_T, in bits.  The client then uses K_T to encrypt:

       mpint     K, the shared secret

   The encryption is performed according to the RSAES-OAEP scheme of
   [RFC3447], with a mask generation function of MGF1-with-HASH, a hash
   of HASH, and an empty label.  See Appendix A for a proof that the
   encoding of K is always short enough to be thus encrypted.  Having
   performed the encryption, the client sends:

       byte      SSH_MSG_KEXRSA_SECRET
       string    RSAES-OAEP-ENCRYPT(K_T, K)

   Note that the last stage of RSAES-OAEP-ENCRYPT is to encode an
   integer as an octet string using the I2OSP primitive of [RFC3447].
   This, combined with encoding the result as an SSH "string", gives a
   result that is similar, but not identical, to the SSH "mpint"
   encoding applied to that integer.  This is the same encoding as is
   used by "ssh-rsa" signatures in [RFC4253].

   The server decrypts K.  If a decryption error occurs, the server
   SHOULD send SSH_MESSAGE_DISCONNECT with a reason code of
   SSH_DISCONNECT_KEY_EXCHANGE_FAILED and MUST disconnect.  Otherwise,
   the server responds with:

       byte      SSH_MSG_KEXRSA_DONE
       string    signature of H with host key

   The hash H is computed as the HASH hash of the concatenation of the
   following:

       string    V_C, the client's identification string
                 (CR and LF excluded)
       string    V_S, the server's identification string
                 (CR and LF excluded)
       string    I_C, the payload of the client's SSH_MSG_KEXINIT
       string    I_S, the payload of the server's SSH_MSG_KEXINIT
       string    K_S, the host key
       string    K_T, the transient RSA key
       string    RSAES_OAEP_ENCRYPT(K_T, K), the encrypted secret
       mpint     K, the shared secret



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   This value is called the exchange hash, and it is used to
   authenticate the key exchange.  The exchange hash SHOULD be kept
   secret.

   The signature algorithm MUST be applied over H, not the original
   data.  Most signature algorithms include hashing and additional
   padding.  For example, "ssh-dss" specifies SHA-1 hashing.  In such
   cases, the data is first hashed with HASH to compute H, and H is then
   hashed again as part of the signing operation.

5.  rsa1024-sha1

   The "rsa1024-sha1" method specifies RSA key exchange as described
   above with the following parameters:

       HASH     SHA-1, as defined in [RFC3174]
       HLEN     160
       MINKLEN  1024

6.  rsa2048-sha256

   The "rsa2048-sha256" method specifies RSA key exchange as described
   above with the following parameters:

       HASH     SHA-256, as defined in [FIPS-180-2]
       HLEN     256
       MINKLEN  2048

7.  Message Numbers

   The following message numbers are defined:

       SSH_MSG_KEXRSA_PUBKEY  30
       SSH_MSG_KEXRSA_SECRET  31
       SSH_MSG_KEXRSA_DONE    32

8.  Security Considerations

   The security considerations in [RFC4251] apply.

   If the RSA private key generated by the server is revealed, then the
   session key is revealed.  The server should thus arrange to erase
   this from memory as soon as it is no longer required.  If the same
   RSA key is used for multiple SSH connections, an attacker who can
   find the private key (either by factorising the public key or by
   other means) will gain access to all of the sessions that used that
   key.  As a result, servers SHOULD use each RSA key for as few key
   exchanges as possible.



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   [RFC3447] recommends that RSA keys used with RSAES-OAEP not be used
   with other schemes, or with RSAES-OAEP using a different hash
   function.  In particular, this means that K_T should not be used as a
   host key, or as a server key in earlier versions of the SSH protocol.

   Like all key-exchange mechanisms, this one depends for its security
   on the randomness of the secrets generated by the client (the random
   number K) and the server (the transient RSA private key).  In
   particular, it is essential that the client use a high-quality
   cryptographic pseudo-random number generator to generate K.  Using a
   bad random number generator will allow an attacker to break all the
   encryption and integrity protection of the Secure Shell transport
   layer.  See [RFC4086] for recommendations on random number
   generation.

