Network Working Group C. Newman
Internet Draft: SCRAM-MD5 SASL Mechanism Innosoft
Document: draft-newman-auth-scram-02.txt January 1998
Expires in six months
Salted Challenge Response Authentication Mechanism (SCRAM)
Status of this memo
This document is an Internet-Draft. Internet-Drafts are working
documents of the Internet Engineering Task Force (IETF), its areas,
and its working groups. Note that other groups may also distribute
working documents as Internet-Drafts.
Internet-Drafts are draft documents valid for a maximum of six
months and may be updated, replaced, or obsoleted by other
documents at any time. It is inappropriate to use Internet-Drafts
as reference material or to cite them other than as "work in
progress."
To view the entire list of current Internet-Drafts, please check
the "1id-abstracts.txt" listing contained in the Internet-Drafts
Shadow Directories on ftp.is.co.za (Africa), ftp.nordu.net
(Europe), munnari.oz.au (Pacific Rim), ds.internic.net (US East
Coast), or ftp.isi.edu (US West Coast).
Abstract
SCRAM is a simple passphrase-based SASL [SASL] authentication
mechanism suitable for a wide variety of usage scenarios. It
combines good properties of CRAM-MD5 [CRAM-MD5] and OTP [OTP], adds
some management features and protection from active attacks without
a significant increase in complexity. SCRAM is intended for use
with services which need a simple, fast and flexible authentication
mechanism.
[NOTE: Public discussion of this mechanism may take place on the
ietf-sasl@imc.org mailing list with a subscription address of
ietf-sasl-request@imc.org. Private comments may be sent to the
author].
1. How to Read This Document
This document has information for several different audiences.
Newman [Page 1]
Internet Draft SCRAM-MD5 SASL Mechanism January 1998
Section 2 provides an introduction to SCRAM. Sections 3-6 and 9
are intended for implementors. Section 7 is intended for system
administrators. Sections 7-10 are intended for security
evaluation.
The key words "MUST", "MUST NOT", "SHOULD", "SHOULD NOT" and "MAY"
in this document are to be interpreted as defined in "Key words for
use in RFCs to Indicate Requirement Levels" [KEYWORDS].
2. Introduction
This section describes the design goals, an overview of how SCRAM
operates and the intended use of SCRAM in comparison to OTP.
2.1. Design Goals
The perfect authentication mechanism would be simple, fast, strong,
use publicly available source code and be backwards compatible with
deployed back-end authentication databases. It is impossible to
achieve all these goals so tradeoffs must be made. SCRAM has
simplicity, speed and protection from passive and active attacks on
the underlying connection (with the exception of dictionary
attacks) as primary design goals. It has managability, backwards
compatibility with CRAM-MD5 intermediate HMAC state verifiers, some
protection from a compromised authentication database and publicly
distributable source code as secondary design goals.
SCRAM has the following characteristics:
o It is a simple passphrase-based mechanism which does not require
complicated infrastructures or public key technology. The
majority of the source code necessary to implement SCRAM is
included in the MD5 specification [MD5] and Appendices B and C
of this specification.
o It does not require plain-text-equivalent verifiers on the
server, so it improves network security over traditional
plain-text password systems without eliminating security of the
server authentication database.
o It supports proxy authentication by including an authorization
identity (user to login as) separate from the authentication
identity (server authentication database entry to use).
o It supports mutual authentication.
Newman [Page 2]
Internet Draft SCRAM-MD5 SASL Mechanism January 1998
o It supports a limited service trust management model. This
means a centralized authentication server could restrict the
services offered by application servers.
o It is backwards-compatible with CRAM-MD5 server authentication
databases.
o It includes an optional SASL integrity protection layer for
lightweight protection from active attacks.
2.2. Basic Operation of SCRAM
SCRAM is built using only a simple one-way hash function, the HMAC
[HMAC] construction and the exclusive-or operation. There are
three fundamental components to the exchange: the client key which
is derived from the passphrase and salt, the client verifier which
is simply the one-way hash function applied to the client key, and
the server key which is also derived from the passphrase and salt.
The server has access to the salt, client verifier and server key
for each user.
SCRAM uses HMAC to sign client and server nonces with the client
verifier to produce a shared key. The client exclusive-ors the
shared key with the client key and sends that to the server which
can reverse the exclusive-or operation and verify that the hash
function applied to the client key is equal to the client verifier.
The server uses HMAC to sign the client and server nonces with the
server key and sends that to the client to authenticate.
The mechanism relies on the one-way characteristic of the hash
function to assure that the client key can't be derived from the
client verifier and that the server key can't be derived from
either the client key or client verifier.
2.3. Intended Use
SCRAM is designed for a usage scenario where simplicity and/or
speed is important, frequent authentications may occur and the
primary threat is passive and active network attacks. A good
example of protocols whose usage and threat model fit SCRAM are
IMAP [IMAP4] and POP3 [POP3]. SCRAM provides limited protection
against threats to the server authentication database, but OTP
[OTP] may be preferable for usage scenarios where the threat to the
server is more serious and active attacks are not an issue.
Newman [Page 3]
Internet Draft SCRAM-MD5 SASL Mechanism January 1998
3. Client Implementation of SCRAM-MD5
This section includes a step-by-step guide for client implementors.
Section 6 contains the formal definition of the syntax and is the
authoritative reference in case of errors here.
When used with SASL the mechanism name is "SCRAM-MD5". The
mechanism does not provide a privacy layer, but does include an
optional integrity protection layer.
The client begins by sending a message to the server containing the
following three pieces of information.
(1) An authorization identity. When the empty string is used, this
defaults to the authentication identity. This is used by system
administrators or proxy servers to login with a different user
identity. This field may be up to 255 octets and is terminated by
a NUL (0) octet. US-ASCII printable characters are preferred,
although UTF-8 [UTF-8] printable characters are permitted to
support international names. Use of character sets other than
US-ASCII and UTF-8 is forbidden.
