Internet-Draft Editor: R. Harrison Intended Category: Draft Standard Novell, Inc. Document: draft-ietf-ldapbis-authmeth-05.txt March 2003 Obsoletes: RFC 2829, RFC 2830 LDAP: Authentication Methods and Connection Level Security Mechanisms Status of this Memo This document is an Internet-Draft and is in full conformance with all provisions of Section 10 of RFC2026. This document is intended to be, after appropriate review and revision, submitted to the RFC Editor as a Standard Track document. Distribution of this memo is unlimited. Technical discussion of this document will take place on the IETF LDAP Extension Working Group mailing list . Please send editorial comments directly to the author . 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." The list of current Internet-Drafts can be accessed at http://www.ietf.org/ietf/1id-abstracts.txt The list of Internet- Draft Shadow Directories can be accessed at http://www.ietf.org/shadow.html. Abstract This document describes LDAPv3 (Lightweight Directory Access Protocol v3) authentication methods and connection level security mechanisms that are required of all conforming LDAPv3 server implementations and makes recommendations for combinations of these mechanisms to be used in various deployment circumstances. Among the mechanisms described are - various forms of authentication including anonymous authentication, password-based authentication, and certificate based authentication - the use of SASL mechanisms with LDAPv3 - the use of TLS (Transport Layer Security) with LDAPv3 Harrison Expires September 2003 [Page 1] Authentication Methods for LDAPv3 - the various authentication and authorization states through which a connection to an LDAP server may pass and the actions that trigger these state changes. 1. Conventions Used in this Document 1.1. Glossary of Terms The following terms are used in this document. To aid the reader, these terms are defined here. - "user" represents any application which is an LDAP client using the directory to retrieve or store information. - "LDAP association" is used to distinguish the LDAP-level connection from any underlying TLS-level connection that may or may not exist. 1.2. Security Terms and Concepts In general, security terms in this document are used consistently with the definitions provided in [RFC2828]. In addition, several terms and concepts relating to security, authentication, and authorization are presented in Appendix B of this document. While the formal definition of these terms and concepts is outside the scope of this document, an understanding of them is prerequisite to understanding much of the material in this document. Readers who are unfamiliar with security-related concepts are encouraged to review Appendix B before reading the remainder of this document. 1.3. Keywords 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 RFC 2119 [RFC2119]. 2. Introduction This document is an integral part of the LDAP Technical Specification [ROADMAP]. This document replaces RFC 2829 and portions of RFC 2830. Changes to RFC 2829 are summarized in Appendix C and changes to RFC 2830 are summarized in Appendix D. LDAPv3 is a powerful access protocol for directories. It offers means of searching, retrieving and manipulating directory content, and ways to access a rich set of security functions. It is vital that these security functions be interoperable among all LDAP clients and servers on the Internet; therefore there has to be a minimum subset of security functions that is common to all implementations that claim LDAPv3 conformance. Basic threats to an LDAP directory service include: Harrison Expires September 2003 [Page 2] Authentication Methods for LDAPv3 (1) Unauthorized access to directory data via data-retrieval operations, (2) Unauthorized access to reusable client authentication information by monitoring others' access, (3) Unauthorized access to directory data by monitoring others' access, (4) Unauthorized modification of directory data, (5) Unauthorized modification of configuration information, (6) Unauthorized or excessive use of resources (denial of service), and (7) Spoofing of directory: Tricking a client into believing that information came from the directory when in fact it did not, either by modifying data in transit or misdirecting the client's connection. Threats (1), (4), (5) and (6) are due to hostile clients. Threats (2), (3) and (7) are due to hostile agents on the path between client and server or hostile agents posing as a server. The LDAP protocol suite can be protected with the following security mechanisms: (1) Client authentication by means of the SASL [RFC2222] mechanism set, possibly backed by the TLS [RFC2246] credentials exchange mechanism, (2) Client authorization by means of access control based on the requestor's authenticated identity, (3) Data integrity protection by means of the TLS protocol or SASL mechanisms that provide data integrity services, (4) Data confidentiality protection against snooping by means of the TLS protocol or SASL mechanisms that provide data confidentiality services, (5) Server resource usage limitation by means of administrative service limits configured on the server, and (6) Server authentication by means of the TLS protocol or SASL mechanism. At the moment, imposition of access controls is done by means outside the scope of the LDAPv3 protocol. 