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This document defines the "Mutual authentication protocol for Hyper-Text Transport Protocol". This protocol provides true mutual authentication between HTTP clients and servers using simple password-based authentication. Unlike Basic and Digest HTTP access authentication protocol, the protocol ensures that server knows the user's entity (encrypted password) upon successful authentication. This prevents common phishing attacks: phishing attackers cannot convince users that the user has been authenticated to the genuine website. Furthermore, even when user has been authenticated against an illegitimate server, the server can not gain any bit of information about user's passwords.
1.
Introduction
1.1.
Requirements Language
2.
Protocol Overview
3.
Message Syntax
3.1.
Tokens and Ext-tokens
3.2.
Numbers
3.3.
Strings
4.
Messages
4.1.
401-B0
4.2.
401-B0-stale
4.3.
req-A1
4.4.
401-B1
4.5.
req-A3
4.6.
200-B4
5.
Decision procedure for the client
6.
Authentication Algorithms
7.
Validation Methods
8.
Session Management
9.
Extension 1: Optional Mutual Authentication
10.
Methods to extend this protocol
11.
IANA Considerations
12.
Security Considerations
13.
Notice on intellectual properties
14.
References
14.1.
Normative References
14.2.
Informative References
§
Authors' Addresses
§
Intellectual Property and Copyright Statements
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This document defines the "Mutual authentication protocol for Hyper-Text Transport Protocol". This protocol provides true mutual authentication between HTTP clients and servers using simple password-based authentication. Unlike Basic and Digest HTTP access authentication protocol, the protocol ensures that server knows the user's entity (encrypted password) upon successful authentication. This prevents common phishing attacks: phishing attackers cannot convince users that the user has been authenticated to the genuine website. Furthermore, even when user has been authenticated against an illegitimate server, the server can not gain any bit of information about user's passwords.
Recently, phishing attacks are getting more and more sophisticated. Phishers not only steal user's password directly, but imitate successful authentication to steal user's sensitive information, check the password validity by forwarding the password to the legitimate server, or employ a man-in-the-middle attack to hijack user's login session. Existing countermeasures such as one-time passwords can not completely solve these problems.
The protocol prevents such attacks by providing users a way to discriminate between true and fake web servers using their own passwords. Even when a user inputs his/her password to a fake website, using this authentication method, any information about the password does not leak to the phisher, and the user certainly notices that the mutual authentication has failed. Phishers cannot make such authentication attempt succeed, even if they forward received data from a user to the legitimate server or vice versa. Users can safely input sensitive data to the web forms after confirming that the mutual authentication has succeeded.
To achieve this goal, this protocol use a mechanism in ISO/IEC 11770-4, a kind of PAKE (Password-Authenticated Key Exchange) authentication algorithms as a basis. The use of PAKE mechanism allows users to use familiar ID/password based accesses, without fear of leaking any password information to the communication peer. The protocol, as a whole, is designed as a natural extension to the current HTTP authentication schema such as Basic and Digest access authentication (RFC 2617). To use PAKE mechanism for such a purpose, we had to modify it to prevent credential forwarding (man-in-the-middle) attacks.
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The key words "MUST", "MUST NOT", "REQUIRED", "SHALL", "SHALL NOT", "SHOULD", "SHOULD NOT", "RECOMMENDED", "MAY", and "OPTIONAL" in this document are to be interpreted as described in RFC2119.
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The following sequence is a typical sequence for the first access to the resource.
For the second or later request to the server, if the client knows that the resource is likely to require the authentication, the client MAY omit first unauthenticated request and send req-A1 message immediately. Furthermore, if client owns a valid session ID (sid), the client can send a req-A3 message using existing sid. In either case, the first (and only the first) response from the server MAY be a normal, unauthenticated message, and client MAY accept such messages. For more detail, see Section 5 (Decision procedure for the client).