(2) An authentication identity. The identity whose passphrase will
be used. This field may be up to 255 octets and is terminated by a
NUL (0) octet. US-ASCII printable characters are preferred,
although UTF-8 [UTF-8] printable characters are permitted to
support international names. Use of character sets other than
US-ASCII and UTF-8 is forbidden.
(3) A "client nonce." It is important that this be globally
unique. One common technique for generating globally unique
identifiers combines a process identifier with the system clock, a
sequence number, a random number and the client's domain name. The
random number is important as clocks are often synchronized using
insecure protocols and are predictable. Advice for generating good
random numbers can be found in [RANDOM].
The server responds by sending a message containing three pieces of
information:
(4) An 8-octet salt value, specific to the authentication identity.
(5) A one-octet bit-mask specifying security layers supported by
the server. Bit 0 (value 1) indicates support for no security
layer and bit 1 (value 2) indicates support for an integrity
protection layer. The other bits are reserved for future use (the
server MUST set them to zero until they are defined in a standards
track specification). If the client doesn't support a security
Newman [Page 4]
Internet Draft SCRAM-MD5 SASL Mechanism January 1998
layer and bit 0 is cleared, then the authentication immediately
fails.
(6) A three-octet number in network byte order (big endian),
containing the maximum cipher-text buffer size the server is able
to receive. This may be 0 if the server supports no security
layers.
(7) A service id consisting of the service name of the protocol's
SASL profile followed by an "@" followed by the domain name of the
server and terminated by NUL. The client SHOULD verify this is
correct.
(8) A "server nonce". As the domain name is included in (7), this
only has to be unique to the server.
The client then does the following:
(A) Create a buffer containing the user's passphrase. The client
MUST support passphrases of at least 64 octets. US-ASCII
characters are preferred, although UTF-8 characters are permitted.
Character sets other than US-ASCII and UTF-8 MUST NOT be used.
(B) Apply the HMAC-MD5 function with (A) as the key and the 8-octet
salt as the data, producing a 16-octet result. Once this is done,
(A) SHOULD be erased from memory.
(C) Apply the MD5 function to the result of (B). This produces a
16-octet result.
(D) Apply the MD5 function to the result of (C). This produces a
16-octet result.
(E) Create a buffer containing the server's response (4)-(8),
immediately followed by the initial client message (1)-(3) and the
client's security layer selection (9)-(10) below.
(F) Apply the HMAC-MD5 function with the result of (D) as the key
and the buffer from (E) as the data. This produces a 16-octet
result.
(G) Create a 16-octet buffer containing the exclusive-or of (C) and
(F).
The client then sends a message to the server containing the
following:
(9) A bit-mask indicating the client selected security layer from
Newman [Page 5]
Internet Draft SCRAM-MD5 SASL Mechanism January 1998
step (5). This has a value of 01 for no security layer and 02 for
an integrity protection layer.
(10) A three octet number indicating the maximum cipher-text buffer
size the client is able to receive in network byte order. If the
client doesn't select a security layer, this may be all zeros.
(11) The 16-octet result of step (G).
The server will respond with:
(12) A 16-octet server authentication verifier.
The client SHOULD verify this with the following procedure:
(H) Apply the HMAC-MD5 function with the result of (B) as the key
and the 8-octet salt as the data. This produces a 16-octet result.
(I) Create a buffer containing the initial client message (1)-(3)
immediately followed by the initial server response (4)-(8) and the
client's security layer selection (9)-(10).
(J) Apply the HMAC-MD5 function with the result of (H) as the key
and the buffer from (I) as the data.
(K) If the result of (J) matches (12), the server is authenticated.
A secured client MAY store the result of (B) to re-authenticate to
services using the same salt, or the intermediate HMAC state from
(B) to re-authenticate to any service. Clients SHOULD NOT store
the passphrase itself.
If integrity protection is negotiated on, the following procedure
is applied to each SASL security layer packet sent by the client:
(L) Apply the HMAC-MD5 function with the output of step (C) as the
key and the buffer from step (E) as the value.
(M) A buffer is created containing a four octet client packet
number in network byte order followed by the 16-octet output of
step (L). The first packet sent under the SASL security layer is
given number 1.
(N) Apply the HMAC-MD5 function with (M) as the key and the
contents of the packet as the data. The result is appended to the
end of the packet.
The integrity protection on packets from the server is verified as
Newman [Page 6]
Internet Draft SCRAM-MD5 SASL Mechanism January 1998
follows:
(O) A buffer is created containing a four octet server packet
number in network byte order followed by the 16-octet output of
step (L) above. This first packet sent under the SASL security
layer is given number 1.
(P) Apply the HMAC-MD5 function with (O) as the key and all but the
last 16 octets of the packet as the value.
(Q) Compare the last 16 octets of the packet to the output of (P).
If they do not match, an integrity error is produced.
4. Server Implementation of SCRAM-MD5
The section includes a step-by-step guide for server implementors
building on the previous section. Section 6 contains the formal
definition of the syntax and is the authoritative reference in case
of errors here.
The server's authentication database contains an 8-octet salt,
16-octet client verifier and a 16-octet server key for each local
user. The server MUST support "user@host" syntax for the
authentication identity at least to the extent of stripping "@host"
when it matches the local hostname or rejecting the authentication
if the hostname doesn't match. The server MAY support remote user
authentication using this syntax.
The stored client verifier is equal to the result of step (D)
above, and the stored server key is equal to the result of step (J)
above. To create its initial response, the server simply looks up
the authentication identity to fetch the salt, and generates an 8
to 248 octet nonce. This nonce MUST be unique for the server to
prevent replay attacks. It can be generated by appending a system
clock to a process and/or thread identifier and a random number
[RANDOM]. To verify the client's credentials, the server performs
the following steps:
(a) Generate a buffer identical to step (E) above.