3. Rationale for LDAPv3 Security Mechanisms Harrison Expires September 2003 [Page 3] Authentication Methods for LDAPv3 It seems clear that allowing any implementation, faced with the above requirements, to simply pick and choose among the possible alternatives is not a strategy that is likely to lead to interoperability. In the absence of mandates, clients will be written that do not support any security function supported by the server, or worse, they will support only mechanisms like the LDAPv3 simple bind using clear text passwords that provide inadequate security for most circumstances. Given the presence of the Directory, there is a strong desire to see mechanisms where identities take the form of an LDAP distinguished name [LDAPDN] and authentication data can be stored in the directory. This means that this data must be updated outside the protocol or only updated in sessions well protected against snooping. It is also desirable to allow authentication methods to carry authorization identities based on existing--non-LDAP DN--forms of user identities for backwards compatibility with non-LDAP-based authentication services. The set of security mechanisms provided in LDAPv3 and described in this document is intended to meet the security needs for a wide range of deployment scenarios and still provide a high degree of interoperability among various LDAPv3 implementations and deployments. Appendix A contains example deployment scenarios that list the mechanisms that might be used to achieve a reasonable level of security in various circumstances. 4. Bind Operation The Bind operation defined in section 4.2 of [Protocol] allows authentication information to be exchanged between the client and server. 4.1. Unbound Connection Treated as Anonymous ("Implied Anonymous Bind") Unlike LDAP version 2, the client need not send a Bind Request in the first PDU of the connection. The client may send any operation request prior to binding, and the server MUST treat it as if it had been performed after an anonymous bind operation. If the server requires that the client bind before browsing or modifying the directory, the server MAY reject a request other than binding, unbinding or an extended request with the "operationsError" result. 4.2. Simple Authentication The simple authentication option provides minimal authentication facilities, with the contents of the authentication field consisting only of a cleartext password. Note that the use of cleartext passwords is strongly discouraged over open networks when the underlying transport service cannot guarantee confidentiality (see section 8). 4.3. SASL Authentication Harrison Expires September 2003 [Page 4] Authentication Methods for LDAPv3 The sasl authentication option allows for any mechanism defined for use with SASL [RFC2222] not specifically prohibited by this document (see section 4.3.1). Clients sending a bind request with the sasl choice selected SHOULD NOT send a value in the name field. Servers receiving a bind request with the sasl choice selected SHALL ignore any value in the name field. The mechanism field in SaslCredentials contains the name of the mechanism. The credentials field contains the arbitrary data used for authentication, inside an OCTET STRING wrapper. Note that unlike some Internet application protocols where SASL is used, LDAP is not text-based, thus no Base64 transformations are performed on the credentials. If any SASL-based integrity or confidentiality services are enabled, they take effect following the transmission by the server and reception by the client of the final BindResponse with a resultCode of success. If a SASL security layer is negotiated, the client MUST discard all information about the server fetched prior to the initiation of the SASL negotiation. If the client is configured to support multiple SASL mechanisms, it SHOULD fetch the supportedSASLmechanisms list both before and after the SASL security layer is negotiated. This allows the client to detect active attacks that remove supported SASL mechanisms from the supportedSASLMechanisms list and allows the client to ensure that it is using the best mechanism supported by both client and server. (This requirement is a SHOULD to allow for environments where the supportedSASLMechanisms list is provided to the client through a different trusted source, e.g. as part of a digitally signed object.) The client can request that the server use authentication information from a lower layer protocol by using the SASL EXTERNAL mechanism (see section 5.2.2.). 