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The Mutual authentication protocol uses four headers: WWW-Authenticate (in responses with status code 401), Optional-WWW-Authenticate (in responses with positive status codes), Authorization (in requests), and Authentication-info (in positive responses). These three headers share the common syntax described in Figure 1 (BNF syntax for the headers used in the protocol). The syntax is denoted in the augmented BNF syntax defined in RFC2616, except that "a"..."b" means any ASCII characters between "a" and "b" inclusive. The syntax is a subset of the one described in RFC2617.
header = header-name ":" spaces "Mutual" spaces fields header-name = "WWW-Authenticate" | "Optional-WWW-Authenticate" | "Authorization" | "Authentication-info" spaces = 1*(SP | HT | CR LF 1*(SP | HT))+ fields = field 0*("," spaces fields) field = key "=" value key = extensive-token extensive-token = token | extension-token extension-token = token "@" token token = 1*("0"..."9" | "A"..."Z" | "a"..."z" | "-" | "_" | ".") value = extensive-token | integer | hex-integer | hex-fixed-number | base64-fixed-number | string integer = "0" | ("1"..."9") 0*("0"..."9") hex-integer = "0" | ("1"..."9" | "A"..."F" | "a"..."f") 0*("0"..."9" | "A"..."F" | "a"..."f") hex-fixed-number = 1*("0"..."9" | "A"..."F" | "a"..."f") base64-fixed-number = string string = <"> *(<TEXT except <"> and "\"> | "\\" | "\" <"> | "\,")* <">
Figure 1: BNF syntax for the headers used in the protocol |
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The tokens MUST be interpreted case-insensitive, and SHOULD be sent in the same case as shown in the specification. All hex-fixed-number or hex-integer numbers are case-insensitive, and SHOULD be sent in lower-case.
Extensive-tokens are used where the set of acceptable tokens are extensible. Any non-standard extensions of this protocol MUST use the extension-tokens of format "<token>@<domain-name>", where domain-name is the valid registered (sub-)domain name on the Internet owned by the party who defines extensions.
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The syntax definitions of integer and hex-integer only allow representations which do not contain extra leading 0s.
The numbers represented as a hex-fixed-number SHALL have even characters (i.e. multiple of eight bits). When these are generated from the cryptographic values, those SHOULD have the natural length: if these are generated from a hash function, its lengths SHOULD correspond to the hash size; if these are representing elements of a mathematical group, its lengths SHOULD be the shortest which can represent all elements in the group. Other values such as session-id are represented in any (even) length determined by the side who generates it first, and the same length SHALL be used throughout the whole communications by both peers.
The numbers represented as a base64-fixed-number MUST be generated as follows: first, the number is converted to a big-endian octet-string representation. The length of the representation is determined in the same way as above. Then, the string is BASE64-converted, and then surrounded by two double-quotations.
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All strings outside ASCII or equivalent character sets SHOULD be encoded using UTF-8 encoding of the ISO 10646-1 character set. Both peers SHOULD reject any invalid UTF-8 sequences which causes decoding ambiguities (e.g. containing <"> in the second or later byte of the UTF-8 encoded characters). To encode character strings, these will first be encoded according to UTF-8, then all occurrences of characters <"> and "\" will be escaped by prepending "\", and two <">s will be put around the string. If the contents of the strings are comma-separated values, the commas in the values are also quoted by "\".
If strings are representing a domain name or URI which contains non-ASCII characters, the host parts SHOULD be encoded using puny-code instead of UTF-8, and SHOULD use lower-case ASCII characters.
For Base64-fixed-numbers, which use the string syntax, see the previous section.
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Every 401-B0 message must be an valid HTTP 401 (Authentication Required) message containing one (and only one: hereafter not explicitly noticed) "WWW-Authenticate" header of the following format.
WWW-Authenticate: Mutual algorithm=xxxx, validation=xxxx, realm=xxxx, stale=0
The header MUST contain the fields with the following keys:
- algorithm:
- (extensive-token) specifies the authentication algorithm to be used. The value MUST be one of the tokens described in Section 6 (Authentication Algorithms), or the tokens specified in other supplemental specification documentations.
- validation:
- (extensive-token) specifies the method of host validation. The value MUST be one of the tokens described in Section 7 (Validation Methods), or the tokens specified in other supplemental specification documentations.
- realm:
- (string) is a UTF-8 encoded name of the authentication domain inside the server.
- pwdhash:
- (optional, extensive-token) specifies the hash algorithm (referred to by ph) used for additionally hashing the password. The valid tokens are
If omitted, the value "none" is assumed.
- none: ph(p) = p
- md5: ph(p) = MD5(p)
- digest-md5: ph(p) defined as A1 in RFC2617.
- sha1: ph(p) = SHA1(p)
- auth-domain:
- (optional, string) MUST currently be equal to the host-part of the requested URI, and assumed to have that value if omitted. The triple of auth-domain, algorithm, and realm determines the "authentication realm" which defines the area where the same user-name and passwords are applicable.
- stale:
- (token) MUST be "0".