(b) Apply the HMAC-MD5 function with the stored client verifier as
the key and the result of (a) as the data. This produces a
16-octet result equal to step (F) above.
(c) Exclusive-or the result of (b) with message (11) from the
client. This produces a 16-octet result which should be equal to
the result of step (C) above.
Newman [Page 7]
Internet Draft SCRAM-MD5 SASL Mechanism January 1998
(d) Apply the MD5 function to the output of step (c). This
produces a 16-octet result which should be equal to the result of
step (D) above.
(e) if the result of (d) is equal to the stored verifier, then the
user is authenticated.
If no client challenge was provided in step (3), the server is now
done and responds with the appropriate status code. Otherwise the
server continues as follows:
(f) Generate a buffer identical to step (I) above.
(g) Apply the HMAC-MD5 function with the stored server verifier as
the key and the buffer from (f) as the data. This produces a
16-octet result.
The result of (g) is sent to the client to authenticate the server.
If integrity protection is negotiated on, the integrity key is
computed as follows:
(h) Apply the HMAC-MD5 function with the output of step (c) as the
key and the buffer from step (a) as the data.
Integrity generation and verification works in the same fashion as
the client.
5. Example
In these examples, "C:" represents lines sent from the client to
the server and "S:" represents lines sent from the server to the
client. The wrapped lines are for editorial clarity -- there are
no actual newlines in the middle of the messages.
The following is an example of the SCRAM-MD5 mechanism using the
IMAP [IMAP4] profile of SASL. For this example, the user "chris",
with an empty authorization identity is using the passphrase
"secret stuff". The client nonce is
"<t4n4Pab9HB0Am/QLXB72eg@eleanor.innosoft.com>" and the server
nonce is "jhcNZlRuPbziFp+vLV+NCw". No security layer is supported,
the salt is "testsalt" and the service identity is
"imap@eleanor.innosoft.com". The complete 40 octet verifier stored
on the server, in hexidecimal is "74657374 73616c74 16484d56
7ee02f47 ac5f8a5a d5795570 90d55334 d2002df6 24cb8c8b 75708f4e."
Newman [Page 8]
Internet Draft SCRAM-MD5 SASL Mechanism January 1998
C: a001 AUTHENTICATE SCRAM-MD5
S: +
C: AGNocmlzADx0NG40UGFiOUhCMEFtL1FMWEI3MmVnQGVsZWFub3IuaW
5ub3NvZnQuY29tPg==
S: + dGVzdHNhbHQBAAAAaW1hcEBlbGVhbm9yLmlubm9zb2Z0LmNvbQBq
aGNOWmxSdVBiemlGcCt2TFYrTkN3
C: AQAAAMg9jU8CeB4KOfk7sUhSQPs=
S: + U0odqYw3B7XIIW0oSz65OQ==
C:
S: a001 OK AUTHENTICATE completed
Note that base64 encoding and the lack of an initial client
response with the first command are characteristics of the IMAP
profile of SASL and not characteristics of SASL or SCRAM-MD5. Here
is another example using the ACAP [ACAP] profile of SASL. This
uses the same salt, passphrase and verifier as the previous
example. In this example, binary data is represented as
hexidecimal digits enclosed in square brackets:
C: a001 AUTHENTICATE "SCRAM-MD5" {52}
C: [00]chris[00]<HSMDKNj0yFGa8f5swzqznw@eleanor.innosoft.com>
S: + {60}
S: testsalt[01000000]acap@eleanor.innosoft.com[00]
m6HdEYWZA5W8keNbiY40aA
C: {20}
C: [01000000 19b66406 4ce8138a e0af7b0b f0ed20ea]
S: a001 OK (SASL {16}
S: [44d7c1c4 0630fea6 5c49cb40 717a2ba5]) "Successful"
Note that arbitrary binary values may be used for the salt and
nonces, as long as the client nonce is globally unique.
6. Formal Syntax of SCRAM-MD5 Messages
This is the formal syntactic definition of the client and server
messages. This uses ABNF [ABNF] notation including the core rules.
client-msg-1 = [authorize-id] NUL authenticate-id NUL nonce
server-msg-1 = salt security-info service-id NUL nonce
client-msg-2 = security-info client-proof
server-msg-2 = server-proof
passphrase = *UTF8-SAFE
;; At least 64 octets MUST be supported
Newman [Page 9]
Internet Draft SCRAM-MD5 SASL Mechanism January 1998
authorize-id = *UTF8-PRINT
;; No more than 255 octets
authenticate-id = *UTF8-PRINT
;; No more than 255 octets
security-info = secbits bufsize
bufsize = 3OCTET
;; in network byte order (big-endian)
secbits = OCTET
;; bit 0 = no protection, bit 1 = integrity,
;; other bits set to 0 and reserved
service-id = service-name "@" server-domain
service-name = *VCHAR
;; a SASL/GSSAPI service name
server-domain = *VCHAR
;; an internet domain name
nonce = 8*OCTET
salt = 8OCTET
client-proof = 16OCTET
server-proof = 16OCTET
NUL = %x00 ;; US-ASCII NUL character
UTF8-SAFE = %x01-09 / %x0B-0C / %x0E-7F / UTF8-MULTI
;; Any character except CR, LF, NUL
UTF8-PRINT = %x20-7E / UTF8-MULTI
;; Any character except CTLs
UTF8-MULTI = UTF8-2 / UTF8-3 / UTF8-4 / UTF8-5 / UTF8-6
;; UTF-8 Multi-octet characters
UTF8-1 = %x80-BF
UTF8-2 = %xC0-DF UTF8-1
UTF8-3 = %xE0-EF 2UTF8-1
Newman [Page 10]
Internet Draft SCRAM-MD5 SASL Mechanism January 1998
UTF8-4 = %xF0-F7 3UTF8-1
UTF8-5 = %xF8-FB 4UTF8-1
UTF8-6 = %xFC-FD 5UTF8-1
7. System Administrator Advice
This section includes advice for system administrators using this
mechanism.