   The size of transient key used should be sufficient to protect the
   encryption and integrity keys generated by the key-exchange method.
   For recommendations on this, see [RFC3766].  The strength of
   RSAES-OAEP is in part dependent on the hash function it uses.
   [RFC3447] suggests using a hash with an output length of twice the
   security level required, so SHA-1 is appropriate for applications
   requiring up to 80 bits of security, and SHA-256 for those requiring
   up to 128 bits.

   Unlike the Diffie-Hellman key-exchange method defined by [RFC4253],
   this method allows the client to fully determine the shared secret,
   K.  This is believed not to be significant, since K is only ever used
   when hashed with data provided in part by the server (usually in the
   form of the exchange hash, H).  If an extension to SSH were to use K
   directly and to assume that it had been generated by Diffie-Hellman
   key exchange, this could produce a security weakness.  Protocol
   extensions using K directly should be viewed with extreme suspicion.

   This key-exchange method is designed to be resistant to collision
   attacks on the exchange hash, by ensuring that neither side is able
   to freely choose its input to the hash after seeing all of the other
   side's input.  The server's last input is in SSH_MSG_KEXRSA_PUBKEY,
   before it has seen the client's choice of K.  The client's last input
   is K and its RSA encryption, and the one-way nature of RSA encryption
   should ensure that the client cannot choose K so as to cause a
   collision.

9.  IANA Considerations

   IANA has assigned the names "rsa1024-sha1" and "rsa2048-sha256" as
   Key Exchange Method Names in accordance with [RFC4250].





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10.  Acknowledgements

   The author acknowledges the assistance of Simon Tatham with the
   design of this key exchange method.

   The text of this document is derived in part from [RFC4253].

11.  References

11.1.  Normative References

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

   [RFC3174]     Eastlake, D. and P. Jones, "US Secure Hash Algorithm 1
                 (SHA1)", RFC 3174, September 2001.

   [RFC3447]     Jonsson, J. and B. Kaliski, "Public-Key Cryptography
                 Standards (PKCS) #1: RSA Cryptography Specifications
                 Version 2.1", RFC 3447, February 2003.

   [RFC4251]     Ylonen, T. and C. Lonvick, "The Secure Shell (SSH)
                 Protocol Architecture", RFC 4251, January 2006.

   [RFC4253]     Ylonen, T. and C. Lonvick, "The Secure Shell (SSH)
                 Transport Layer Protocol", RFC 4253, January 2006.

   [RFC4250]     Lehtinen, S. and C. Lonvick, "The Secure Shell (SSH)
                 Protocol Assigned Numbers", RFC 4250, January 2006.

   [FIPS-180-2]  National Institute of Standards and Technology (NIST),
                 "Secure Hash Standard (SHS)", FIPS PUB 180-2,
                 August 2002.

11.2.  Informative References

   [SSH1]        Ylonen, T., "SSH -- Secure Login Connections over the
                 Internet", 6th USENIX Security Symposium, pp. 37-42,
                 July 1996.

   [RFC3766]     Orman, H. and P. Hoffman, "Determining Strengths For
                 Public Keys Used For Exchanging Symmetric Keys",
                 BCP 86, RFC 3766, April 2004.

   [RFC4086]     Eastlake, D., Schiller, J., and S. Crocker, "Randomness
                 Requirements for Security", BCP 106, RFC 4086,
                 June 2005.




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Appendix A.  On the Size of K

   The requirements on the size of K are intended to ensure that it is
   always possible to encrypt it under K_T.  The mpint encoding of K
   requires a leading zero bit, padding to a whole number of bytes, and
   a four-byte length field, giving a maximum length in bytes,
   B = (KLEN-2*HLEN-49+1+7)/8 + 4 = (KLEN-2*HLEN-9)/8 (where "/" denotes
   integer division rounding down).

   The maximum length of message that can be encrypted using RSAEP-OAEP
   is defined by [RFC3447] in terms of the key length in bytes, which is
   (KLEN+7)/8.  The maximum length is thus L = (KLEN+7-2*HLEN-16)/8 =
   (KLEN-2*HLEN-9)/8.  Thus, the encoded version of K is always small
   enough to be encrypted under K_T.

Author's Address

   Ben Harris
   2a Eachard Road
   CAMBRIDGE
   CB4 1XA
   UNITED KINGDOM

   EMail: bjh21@bjh21.me.uk



























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