Any additional fields MUST NOT be contained in the header, except those explicitly specified in supplement specifications of the "authentication algorithm".
The algorithm will determine the values for w_A, w_B, o_A and o_B.
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A 401-B0-stale message is a variant of 401-B0 message, which means that the client has sent a request message which is not for any active session.
WWW-Authenticate: Mutual algorithm=xxxx, validation=xxxx, realm=xxxx, stale=1
The header MUST contain the same fields as in 401-B0, except the stale field holds the integer 1.
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Every req-A1 message MUST be a valid HTTP request message containing a "Authorization" header of the following format.
Authorization: Mutual algorithm=xxxx, validation=xxxx, user=xxxx, realm=xxxx, wa=xxxx
The header MUST contain the fields with the following keys:
- algorithm, validation, auth-domain, realm:
- MUST be the same value as it is received from S.
- user:
- (string) is the UTF-8 encoded name of the user.
- wa:
- (algorithm-determined) is the value of w_A specified by the used algorithm.
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Every 401-B1 message MUST be an valid HTTP 401 (Authentication Required) message containing a "WWW-Authenticate" header of the following format.
WWW-Authenticate: Mutual sid=xxxx, wb=xxxx, nc-max=x, nc-window=x, time=x, path=xxxx
The header MUST contain the fields with the following keys:
- sid:
- (hex-fixed-number) MUST be a session id, which is a random integer. The sid SHOULD have uniqueness of at least 80 bits or the square of the maximal estimated transactions concurrently available in the session table, whichever is larger. Sids are local to each authentication realm concerned: the same sids for different authentication realms SHALL be treated as independent ones.
- wb:
- (algorithm-determined) is the value of w_B specified by the algorithm.
- nc-max:
- (hex-integer) is the maximal value of nonce counts which S accepts.
- nc-window:
- (hex-integer) the number of available nonce slots which S prepares. The value of nc-window is RECOMMENDED to be thirty-two ("20" in hex-integer) or more.
- time:
- (integer) represents the suggested time (in seconds) which C can reuse the session key represented by sid. It SHOULD at least be 60. The value of this field is not directly linked to the duration that S keeps track of the session represented by sid.
- path:
- (string) specifies for which path in the URI space the same authentication is expected to apply. The value is the same format as it is specified in RFC2617 for the Digest authentications, and client is RECOMMENDED to recognize it. The all paths contained in the field SHALL be inside the specified auth-domain: if not, client SHOULD ignore such elements.
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Every req-A3 message MUST be a valid HTTP request message containing a "Authorization" header of the following format.
Authorization: Mutual sid=xxxx, nc=x, oa=xxxx
The fields contained in the header is as follows:
- sid:
- (hex-fixed-number) MUST be one of the sid values which has been received from S.
- nc:
- (hex-integer) is a nonce value which is unique among the requests sharing the same sid. The valie of nc MUST satisfy the following properties:
- It is not larger than the nc-max value which has been sent from S in the session represented by the sid.
- C have not sent the same value in the same session.
- It is not smaller than (largest-nc - nc-window), where largest-nc is the maximal value of nc which has previously been sent in the session, and nc-window is the value of the nc-window field which has been sent from S in the session.
- oa:
- (algorithm-determined) is the value of o_A specified by the algorithm.
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Every 200-B1 message MUST be an valid HTTP message which is not 401 (Authentication Required) type, containing an "Authentication-Info" header of the following format.
Authentication-Info: Mutual sid=xxxx, ob=xxxx
The fields contained in the header is as follows:
- sid:
- (hex-fixed-number) MUST be the value received from C.
- ob:
- (algorithm-determined) is the value of o_B specified by the algorithm.
- logout-timeout:
- (optional, integer) is a number of seconds after which the client should re-validate the user's password for the authentication realm. As a special case, the value 0 means that the client SHOULD automatically forget the user-inputed password to the current authentication realm and revert to the unauthenticated state (i.e.~server-initiated logout). This does not, however, mean that the long-term memories for the passwords (such as password reminders and auto fill-in) should be removed. If new value of timeout is received for the same authentication realm, it overrides the previous timeout.
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To securely implementing the protocol, the user client must be careful to accepting authenticated responses from the server.
Clients SHOULD implement the decision procedure equivalent to the one shown below. (Unless implementers understand what is required for security, they should not alter this.)
- Step 1
- If the client software need to get a new Web resource, check whether the resource is expected to be inside some authentication realm for which the user has already authenticated. if yes, go to Step 2. Otherwise, go to Step 5.