A SCRAM server stores three pieces of information for each user: a
salt, a client verifier and server key. The latter two are derived
from the salt and the user's passphrase.
The salt prevents global dictionary attacks, similar to the salt
used in Unix /etc/passwd files. As the 12 bits of salt in Unix
/etc/passwd has proved to be insufficient, SCRAM uses 64 bits of
salt. See [SCHNEIER] for a good discussion of salt and dictionary
attacks. In a multi-server site, security can be increased by
using a different salt on each server.
Although the verifiers used by SCRAM-MD5 have roughly comparable
security to those used by current plain-text mechanisms (such as
Unix /etc/passwd), it is still very important to keep them secret.
Just as tools exist to try common passwords against Unix
/etc/passwd files, it is also possible to build such tools for
SCRAM-MD5. In addition, once a SCRAM-MD5 verifier is stolen, a
passive (undetectable) eavesdropper of that user logging in gains
the output of step (C) above, which is sufficient to impersonate
the user to all services with the same salt. This is better than
current plain-text mechanisms where a passive eavesdropper always
recovers the user's password, but is still a serious concern.
Verifiers SHOULD be kept hidden from all users on the server.
Sites which distribute verifiers among multiple servers, SHOULD
encrypt them when transferring them over the network.
SCRAM-MD5 is only a good mechanism if passphrases are well chosen.
For this reason, implementations should use the term "passphrase"
rather than "password" and when a user's passphrase is set, site
policy restrictions should be applied. A reasonably secure site
policy would require passphrases of at least 10 characters with at
least one non-alphanumeric character.
SCRAM-MD5 doesn't protect the privacy of data exchanged after
authentication. Use of TLS [TLS] or a stronger SASL mechanism such
Newman [Page 11]
Internet Draft SCRAM-MD5 SASL Mechanism January 1998
as Kerberos is encouraged if this functionality is needed.
8. SCRAM Functional Notation
This section is designed to provide a quick understanding of SCRAM
for those who like functional notation.
+ octet concatenation
XOR the exclusive-or function
AU is the authentication user identity (NUL terminated)
AZ is the authorization user identity (NUL terminated)
if AZ is the same as AU, a single NUL is used instead.
csecinfo client security layer option bits and buffer size
ssecinfo server security layer option bits and buffer size
service is the name of the service and server (NUL terminated)
pass is the plain-text passphrase
H(x) is a one-way hash function applied to "x", such as MD5
MAC(x,y) is a message authentication code (MAC) such as HMAC-MD5
"y" is the key and "x" is the text signed by the key.
salt is a per-user salt value the server stores
Us is a unique nonce the server sends to the client
Uc is a unique nonce the client sends to the server
The SCRAM computations and exchange are as follows:
client-msg-1 = AZ + AU + Uc
(1) client -> server: client-msg-1
server-msg-1 = salt + ssecinfo + service + Us
(2) server -> client: server-msg-1
salted-pass = MAC(salt, pass)
client-key = H(salted-pass)
client-verifier = H(client-key)
shared-key = MAC(server-msg-1 + client-msg-1 + csecinfo,
client-verifier)
client-proof = client-key XOR shared-key
(3) client -> server: client-proof + secinfo
server-key = MAC(salt, salted-pass)
server-proof = MAC(client-msg-1 + server-msg-1 + csecinfo,
server-key)
(4) server -> client: server-proof
integrity-key = MAC(server-msg-1 + client-msg-1 + csecinfo,
client-key)
The server stores the salt, client-verifier and server-key. It
authenticates the client by computing:
H(client-proof XOR shared-key)
Newman [Page 12]
Internet Draft SCRAM-MD5 SASL Mechanism January 1998
after step 3 and comparing it to the stored client-verifier. The
server computes the integrity-key with:
MAC(server-msg-1 + client-msg-1, client-proof XOR shared-key)
The client verifies the server by computing the server-proof
directly and comparing.
9. Security Considerations
Security considerations are discussed throughout this document.
The security considerations of MD5 [MD5] and HMAC [HMAC] also
apply. SCRAM relies primarily on the one-way characteristic of MD5
and HMAC-MD5 for security. The weaknesses found in MD5 are not
believed to impact this use. In the interest of avoiding
proliferation of authentication mechanisms, it is hoped that it
will be easy to deploy public-key technology before a hash function
upgrade becomes necessary.
SCRAM does use the output of an HMAC function and exclusive-or to
construct a simple 16-octet encryption function. While
constructing an encryption function from a hash function is
normally a questionable practice [SCHNEIER], in this case both the
key and the data are outputs of a one-way hash function with a good
bit-distribution and the key is used only once (as long as the
combined nonces are unique).
An analysis of different attacks follows:
Passive Network Attacks
SCRAM is resistant to replay attacks as long as the appropriate
nonce is unique.
SCRAM is not resistant to passive dictionary attacks. User
education, passphrase setting policy and TLS [TLS] can be used to
protect against such attacks.
SCRAM does not protect against session data eavesdropping. TLS
[TLS] can be used to protect against this.
Active Network Attacks
If the client fails to verify the server proof, then SCRAM provides
no protection from active attacks.
SCRAM protects against server impersonation with the server mutual
Newman [Page 13]
Internet Draft SCRAM-MD5 SASL Mechanism January 1998
authentication.
An attacker could use SCRAM to probe for users by trying each user
name twice to see if the salt varies. The server can prevent this
attack by inventing consistent salt values for non-users. One way
to do this would be to store a random secret and generate the salt
using HMAC(user-name, random-secret).