4.3.1. Use of ANONYMOUS and PLAIN SASL Mechanisms As LDAP includes native anonymous and plaintext authentication methods, the "ANONYMOUS" and "PLAIN" SASL mechanisms are not used with LDAP. If an authorization identity of a form different from a DN is requested by the client, a data confidentiality mechanism that protects the password in transit should be used. 4.3.2. Use of EXTERNAL SASL Mechanism The "EXTERNAL" SASL mechanism can be used to request the LDAP server make use of security credentials exchanged by a lower layer. If a TLS session has not been established between the client and server prior to making the SASL EXTERNAL Bind request and there is no other external source of authentication credentials (e.g. IP-level Harrison Expires September 2003 [Page 5] Authentication Methods for LDAPv3 security [RFC2401]), or if during the process of establishing the TLS session, the server did not request the client's authentication credentials, the SASL EXTERNAL bind MUST fail with a resultCode of inappropriateAuthentication. Any client authentication and authorization state of the LDAP association is lost, so the LDAP association is in an anonymous state after the failure (see [Protocol] section 4.2.1). 4.3.3. Other SASL Mechanisms Other SASL mechanisms may be used with LDAP, but their usage is not considered in this document. 4.4. SASL Authorization Identity The authorization identity is carried as part of the SaslCredentials credentials field in the Bind request and response. When the "EXTERNAL" SASL mechanism is being negotiated, if the credentials field is present, it contains an authorization identity of the authzId form described below. Other mechanisms define the location of the authorization identity in the credentials field. 4.4.1. Authorization Identity Syntax The authorization identity is a string in the UTF-8 character set, corresponding to the following ABNF grammar [RFC2234]: ; Specific predefined authorization (authz) id schemes are ; defined below -- new schemes may be defined in the future. authzId = dnAuthzId / uAuthzId DNCOLON = %x64 %x6e %x3a ; "dn:" UCOLON = %x75 %x3a ; "u:" ; distinguished-name-based authz id. dnAuthzId = DNCOLON dn dn = utf8string ; with syntax defined in [LDAPDN] section 3. ; unspecified authorization id, UTF-8 encoded. uAuthzId = UCOLON userid userid = utf8string ; syntax unspecified The dnAuthzId choice allows client applications to assert authorization identities in the form of a distinguished name. The decision to allow or disallow an authentication identity to have access to the requested authorization identity is a matter of local policy ([SASL] section 4.2). For this reason there is no requirement that the asserted dn be that of an entry in directory. Harrison Expires September 2003 [Page 6] Authentication Methods for LDAPv3 The uAuthzId choice allows for compatibility with client applications that wish to assert an authorization identity to a local directory but do not have that identity in distinguished name form. The format of utf8string is defined as only a sequence of UTF- 8 encoded ISO 10646 characters, and further interpretation is subject to prior agreement between the client and server. For example, the userid could identify a user of a specific directory service, or be a login name or the local-part of an RFC 822 email address. In general, a uAuthzId MUST NOT be assumed to be globally unique. Additional authorization identity schemes MAY be defined in future versions of this document. 4.5. SASL Service Name for LDAP For use with SASL [RFC2222], a protocol must specify a service name to be used with various SASL mechanisms, such as GSSAPI. For LDAP, the service name is "ldap", which has been registered with the IANA as a GSSAPI service name. 4.6. SASL Integrity and Privacy Protections Any negotiated SASL integrity and privacy protections SHALL start on the first octet of the first LDAP PDU following successful completion of the SASL bind operation. If lower level security layer is negotiated, such as TLS, any SASL security services SHALL be layered on top of such security layers regardless of the order of their negotiation. 5. Start TLS Operation The Start Transport Layer Security (StartTLS) operation defined in section 4.13 of [Protocol] provides the ability to establish Transport Layer Security [RFC2246] on an LDAP association. 5.1. Sequencing of the Start TLS Operation This section describes the overall procedures clients and servers must follow for TLS establishment. These procedures take into consideration various aspects of the overall security of the LDAP association including discovery of resultant security level and assertion of the client's authorization identity. Note that the precise effects, on a client's authorization identity, of establishing TLS on an LDAP association are described in detail in section 5.5. 