- Step 2
- Check whether there is an available sid for the authentication realm you expects. If there is one, go to Step 3. Other wise, go to Step 4.
- Step 3
- Send a req-A3 request.
- If you receive a 401-B0 message with a different authentication realm than expected, go to Step 6.
- If you receive a 401-B0-stale message, go to Step 9.
- If you receive a 401-B0 message, go to Step 13.
- If you receive a valid 200-B4 message, go to Step 14.
- If you receive a normal response (without Mutual-specific headers), go to Step 11.
- Step 4
- Send a req-A1 request.
- If you receive a 401-B0 message with a different authentication realm than expected, go to Step 6.
- If you receive a 401-B0-stale message, go to Step 9.
- If you receive a 401-B1 message, go to Step 10.
- If you receive a normal response (without Mutual-specific headers), go to Step 10.
- Step 5
- Send a request without any authentication headers.
- If you receive a 401-B0 message, go to Step 6.
- If you receive a normal response (without Mutual-specific headers), go to Step 11.
- Step 6
- Check whether you know the user's password for the requested authentication realm. If yes, go to Step 7. Otherwise, go to Step 12.
- Step 7
- Check whether there is an available sid for the authentication realm you expects. If there is one, go to Step 8. Other wise, go to Step 9.
- Step 8
- Send a req-A3 request.
- If you receive a 401-B0 message with a different authentication realm than expected, go to Step 6.
- If you receive a 401-B0-stale message, go to Step 9.
- If you receive a 401-B0 message, go to Step 13.
- If you receive a valid 200-B4 message, go to Step 14.
- Step 9
- Send a req-A1 request.
- If you receive a 401-B1 message, go to Step 10.
- Step 10
- Send a req-A3 request.
- If you receive a 401-B0 message, go to Step 13.
- If you receive a valid 200-B4 message, go to Step 14.
- Step 11
- This case means that the resource requested is out of the authenticated contents area. The client will be in "UNAUTHENTICATED" status.
- Step 12
- This case means that the resource requested requires mutual authentication, and the user is not authenticated yet. The client will be in "AUTH_REQUESTED" status, is RECOMMENDED to process the content sent from the server and, SHOULD ask user a username and password. If the user has input those, go to Step 9.
- Step 13
- This case means that in some reason the authentication failed: possibly the password or username is invalid for the authenticated resource. Forget the password for the authentication realm and go to Step 12.
- Step 14
- This case means that the mutual authentication has been succeeded. The client will be in "AUTH_SUCCEEDED" status.
All other kind of responses than shown in above procedure SHOULD be interpreted as fatal communication error, and in such cases user clients MUST NOT process any data sent from the server.
The client software SHOULD show the three client status to the end-user.
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This specification specified only one family of the authentication algorithm. The family consist of four authentication algorithms, which only differ in underlying mathematical groups and security parameters. The algorithms do not add any additional fields. The tokens for algorithms are
The clients SHOULD support at least "iso11770-4-dl-2048" algorithm, and RECOMMENDED to support all of the above four algorithms if possible. The server software implementations SHOULD support at least "iso11770-4-dl-2048" algorithm, unless it is known that users will not use it.
This algorithm uses Key-exchange-method-3 defined in ISO-11770-4 as a basis.
For the elliptic-curve settings, the underlying fields and the curves used for elliptic-curve cryptography are the prime field and the Curve P-256 and P-511, respectively, specified in the appendix of FIPS PUB 186-2 specification. The hash functions H are SHA-256 for P-256 curve and SHA-512 for P-521 curve, respectively. The representation of fields wa, wb, oa, and ob is hex-fixed-number.
For discrete-logarithm settings, the underlying groups are 2048-bit and 4096-bit MODP group defined in RFC3526 respectively. The hash functions H are SHA-256 for 2048-bit field and SHA-512 for 4096-bit field, respectively. The representation of fields wa, wb, oa, and ob is base64-fixed-number.
The password-based string pi used by this authentication is derived in the following manner:
pi = H(VS(algorithm) | VS(auth-domain) | VS(realm) | VS(username) | VS(ph(password)).
The values of algorithm, realm and auth-domain are taken from the values contained in the 401-B0 message. When pi is used in the context of an octet string, it MUST have the natural length derived from the bit-length of the output of function H (e.g. 32 octets for SHA-256). The function ph is defined by the value of the pwdhash given in a 401-B0 message.