SASL is susceptible to downgrade active attacks which reduce the
advertised authentication mechanisms to the weakest the server
offers. If SCRAM is the weakest mechanism, such attacks can be
detected if integrity protection is negotiated on and the client
requests a duplicate copy of the server's capability list after
authentication (e.g., by re-issuing the CAPABILITY command in
IMAP). For a protocol such as ACAP [ACAP], the server SHOULD
repeat the greeting line immediately after authentication is
completed whenever integrity protection is negotiated on.
SCRAM can protect against connection tampering only if integrity
protection is negotiated on. TLS [TLS] or IPAUTH [IPAUTH] may also
be used to protect against such tampering. If TLS or IPAUTH is
active, then the SCRAM integrity layer is unnecessary and SHOULD be
negotiated off.
SCRAM does not protect against most active denial of service
attacks, although it is less susceptible to such attacks than OTP
[OTP].
Server Attacks
A server implementation which does not tolerate input of any length
with any content may be susceptible to attacks which permit
privileged access to the server. For this reason server
implementations MUST be able to accept input of any length with any
content although server implementations MAY refuse to authenticate
the client if messages exceed the specified maximum lengths.
An attacker which has access to both the SCRAM verifier and a
client exchange for a particular user gains the ability to
impersonate that user to other servers using the same salt. TLS
[TLS] can make it more difficult to obtain the client exchange, but
can not defend against installation of a trojan horse on a
compromised server.
In the process of authentication, the server gains access to the
client-key which is sufficient to impersonate the user to other
services with the same salt.
Newman [Page 14]
Internet Draft SCRAM-MD5 SASL Mechanism January 1998
Client Attacks
As SCRAM is designed for user entry of a plain-text passphrase, it
is vulnerable to passphrase hijacking by trojan horse clients. OTP
[OTP] with an external portable OTP calculator can limit the
vulnerability to a single session.
10. Intellectual Property Issues and Prior Art
The author is not aware of any patents or pending patents which
apply to this mechanism.
This is primarily a derivative of simple hash-based challenge
response systems. The hash-based challenge response idea has
existed since at least 1992, when the RIPE project published the
SKID algorithm according to [SCHNEIER].
The repeated-hash idea used to verify the client's authenticator is
derived from S/KEY [SKEY].
The idea of using salt to protect against global dictionary attacks
dates back to at least the Unix /etc/passwd system. There is some
discussion of this in [SCHNEIER].
SCRAM combines these techniques. The author of this specification
first proposed this idea on a public mailing list on July 16, 1997.
11. Multinational Considerations
As remote access is a crucial service, users are encouraged to
restrict user names and passphrases to the US-ASCII character set.
However, if characters outside the US-ASCII chracter set are used
in user names and passphrases, then they are interpreted according
to UTF-8 [UTF-8] and it is a protocol error to include any octet
sequences not legal for UTF-8. Servers are encourged to enforce
this restriction to discourage clients which use unlabelled
character sets in this context.
12. References
[ABNF] Crocker, Overell, "Augmented BNF for Syntax Specifications:
ABNF", RFC 2234, Internet Mail Consortium, Demon Internet Ltd,
November 1997.
<ftp://ds.internic.net/rfc/rfc2234.txt>
Newman [Page 15]
Internet Draft SCRAM-MD5 SASL Mechanism January 1998
[ACAP] Newman, Myers, "ACAP -- Application Configuration Access
Protocol", RFC 2244, Innosoft, Netscape, November 1997.
<ftp://ds.internic.net/rfc/rfc2244.txt>
[CRAM-MD5] Klensin, Catoe, Krumviede, "IMAP/POP AUTHorize Extension
for Simple Challenge/Response", RFC 2195, MCI, September 1997.
<ftp://ds.internic.net/rfc/rfc2195.txt>
[HMAC] Krawczyk, Bellare, Canetti, "HMAC: Keyed-Hashing for Message
Authentication", RFC 2104, IBM, UCSD, February 1997.
<ftp://ds.internic.net/rfc/rfc2104.txt>
[IMAP4] Crispin, M., "Internet Message Access Protocol - Version
4rev1", RFC 2060, University of Washington, December 1996.
<ftp://ds.internic.net/rfc/rfc2060.txt>
[IPAUTH] Atkinson, "IP Authentication Header", RFC 1826, Naval
Research Laboratory, August 1995.
<ftp://ds.internic.net/rfc/rfc1826.txt>
[KEYWORDS] Bradner, "Key words for use in RFCs to Indicate
Requirement Levels", RFC 2119, Harvard University, March 1997.
<ftp://ds.internic.net/rfc/rfc2119.txt>
[MD5] Rivest, "The MD5 Message Digest Algorithm", RFC 1321, MIT
Laboratory for Computer Science, April 1992.
<ftp://ds.internic.net/rfc/rfc1321.txt>
[OTP] Haller, Metz, "A One-Time Password System", RFC 1938,
Bellcore, Kaman Sciences Corporation, May 1996.
<ftp://ds.internic.net/rfc/rfc1938.txt>
[OTP-EXT] Metz, "OTP Extended Responses", RFC 2243, The Inner Net,
November 1997.
<ftp://ds.internic.net/rfc/rfc2243.txt>
Newman [Page 16]
Internet Draft SCRAM-MD5 SASL Mechanism January 1998
[POP3] Myers, J., Rose, M., "Post Office Protocol - Version 3", RFC
1939, Carnegie Mellon, Dover Beach Consulting, Inc., May 1996.
<ftp://ds.internic.net/rfc/rfc1939.txt>
[RANDOM] Eastlake, Crocker, Schiller, "Randomness Recommendations
for Security", RFC 1750, DEC, Cybercash, MIT, December 1994.