5.1.1. Requesting to Start TLS on an LDAP Association The client MAY send the Start TLS extended request at any time after establishing an LDAP association, except that in the following cases the client MUST NOT send a Start TLS extended request: Harrison Expires September 2003 [Page 7] Authentication Methods for LDAPv3 - if TLS is currently established on the connection, or - during a multi-stage SASL negotiation, or - if there are any LDAP operations outstanding on the connection. The result of violating any of these requirements is a resultCode of operationsError, as described above in [Protocol] section 14.3.2.2. In particular, there is no requirement that the client have or have not already performed a Bind operation before sending a Start TLS operation request. The client may have already performed a Bind operation when it sends a Start TLS request, or the client might have not yet bound. If the client did not establish a TLS connection before sending any other requests, and the server requires the client to establish a TLS connection before performing a particular request, the server MUST reject that request by sending a resultCode of confidentialityRequired or strongAuthRequired. In response, the client MAY send a Start TLS extended request, or it MAY choose to close the connection. 5.1.2. Starting TLS The server will return an extended response with the resultCode of success if it is willing and able to negotiate TLS. It will return other resultCodes (documented in [Protocol] section 4.13.2.2) if it is unable to do so. In the successful case, the client (which has ceased to transfer LDAP requests on the connection) MUST either begin a TLS negotiation or close the connection. The client will send PDUs in the TLS Record Protocol directly over the underlying transport connection to the server to initiate TLS negotiation [RFC2246]. 5.1.3. TLS Version Negotiation Negotiating the version of TLS or SSL to be used is a part of the TLS Handshake Protocol, as documented in [RFC2246]. Please refer to that document for details. 5.1.4. Discovery of Resultant Security Level After a TLS connection is established on an LDAP association, both parties MUST individually decide whether or not to continue based on the privacy level achieved. Ascertaining the TLS connection's privacy level is implementation dependent, and accomplished by communicating with one's respective local TLS implementation. If the client or server decides that the level of authentication or privacy is not high enough for it to continue, it SHOULD gracefully close the TLS connection immediately after the TLS negotiation has completed (see [Protocol] section 4.13.3.1 and section 5.2.3 below). Harrison Expires September 2003 [Page 8] Authentication Methods for LDAPv3 If the client decides to continue, it MAY attempt to Start TLS again, it MAY send an unbind request, or it MAY send any other LDAP request. 5.1.5. Assertion of Client's Authorization Identity The client MAY, upon receipt of a Start TLS response indicating success, assert that a specific authorization identity be utilized in determining the client's authorization status. The client accomplishes this via an LDAP Bind request specifying a SASL mechanism of "EXTERNAL" [RFC2222] (see section 5.5.1.2 below). 5.1.6. Server Identity Check The client MUST check its understanding of the server's hostname against the server's identity as presented in the server's Certificate message, in order to prevent man-in-the-middle attacks. Matching is performed according to these rules: - The client MUST use the server hostname it used to open the LDAP connection as the value to compare against the server name as expressed in the server's certificate. The client MUST NOT use the any other derived form of name including the server's canonical DNS name. - If a subjectAltName extension of type dNSName is present in the certificate, it SHOULD be used as the source of the server's identity. - Matching is case-insensitive. - The "*" wildcard character is allowed. If present, it applies only to the left-most name component. For example, *.bar.com would match a.bar.com and b.bar.com, but it would not match a.x.bar.com nor would it match bar.com. If more than one identity of a given type is present in the certificate (e.g. more than one dNSName name), a match in any one of the set is considered acceptable. If the hostname does not match the dNSName-based identity in the certificate per the above check, user-oriented clients SHOULD either notify the user (clients MAY give the user the opportunity to continue with the connection in any case) or terminate the connection and indicate that the server's identity is suspect. Automated clients SHOULD close the connection, returning and/or logging an error indicating that the server's identity is suspect. Beyond the server identity checks described in this section, clients SHOULD be prepared to do further checking to ensure that the server is authorized to provide the service it is observed to provide. The client MAY need to make use of local policy information. Harrison Expires September 2003 [Page 9] Authentication Methods for LDAPv3 5.1.7. Refresh of Server Capabilities Information Upon TLS session establishment, the client MUST discard all information about the server fetched prior to the initiation of the TLS negotiation and MUST refresh any cached server capabilities information (e.g. from the server's root DSE; see section 3.4 of [Protocol]). This is necessary to protect against active- intermediary attacks that may have altered any server capabilities information retrieved prior to TLS establishment. The server MAY advertise different capabilities after TLS establishment. In particular, the value of supportedSASLMechanisms MAY be different after TLS has been negotiated (specifically, the EXTERNAL mechanism or the proposed PLAIN mechanism are likely to only be listed after a TLS negotiation has been performed). 