The function VS encodes variable-length octet string into decodable octet string, as in the following manner:
VS(s) = VI(length(s)) | s,
where length(s) is a number of octets (not characters) in s and the function VI converts integer into octet string in the manner which is used for the length field in DER format. Shortly, integers are represented in big-endian radix-128 string, where each digit is represented by a octet 0x80–0xff except for the last digit represented by 0x00–0x7f. The first octet MUST NOT be 0x80. For example, VI(i) = octet(i) for i < 128, and VI(i) = octet(0x80 | (i >> 7)) | octet(i & 127) for 128 <= i < 16384.
The equation for J, w_A, T, z, K_i, and w_B is the one specified in the documentation of ISO-11770-4, given that pi is derived in the above equation.
The value o_A (o_A') and o_B (o_B') is derived by the following equation, instead of ones specified in ISO 11770-4.
o_A = H(hex(04) | GEtoOS_x(w_A) | GEtoOS_x(W_B) | GEtoOS_x(z) | GEtoOS_x(g_1) | VI(nc) | VS(v))
o_B = H(hex(03) | GEtoOS_x(w_A) | GEtoOS_x(W_B) | GEtoOS_x(z) | GEtoOS_x(g_1) | VI(nc) | VS(v))
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The "validation methods" specifies a method to "relates" the mutual authentication processed by this protocol with other authentications already performed in the underlying layers. It decides the value of v, which is an input to the authentication protocol.
The meaning of the validation method field and corresponding values of v is as follows:
- host:
- hostname validation: v will be the ASCII string in the following format: "scheme://host:port". The scheme and host are lower-case, and the port is in a shortest decimal representation. Even if the request-URI do not have a port part, v will include the one.
- tls-cert:
- TLS certificate validation: v will be the octet string of the fingerprint of the public key certificate used in underlying TLS/SSL connection.
- tls-key:
- TLS shared-key validation: v will be the octet string of the pre-shared secret negotiated in underlying TLS/SSL connection.
If HTTP protocol is used on unencrypted channel, the validation type MUST be "host". If HTTPS protocol with server certificates is used, the validation type MUST be either "tls-cert" or "tls-key". If HTTPS protocol is used with anonymous Diffie-Hellman key exchange, the validation type MUST be "tls-key" (but see the note below).
The client MUST validate this field upon reception of 401-B0 messages.
However, when the protocol is used on web browsers with any scripting capabilities, anonymous Diffie-Hellman family of TLS/SSL cipher-suite MUST NOT be used even if "tls-key" validated Mutual authentication has been employed, and the certificate shown in TLS/SSL negotiation MUST be verified using PKI. For other systems, if the "tls-key" validation is used on TLS/SSL protocol without certificate verification using PKI, those systems MUST ensure that all transactions with authenticated peer server MUST use and be validated by the Mutual authentication protocol, regardless of the existence of the 401-B0 responses.
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By the first 4 messages (first request, 401-B0, req-A1 and 401-B1), a session represented by a sid is generated. This session can be used for 1 or more requests for resources protected by the same realm in the same server.
The server SHOULD accept at least one req-A3 request for each sessions (given that the request reaches to the server in a time window specified by the timeout field specified in the 401-B1 message). After that, the server can discard any session at any time and send 401-B0-stale messages for any req-A3 requests.
The client can send more than 1 requests using a single session specified by the sid. However, for all such requests, the values of the nonce-counter (nc field) MUST be different from each other. The server MUST check for duplication of the received nonces, and if any duplication is detected, the server MUST discard the session and respond by a 401-B1-stale message.
In addition, for each sessions, if the client has already sent a request with nonce value x, it SHOULD NOT sent requests with nonce value not larger than (x - nc-window) afterwards. The server MAY reject any requests with nonces violating this rule with 401-B1-stale responses.
The value of nonces and nonce-related values MUST always be treated as a natural number within infinite range. Implementations using fixed-width integers or fixed-precision floating numbers MUST handle integer overflow correctly and carefully. Such implementations are RECOMMENDED to accept any larger values from the peer which cannot be represented in the fixed-width integer representations, as long as other limits such as internal header-length restrictions are involved. The protocol is designed carefully so that both clients and servers can be implemented the protocol only with fixed-width integers, by rounding any overflowed value into the maximum possible value.
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In several Web applications, users can access the same contents both as a guest user and as a authenticated users. In usual Web applications, it is implemented using Cookies and custom form-based authentications. The extension described in this section provides a replacement for those authentication systems.