<ftp://ds.internic.net/rfc/rfc1750.txt>
[SASL] Myers, "Simple Authentication and Security Layer (SASL)",
RFC 2222, Netscape Communications, October 1997.
<ftp://ds.internic.net/rfc/rfc2222.txt>
[SCHNEIER] Schneier, "Applied Cryptography: Protocols, Algorithms
and Source Code in C," John Wiley and Sons, Inc., 1996.
[SKEY] Haller, Neil M. "The S/Key One-Time Password System", RFC
1760, Bellcore, February 1995.
<ftp://ds.internic.net/rfc/rfc1760.txt>
[TLS] Dierks, Allen, "The TLS Protocol Version 1.0", Work in
progress.
[UTF8] Yergeau, F. "UTF-8, a transformation format of Unicode and
ISO 10646", RFC 2044, Alis Technologies, October 1996.
<ftp://ds.internic.net/rfc/rfc2044.txt>
13. Author's Address
Chris Newman
Innosoft International, Inc.
1050 Lakes Drive
West Covina, CA 91790 USA
Email: chris.newman@innosoft.com
A. Appendix - Additional Services
Several additional services are needed to make SCRAM useful in more
usage scenarios. These include remote authentication database
support for servers, authentication database APIs for servers,
remote passphrase change support for clients, single-sign-on APIs
Newman [Page 17]
Internet Draft SCRAM-MD5 SASL Mechanism January 1998
for clients and management tools. The service-id and server-key
are included to facilitate the remote authentication database
service. Otherwise these issues are deferred for future work.
B. Appendix - HMAC-MD5 Sample Source Code
The following sample C source code calls the source code in the MD5
specification [MD5] and is derived from the source code in [HMAC].
It is needed by the SCRAM source code in the next section.
The client may call hmac_md5_precalc() to save the intermediate
HMAC result for later use in hmac_md5_import(). This can be used
by a CRAM-MD5 [CRAM-MD5] or a SCRAM-MD5 [SCRAM-MD5] client to save
an intermediate result suitable for use with any server without
saving the plain-text passphrase.
/* hmac-md5.h -- HMAC_MD5 functions
*/
#define HMAC_MD5_SIZE 16
/* intermediate MD5 context */
typedef struct HMAC_MD5_CTX_s {
MD5_CTX ictx, octx;
} HMAC_MD5_CTX;
/* intermediate HMAC state
* values stored in network byte order (Big Endian)
*/
typedef struct HMAC_MD5_STATE_s {
UINT4 istate[4];
UINT4 ostate[4];
} HMAC_MD5_STATE;
/* One step hmac computation
*
* digest may be same as text or key
*/
void hmac_md5(const unsigned char *text, int text_len,
const unsigned char *key, int key_len,
unsigned char digest[HMAC_MD5_SIZE]);
/* create context from key
*/
void hmac_md5_init(HMAC_MD5_CTX *hmac,
const unsigned char *key, int key_len);
/* precalculate intermediate state from key
*/
Newman [Page 18]
Internet Draft SCRAM-MD5 SASL Mechanism January 1998
void hmac_md5_precalc(HMAC_MD5_STATE *hmac,
const unsigned char *key, int key_len);
/* initialize context from intermediate state
*/
void hmac_md5_import(HMAC_MD5_CTX *hmac, HMAC_MD5_STATE *state);
#define hmac_md5_update(hmac, text, text_len) \
MD5Update(&(hmac)->ictx, (text), (text_len))
/* finish hmac from intermediate result.
* Intermediate result is erased.
*/
void hmac_md5_final(unsigned char digest[HMAC_MD5_SIZE],
HMAC_MD5_CTX *hmac);
/* hmac-md5.c -- HMAC MD5 Keyed-Hashing by Chris Newman
* derived from RFC 2104 by H. Krawczyk, M. Bellare, R.Canetti
*/
#include <stdio.h>
#include <string.h>
#include "md5.h"
#include "hmac-md5.h"
/* for htonl() and ntohl() */
#include <sys/types.h>
#include <netinet/in.h>
/* MD5 block size */
#define BLOCK_SIZE 64
void hmac_md5_init(HMAC_MD5_CTX *hmac,
const unsigned char *key, int key_len)
{
unsigned char k_pad[BLOCK_SIZE]; /* padded key */
int i;
/* if key longer than BLOCK_SIZE bytes reset to MD5(key) */
if (key_len > BLOCK_SIZE) {
MD5Init(&hmac->ictx);
MD5Update(&hmac->ictx, key, key_len);
MD5Final(k_pad, &hmac->ictx);
key = k_pad;
key_len = HMAC_MD5_SIZE;
}
/* XOR padded key with inner pad value */
Newman [Page 19]
Internet Draft SCRAM-MD5 SASL Mechanism January 1998
for (i = 0; i < key_len; i++) {
k_pad[i] = key[i] ^ 0x36;
}
while (i < BLOCK_SIZE) {
k_pad[i++] = 0x36;
}
/* Begin inner MD5 */
MD5Init(&hmac->ictx);
MD5Update(&hmac->ictx, k_pad, BLOCK_SIZE);
/* XOR padded key with outer pad value */
for (i = 0; i < BLOCK_SIZE; ++i) {
k_pad[i] ^= (0x36 ^ 0x5c);
}
/* Begin outer MD5 */
MD5Init(&hmac->octx);
MD5Update(&hmac->octx, k_pad, BLOCK_SIZE);
/* clean up workspace */
memset(k_pad, 0, BLOCK_SIZE);
}
void hmac_md5_final(unsigned char digest[HMAC_MD5_SIZE],
HMAC_MD5_CTX *hmac)
{
/* finish inner MD5 */
MD5Final(digest, &hmac->ictx);
/* finish outer MD5 */