5.2. Effects of TLS on a Client's Authorization Identity This section describes the effects on a client's authorization identity brought about by establishing TLS on an LDAP association. The default effects are described first, and next the facilities for client assertion of authorization identity are discussed including error conditions. Finally, the effects of closing the TLS connection are described. Authorization identities and related concepts are described in Appendix B. 5.2.1. Default Effects Upon establishment of the TLS session onto the LDAP association, any previously established authentication and authorization identities MUST remain in force, including anonymous state. This holds even in the case where the server requests client authentication via TLS -- e.g. requests the client to supply its certificate during TLS negotiation (see [RFC2246]). 5.2.2. Client Assertion of Authorization Identity A client MAY either implicitly request that its LDAP authorization identity be derived from its authenticated TLS credentials or it MAY explicitly provide an authorization identity and assert that it be used in combination with its authenticated TLS credentials. The former is known as an implicit assertion, and the latter as an explicit assertion. 5.2.2.1. Implicit Assertion An implicit authorization identity assertion is accomplished after TLS establishment by invoking a Bind request of the SASL form using the "EXTERNAL" mechanism name [RFC2222] [Protocol] that SHALL NOT include the optional credentials octet string (found within the SaslCredentials sequence in the Bind Request). The server will derive the client's authorization identity from the authentication Harrison Expires September 2003 [Page 10] Authentication Methods for LDAPv3 identity supplied in the client's TLS credentials (typically a public key certificate) according to local policy. The underlying mechanics of how this is accomplished are implementation specific. 5.2.2.2. Explicit Assertion An explicit authorization identity assertion is accomplished after TLS establishment by invoking a Bind request of the SASL form using the "EXTERNAL" mechanism name [RFC2222] [Protocol] that SHALL include the credentials octet string. This string MUST be constructed as documented in section 4.4.1. 5.2.2.3. Error Conditions For either form of assertion, the server MUST verify that the client's authentication identity as supplied in its TLS credentials is permitted to be mapped to the asserted authorization identity. The server MUST reject the Bind operation with an invalidCredentials resultCode in the Bind response if the client is not so authorized. Additionally, with either form of assertion, if a TLS session has not been established between the client and server prior to making the SASL EXTERNAL Bind request and there is no other external source of authentication credentials (e.g. IP-level security [RFC2401]), or if during the process of establishing the TLS session, the server did not request the client's authentication credentials, the SASL EXTERNAL bind MUST fail with a result code of inappropriateAuthentication. After the above Bind operation failures, any client authentication and authorization state of the LDAP association is lost (see [Protocol] section 4.2.1), so the LDAP association is in an anonymous state after the failure. The TLS session state is unaffected, though a server MAY end the TLS session, via a TLS close_notify message, based on the Bind failure (as it MAY at any time). 5.2.3. TLS Connection Closure Effects Closure of the TLS session MUST cause the LDAP association to move to an anonymous authentication and authorization state regardless of the state established over TLS and regardless of the authentication and authorization state prior to TLS session establishment. 6. LDAP Association State Transition Tables To comprehensively diagram the various authentication and TLS states through which an LDAP association may pass, this section provides a state transition table to represent a state diagram for the various states through which an LDAP association may pass during the course of its existence and the actions that cause these changes in state. 