Every HTTP successful responses (response code 200, 206 and others) to GET requests which do not contain Authentication-Info: header can contain the Optional-WWW-Authenticate header. Such messages are hereafter called 200-Optional-B0 messages.
HTTP/1.1 200 OK
Optional-WWW-Authenticate: Mutual algorithm=xxxx, validation=xxxx, realm=xxxx, stale=0
The fields contained in the Optional-WWW-Authenticate header is the same as the 401-B0 message described in Section 4.1 (401-B0). The client software supporting the mutual authentication protocol receiving a 200-Optional-B0 message will process the contents of the message and enables an authentication input field.
When the user input the username and password, the client resends the request with req-A1 header. The server MUST respond with a 401-B1 message. 200-Optional-B0 response SHOULD NOT be sent as a response to req-A1 and req-A3 messages, unless the authentication realm sent from the client (or indicated by sid) is different from the one which the server requests.
The client software supporting optional mutual authentication MUST recognize the "Path" field contained in 200-B4 message, and MUST send either req-A1 or req-A3 request for the URI space inside the specified "path"s, instead of unauthenticated requests.
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If a non-standard extensions to the this protocol is implemented, it SHOULD use the extension-tokens defined in Section 3 (Message Syntax) to avoid conflicts with this protocol and other extensions.
Authentication algorithms other than those defined in this document MAY use other representations for keys "wa", "wb", "oa" and "ob", replace those keys, and/or add fields to the messages containing those fields by supplemental specifications. Those specifications are RECOMMENDED to use extension-tokens to avoid any key-name conflict with the future extension of this protocol.
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The tokens used for authentication-algorithm, pwd-hash, validation MUST be registered to and assigned by IANA. All registered tokens must be defined by at least Informational RFC or similar standardization processes. Extension-tokens MAY be freely used for any non-standard or experimental uses for those fields provided that the domain part in the token is appropriately used.
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The National Institute of Advanced Industrial Science and Technology (AIST) and Yahoo! Japan, Inc. has jointly submitted a patent application about the protocol proposed in this documentation to the Patent Office of Japan. The patent is intended to be open to any implementors of this protocol and its variants under non-exclusive royalty-free manner without any contracts with the patent owners once the protocol is accepted as a Internet standard. For the detail of the patent application, contact the author of this document.
The elliptic-curve based authentication algorithms might involve several existing patents of third-parties. The authors of the document take no position regarding the validity or scope of such patents, and other patents as well.
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[ISO-11770-4] | International Organization for Standardization, “ISO/IEC 11770-4:2006: Information technology – Security techniques – Key management – Part 4: Mechanisms based on weak secrets,” 2006. |
[RFC2119] | Bradner, S., “Key words for use in RFCs to Indicate Requirement Levels,” BCP 14, RFC 2119, March 1997 (TXT, HTML, XML). |
[RFC3526] | Kivinen, T. and M. Kojo, “More Modular Exponential (MODP) Diffie-Hellman groups for Internet Key Exchange (IKE),” RFC 3526, May 2003 (TXT). |
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[RFC2616] | Fielding, R., Gettys, J., Mogul, J., Frystyk, H., Masinter, L., Leach, P., and T. Berners-Lee, “Hypertext Transfer Protocol -- HTTP/1.1,” RFC 2616, June 1999 (TXT, PS, PDF, HTML, XML). |
[RFC2617] | Franks, J., Hallam-Baker, P., Hostetler, J., Lawrence, S., Leach, P., Luotonen, A., and L. Stewart, “HTTP Authentication: Basic and Digest Access Authentication,” RFC 2617, June 1999 (TXT, HTML, XML). |
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Yutaka Oiwa | |
National Institute of Advanced Industrial Science and Technology | |
Research Center for Information Security | |
Akihabara Daibiru #1102 | |
1-18-13 Sotokanda | |
Chiyoda-ku, Tokyo | |
JP | |
Phone: | +81 3-5298-4722 |
Email: | y.oiwa@aist.go.jp |
Hajime Watanabe | |
National Institute of Advanced Industrial Science and Technology | |
Hiromitsu Takagi | |
National Institute of Advanced Industrial Science and Technology | |
Hirofumi Suzuki | |
Yahoo! Japan, Inc. | |
Roppongi Hills Mori Tower | |
6-10-1 Roppongi | |
Minato-ku, Tokyo | |
JP | |
Phone: | +81 3-6440-6290 |
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Copyright © The IETF Trust (2007).
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