MD5Update(&hmac->octx, digest, HMAC_MD5_SIZE);
MD5Final(digest, &hmac->octx);
/* MD5Final zeros context */
}
void hmac_md5(const unsigned char *text, int text_len,
const unsigned char *key, int key_len,
unsigned char digest[HMAC_MD5_SIZE])
{
HMAC_MD5_CTX hmac;
hmac_md5_init(&hmac, key, key_len);
hmac_md5_update(&hmac, text, text_len);
hmac_md5_final(digest, &hmac);
}
void hmac_md5_precalc(HMAC_MD5_STATE *ctx,
const unsigned char *pass, int passlen)
Newman [Page 20]
Internet Draft SCRAM-MD5 SASL Mechanism January 1998
{
HMAC_MD5_CTX hctx;
if (passlen == 0) passlen = strlen((const char *) pass);
hmac_md5_init(&hctx, pass, passlen);
ctx->istate[0] = htonl(hctx.ictx.state[0]);
ctx->istate[1] = htonl(hctx.ictx.state[1]);
ctx->istate[2] = htonl(hctx.ictx.state[2]);
ctx->istate[3] = htonl(hctx.ictx.state[3]);
ctx->ostate[0] = htonl(hctx.octx.state[0]);
ctx->ostate[1] = htonl(hctx.octx.state[1]);
ctx->ostate[2] = htonl(hctx.octx.state[2]);
ctx->ostate[3] = htonl(hctx.octx.state[3]);
memset(&hctx, 0, sizeof (hctx));
}
void hmac_md5_import(HMAC_MD5_CTX *hctx, HMAC_MD5_STATE *ctx)
{
hctx->ictx.state[0] = ntohl(ctx->istate[0]);
hctx->ictx.state[1] = ntohl(ctx->istate[1]);
hctx->ictx.state[2] = ntohl(ctx->istate[2]);
hctx->ictx.state[3] = ntohl(ctx->istate[3]);
hctx->octx.state[0] = ntohl(ctx->ostate[0]);
hctx->octx.state[1] = ntohl(ctx->ostate[1]);
hctx->octx.state[2] = ntohl(ctx->ostate[2]);
hctx->octx.state[3] = ntohl(ctx->ostate[3]);
hctx->ictx.count[0] = hctx->octx.count[0] = BLOCK_SIZE << 3;
hctx->ictx.count[1] = hctx->octx.count[1] = 0;
}
C. Appendix - SCRAM sample source code
The following sample source code implements SCRAM itself for both
server and client.
Please note the lines marked "XXX: ..." as they need to be
translated from English to computer readable code.
A client implementation simply calls scram_md5_generate() with the
passphrase after receiving the first server reply. The cproof
parameter will hold the message to send to the server and the
sproof parameter will hold the expected server mutual
authentication. The clidata parameter holds the client's security
layer selections. A client may also call hmac_md5_precalc() to
turn a passphrase into CRAM/SCRAM credentials for later use in
scram_md5_generate().
Newman [Page 21]
Internet Draft SCRAM-MD5 SASL Mechanism January 1998
A server implementation simply calls scram_md5_generate() with the
stored verifier, the second client message and the SCRAM_VERIFY
option. Server verifiers are generated by creating a random salt
and calling scram_md5_vgen() with either the passphrase or
CRAM/SCRAM credentials.
If integrity protection is desired, the integrity_key parameter may
be provided to scram_md5_generate() and will receive the resulting
key. Generating an verifying the integrity protection is left as
an exercise to the reader.
/* scram.h -- scram utility functions
*/
/* size of SCRAM_MD5 salt and verifier */
#define SCRAM_MD5_SALTSIZE 8
#define SCRAM_MD5_DATASIZE 16
/* SCRAM verifier */
typedef struct SCRAM_MD5_VRFY_s {
unsigned char salt[SCRAM_MD5_SALTSIZE];
unsigned char clidata[SCRAM_MD5_DATASIZE];
unsigned char svrdata[SCRAM_MD5_DATASIZE];
} SCRAM_MD5_VRFY;
/* Client proof message */
typedef struct SCRAM_MD5_CLIENT_s {
unsigned char secprops[4];
unsigned char cproof[SCRAM_MD5_DATASIZE];
} SCRAM_MD5_CLIENT;
/* generate SCRAM-MD5 verifier
* vptr -- gets result
* salt -- contains salt of SCRAM_MD5_SALTSIZE
* pass -- passphrase or verifier
* passlen -- len of pass/verifier (0 ok if NUL terminated)
* plainflag -- 1 = plaintext passphrase,
* 0 = result of hmac_md5_precalc()
* clientkey -- cache for client proof, usually NULL
*/
void scram_md5_vgen(SCRAM_MD5_VRFY *vptr,
const unsigned char *salt,
const char *pass, int passlen, int plainflag,
unsigned char *clientkey);
/* scram secret action type */
#define SCRAM_CREDENTIAL 0 /* generate replies using credentials */
#define SCRAM_PLAINTEXT 1 /* generate replies using plaintext */
#define SCRAM_VERIFY 2 /* use SCRAM_MD5_VRFY to verify client,
Newman [Page 22]
Internet Draft SCRAM-MD5 SASL Mechanism January 1998
and generate server reply */
/* generate or verify SCRAM-MD5
* input params:
* cchal -- client challenge string
* cchallen -- length of client challenge
* schal -- server challenge string
* schallen -- length of server challenge
* secret -- passphrase, credentials, or verifier
* secretlen -- length of passphrase (0 ok if NUL terminated)
* action -- see above
* in/out:
* clidata -- client data for client response
* output:
* sproof -- server proof of length SCRAM_MD5_DATASIZE
* integrity_key -- integrity key of length SCRAM_MD5_DATASIZE
* caller may pass NULL if no integrity needed
* returns:
* -2 if params invalid
* -1 if verify fails
* 0 on success
*/
int scram_md5_generate(const char *cchal, int cchallen,
const char *schal, int schallen,
const char *secret, int secretlen,
int action,
SCRAM_MD5_CLIENT *clidata,
unsigned char *sproof,
unsigned char *integrity_key);
/* scram.c -- routines for SCRAM-MD5 calculations
*/
#include <stdio.h>
#include <stdlib.h>
#include <string.h>
#include "md5.h"
#include "hmac-md5.h"
#include "scram.h"
void scram_md5_vgen(SCRAM_MD5_VRFY *vptr,
const unsigned char *salt,
const char *pass, int passlen, int plainflag,
unsigned char *clientkey)
{
HMAC_MD5_CTX hctx;
if (clientkey == NULL) clientkey = vptr->clidata;
Newman [Page 23]
Internet Draft SCRAM-MD5 SASL Mechanism January 1998
/* get context */
if (plainflag) {
if (passlen == 0) passlen = strlen(pass);
hmac_md5_init(&hctx, (const unsigned char *) pass,
passlen);
} else {
hmac_md5_import(&hctx, (HMAC_MD5_STATE *) pass);
}
/* generate salted passphrase */
hmac_md5_update(&hctx, salt, SCRAM_MD5_SALTSIZE);
hmac_md5_final(vptr->clidata, &hctx);
/* generate server proof */
hmac_md5(salt, SCRAM_MD5_SALTSIZE, vptr->clidata,
sizeof (vptr->clidata), vptr->svrdata);
/* generate client key and client verifier */
MD5Init(&hctx.ictx);
MD5Update(&hctx.ictx, vptr->clidata, sizeof (vptr->clidata));
MD5Final(clientkey, &hctx.ictx);
MD5Init(&hctx.ictx);
MD5Update(&hctx.ictx, clientkey, SCRAM_MD5_DATASIZE);
MD5Final(vptr->clidata, &hctx.ictx);
/* copy salt to verifier */
if (salt != vptr->salt) {
memcpy(vptr->salt, salt, SCRAM_MD5_SALTSIZE);
}
}
int scram_md5_generate(const char *cchal, int cchallen,
const char *schal, int schallen,
const char *secret, int secretlen,
int action,
SCRAM_MD5_CLIENT *clidata,
unsigned char *sproof,
unsigned char *integrity_key)
{
SCRAM_MD5_VRFY verifier, *vptr;
HMAC_MD5_CTX hctx;
unsigned char clientkey[HMAC_MD5_SIZE];
unsigned char sharedkey[HMAC_MD5_SIZE];
int i, result = 0;
/* check params */
if ((action == SCRAM_CREDENTIAL
Newman [Page 24]
Internet Draft SCRAM-MD5 SASL Mechanism January 1998
&& secretlen != sizeof (HMAC_MD5_STATE))
|| (action == SCRAM_VERIFY
&& secretlen != sizeof (verifier))
|| schallen < SCRAM_MD5_SALTSIZE) {
return (-2);
}
/* get verifier */
if (action == SCRAM_VERIFY) {
vptr = (SCRAM_MD5_VRFY *) secret;
} else {
scram_md5_vgen(&verifier, (const unsigned char *) schal,
secret, secretlen, action, clientkey);
vptr = &verifier;
}
/* calculate shared key */
hmac_md5_init(&hctx, vptr->clidata, sizeof (vptr->clidata));
hmac_md5_update(&hctx, (unsigned char *) schal, schallen);
hmac_md5_update(&hctx, (unsigned char *) cchal, cchallen);
hmac_md5_update(&hctx, clidata->secprops, 4);
hmac_md5_final(sharedkey, &hctx);
if (action == SCRAM_VERIFY) {
/* verify client proof */
for (i = 0; i < HMAC_MD5_SIZE; ++i) {
XXX: the line which belongs here is omitted due to
U.S. export regulations, but it exclusive-ors the
"sharedkey" with the "clidata->cproof" and places the
result in "clientkey" (see step (c) above)
}
MD5Init(&hctx.ictx);
MD5Update(&hctx.ictx, clientkey, sizeof (clientkey));
MD5Final(sharedkey, &hctx.ictx);
if (memcmp(sharedkey, vptr->clidata,
sizeof (sharedkey)) != 0) {
result = -1;
}
} else {
/* generate client proof */
for (i = 0; i < HMAC_MD5_SIZE; ++i) {
XXX: the line which belongs here is omitted due to
U.S. export regulations, but it exclusive-ors the
"sharedkey" with the "clientkey" and places the
result in "clidata->cproof" (see step (G) above)
}
}
Newman [Page 25]
Internet Draft SCRAM-MD5 SASL Mechanism January 1998
/* calculate integrity key */
if (integrity_key != NULL) {
hmac_md5_init(&hctx, clientkey, HMAC_MD5_SIZE);
hmac_md5_update(&hctx, (unsigned char *) schal, schallen);
hmac_md5_update(&hctx, (unsigned char *) cchal, cchallen);
hmac_md5_update(&hctx, clidata->secprops, 4);
hmac_md5_final(integrity_key, &hctx);
}
/* calculate server result */
if (result == 0) {
hmac_md5_init(&hctx, vptr->svrdata, HMAC_MD5_SIZE);
hmac_md5_update(&hctx, (unsigned char *) cchal, cchallen);
hmac_md5_update(&hctx, (unsigned char *) schal, schallen);
hmac_md5_update(&hctx, clidata->secprops, 4);
hmac_md5_final(sproof, &hctx);
}
/* cleanup workspace */
memset(clientkey, 0, sizeof (clientkey));
memset(sharedkey, 0, sizeof (sharedkey));
if (vptr == &verifier) memset(&verifier, 0, sizeof (verifier));
return (result);
}
Newman [Page 26]