6.1. LDAP Association States Harrison Expires September 2003 [Page 11] Authentication Methods for LDAPv3 The following table lists the valid LDAP association states and provides a description of each state. The ID for each state is used in the state transition table in section 6.4. ID State Description -- -------------------------------------------------------------- S1 no Auth ID no AuthZ ID [TLS: no Creds, OFF] S2 no Auth ID no AuthZ ID [TLS: no Creds, ON] S3 no Auth ID no AuthZ ID [TLS: Creds Auth ID "I", ON] S4 Auth ID = Xn AuthZ ID= Y [TLS: no Creds, OFF] S5 Auth ID = Xn AuthZ ID= Yn [TLS: no Creds, ON] S6 Auth ID = Xn AuthZ ID= Yn [TLS: Creds Auth ID "I", ON] S7 Auth ID = I AuthZ ID= J [TLS: Creds Auth ID "I", ON] S8 Auth ID = I AuthZ ID= K [TLS: Creds Auth ID "I", ON] 6.2. Actions that Affect LDAP Association State The following table lists the actions that can affect the state of an LDAP association. The ID for each action is used in the state transition table in section 6.4. ID Action -- ------------------------------------------------ A1 Client binds anonymously A2 Inappropriate authentication: client attempts an anonymous bind or a bind without supplying credentials to a server that requires the client to provide some form of credentials. A3 Client Start TLS request Server: client auth NOT required A4 Client: Start TLS request Server: client creds requested Client: [TLS creds: Auth ID "I"] A5 Client or Server: send TLS closure alert ([Protocol] section X) A6 Client: Bind w/simple password or SASL mechanism (e.g. DIGEST- MD5 password, Kerberos, etc. -û except EXTERNAL [Auth ID "X" Harrison Expires September 2003 [Page 12] Authentication Methods for LDAPv3 maps to AuthZ ID "Y"] A7 Client Binds SASL EXTERNAL with credentials: AuthZ ID "J" [Explicit Assertion (section 5.2.1.2.2)] A8 Client Bind SASL EXTERNAL without credentials [Implicit Assertion (section 5.2 .1.2.1)] 6.3. Decisions Used in Making LDAP Association State Changes Certain changes in the state of an LDAP association are only allowed if the server can affirmatively answer a question. These questions are applied as part of the criteria for allowing or disallowing a state change in the state transition table in section 6.4. ID Decision Question -- -------------------------------------------------------------- D1 Can TLS Credentials Auth ID "I" be mapped to AuthZ ID "J"? D2 Can a valid AuthZ ID "K" be derived from TLS Credentials Auth ID "I"? 6.4. LDAP Association State Transition Table The LDAP Association table below lists the valid states for an LDAP association and the actions that could affect them. For any given row in the table, the Current State column gives the state of an LDAP association, the Action column gives an action that could affect the state of an LDAP assocation, and the Next State column gives the resulting state of an LDAP association after the action occurs. The initial state for the state machine described in this table is S1. Current Next State Action State Comment ------- ------------- ----- ----------------------------------- S1 A1 S1 S1 A2 S1 Error: Inappropriate authentication S1 A3 S2 S1 A4 S3 S1 A6 S4 S1 A7 ? identity could be provided by another underlying mechanism such as IPSec. S1 A8 ? identity could be provided by another underlying mechanism such as IPSec. S2 A1 S2 S2 A2 S2 Error: Inappropriate authentication S2 A5 S1 S2 A6 S5 S2 A7 ? identity could be provided by another underlying mechanism such as IPSec. Harrison Expires September 2003 [Page 13] Authentication Methods for LDAPv3 S2 A8 ? identity could be provided by another underlying mechanism such as IPSec. S3 A1 S3 S3 A2 S3 Error: Inappropriate authentication S3 A5 S1 S3 A6 S6 S3 A7 and D1=NO S3 Error: InvalidCredentials S3 A7 and D1=YES S7 S3 A8 and D2=NO S3 Error: InvalidCredentials S3 A8 and D2=YES S8 S4 A1 S1 S4 A2 S4 Error: Inappropriate Authentication S4 A3 S5 S4 A4 S6 S4 A5 S1 S4 A6 S4 S4 A7 ? identity could be provided by another underlying mechanism such as IPSec. S4 A8 ? identity could be provided by another underlying mechanism such as IPSec. S5 A1 S2 S5 A2 S5 Error: Inappropriate Authentication S5 A5 S1 S5 A6 S5 S5 A7 ? identity could be provided by another underlying mechanism such as IPSec. S5 A8 ? identity could be provided by another underlying mechanism such as IPSec. S6 A1 S3 S6 A2 S6 Error: Inappropriate Authentication S6 A5 S1 S6 A6 S6 S6 A7 and D1=NO S6 Error: InvalidCredentials S6 A7 and D1=YES S7 S6 A8 and D2=NO S6 Error: InvalidCredentials S6 A8 and D2=YES S8 S7 A1 S3 S7 A2 S7 Error: Inappropriate Authentication S7 A5 S1 S7 A6 S6 S7 A7 S7 S7 A8 and D2=NO S3 Error: InvalidCredentials S7 A8 and D2=YES S8 S8 A1 S3 S8 A2 S8 Error: Inappropriate Authentication S8 A5 S1 S8 A6 S6 Harrison Expires September 2003 [Page 14] Authentication Methods for LDAPv3 S8 A7 and D1=NO S6 Error: InvalidCredentials S8 A7 and D1=YES S7 S8 A8 S8 7. Anonymous Authentication Directory operations that modify entries or access protected attributes or entries generally require client authentication. Clients that do not intend to perform any of these operations typically use anonymous authentication. Servers SHOULD NOT allow clients with anonymous authentication to modify directory entries or access sensitive information in directory entries. LDAP implementations MUST support anonymous authentication, as defined in section 7.1. LDAP implementations MAY support anonymous authentication with TLS, as defined in section 7.2. While there MAY be access control restrictions to prevent access to directory entries, an LDAP server SHOULD allow an anonymously-bound client to retrieve the supportedSASLMechanisms attribute of the root DSE. An LDAP server MAY use other information about the client provided by the lower layers or external means to grant or deny access even to anonymously authenticated clients. 7.1. Anonymous Authentication Procedure An LDAPv3 client that has not successfully completed a bind operation on a connection is anonymously authenticated. See section 4.3.3. An LDAP client MAY also choose to explicitly bind anonymously. A client that wishes to do so MUST choose the simple authentication option in the Bind Request (see section 4.1) and set the password to be of zero length. (This is often done by LDAPv2 clients.) Typically the name is also of zero length. 7.2. Anonymous Authentication and TLS An LDAP client MAY use the Start TLS operation (section 5) to negotiate the use of TLS security [RFC2246]. If the client has not bound beforehand, then until the client uses the EXTERNAL SASL mechanism to negotiate the recognition of the client's certificate, the client is anonymously authenticated. Recommendations on TLS ciphersuites are given in section 10. An LDAP server which requests that clients provide their certificate during TLS negotiation MAY use a local security policy to determine Harrison Expires September 2003 [Page 15] Authentication Methods for LDAPv3 whether to successfully complete TLS negotiation if the client did not present a certificate which could be validated. 8. Password-based Authentication This section discusses various options for performing password-based authentication to LDAPv3 compliant servers and the environments suitable for their use. 8.1. Simple Authentication The LDAP "simple" authentication choice is not suitable for authentication in environments where there is no network or transport layer confidentiality. LDAP implementations SHOULD support authentication with the "simple" authentication choice when the connection is protected against eavesdropping using TLS, as defined in section 5. LDAP implementations SHOULD NOT support authentication with the "simple" authentication choice unless the data on the connection is protected using TLS or other data confidentiality and data integrity protection. 8.2. Digest Authentication LDAP servers that implement any password-based authentication method MUST support authentication with a password using the DIGEST-MD5 SASL mechanism for password protection. An LDAP client MAY determine whether the server supports this mechanism by performing a search request on the root DSE, requesting the supportedSASLMechanisms attribute, and checking whether the string "DIGEST-MD5" is present as a value of this attribute. In the first stage of authentication, when the client is performing an "initial authentication" as defined in section 2.1 of [RFC2831], the client sends a bind request in which the version number is 3, the authentication choice is sasl, the sasl mechanism name is "DIGEST-MD5", and the credentials are absent. The client then waits for a response from the server to this request. The server will respond with a bind response in which the resultCode is saslBindInProgress, and the serverSaslCreds field is present. The contents of this field is a string defined by "digest-challenge" in section 2.1.1 of [RFC2831]. The server SHOULD include a realm indication and MUST indicate support for UTF-8. The client will send a bind request with a distinct message id, in which the version number is 3, the authentication choice is sasl, the sasl mechanism name is "DIGEST-MD5", and the credentials contain the string defined by "digest-response" in section 2.1.2 of [RFC2831]. The serv-type is "ldap". The server will respond with a bind response in which the resultCode is either success, or an error indication. If the authentication is successful and the server does not support subsequent Harrison Expires September 2003 [Page 16] Authentication Methods for LDAPv3 authentication, then the credentials field is absent. If the authentication is successful and the server supports subsequent authentication, then the credentials field contains the string defined by "response-auth" in section 2.1.3 of [RFC2831]. Support for subsequent authentication is OPTIONAL in clients and servers. 8.3. "simple" authentication choice under TLS encryption Following the negotiation of an appropriate TLS ciphersuite providing connection confidentiality [RFC2246], a client MAY authenticate to a directory that supports the simple authentication choice by performing a simple bind operation. The client will use the Start TLS operation [Protocol] to negotiate the use of TLS security [RFC2246] on the connection to the LDAP server. The client need not have bound to the directory beforehand. For this authentication procedure to be successful, the client and server MUST negotiate a ciphersuite which contains a bulk encryption algorithm of appropriate strength. Recommendations on cipher suites are given in section 10. Following the successful completion of TLS negotiation, the client MUST send an LDAP bind request with the version number of 3, the name field containing a DN, and the "simple" authentication choice, containing a password. 8.3.1. "simple" Authentication Choice DSAs that map the DN sent in the bind request to a directory entry with an associated set of one or more passwords will compare the presented password to the set of passwords associated with that entry. If there is a match, then the server will respond with resultCode success, otherwise the server will respond with resultCode invalidCredentials. 8.4. Other authentication choices with TLS It is also possible, following the negotiation of TLS, to perform a SASL authentication that does not involve the exchange of plaintext reusable passwords. In this case the client and server need not negotiate a ciphersuite that provides confidentiality if the only service required is data integrity. 9. Certificate-based authentication LDAP server implementations SHOULD support authentication via a client certificate in TLS, as defined in section 5.2.2. 9.1. Certificate-based authentication with TLS A user who has a public/private key pair in which the public key has been signed by a Certification Authority may use this key pair to authenticate to the directory server if the user's certificate is Harrison Expires September 2003 [Page 17] Authentication Methods for LDAPv3 requested by the server. The user's certificate subject field SHOULD be the name of the user's directory entry, and the Certification Authority that issued the user's certificate must be sufficiently trusted by the directory server in order for the server to process the certificate. The means by which servers validate certificate paths is outside the scope of this document. A server MAY support mappings for certificates in which the subject field name is different from the name of the user's directory entry. A server which supports mappings of names MUST be capable of being configured to support certificates for which no mapping is required. The client will use the Start TLS operation [Protocol] to negotiate the use of TLS security [RFC2246] on the connection to the LDAP server. The client need not have bound to the directory beforehand. In the TLS negotiation, the server MUST request a certificate. The client will provide its certificate to the server, and the server MUST perform a private key-based encryption, proving it has the private key associated with the certificate. In deployments that require protection of sensitive data in transit, the client and server MUST negotiate a ciphersuite that contains a bulk encryption algorithm of appropriate strength. Recommendations of cipher suites are given in section 10. The server MUST verify that the client's certificate is valid. The server will normally check that the certificate is issued by a known certification authority (CA), and that none of the certificates on the client's certificate chain are invalid or revoked. There are several procedures by which the server can perform these checks. Following the successful completion of TLS negotiation, the client will send an LDAP bind request with the SASL "EXTERNAL" mechanism. 10. TLS Ciphersuites The following ciphersuites defined in [RFC2246] MUST NOT be used for confidentiality protection of passwords or data: TLS_NULL_WITH_NULL_NULL TLS_RSA_WITH_NULL_MD5 TLS_RSA_WITH_NULL_SHA The following ciphersuites defined in [RFC2246] can be cracked easily (less than a day of CPU time on a standard CPU in 2000). These ciphersuites are NOT RECOMMENDED for use in confidentiality protection of passwords or data. Client and server implementers SHOULD carefully consider the value of the password or data being protected before using these ciphersuites: TLS_RSA_EXPORT_WITH_RC4_40_MD5 TLS_RSA_EXPORT_WITH_RC2_CBC_40_MD5 TLS_RSA_EXPORT_WITH_DES40_CBC_SHA Harrison Expires September 2003 [Page 18] Authentication Methods for LDAPv3 TLS_DH_DSS_EXPORT_WITH_DES40_CBC_SHA TLS_DH_RSA_EXPORT_WITH_DES40_CBC_SHA TLS_DHE_DSS_EXPORT_WITH_DES40_CBC_SHA TLS_DHE_RSA_EXPORT_WITH_DES40_CBC_SHA TLS_DH_anon_EXPORT_WITH_RC4_40_MD5 TLS_DH_anon_EXPORT_WITH_DES40_CBC_SHA The following ciphersuites are vulnerable to man-in-the-middle attacks, and SHOULD NOT be used to protect passwords or sensitive data, unless the network configuration is such that the danger of a man-in-the-middle attack is tolerable: TLS_DH_anon_EXPORT_WITH_RC4_40_MD5 TLS_DH_anon_WITH_RC4_128_MD5 TLS_DH_anon_EXPORT_WITH_DES40_CBC_SHA TLS_DH_anon_WITH_DES_CBC_SHA TLS_DH_anon_WITH_3DES_EDE_CBC_SHA A client or server that supports TLS MUST support TLS_DHE_DSS_WITH_3DES_EDE_CBC_SHA and MAY support other ciphersuites offering equivalent or better protection. 11. Security Considerations Security issues are discussed throughout this memo; the (unsurprising) conclusion is that mandatory security is important and that session confidentiality protection is required when snooping is a problem. Servers are encouraged to prevent modifications by anonymous users. Servers may also wish to minimize denial of service attacks by timing out idle connections, and returning the unwillingToPerform result code rather than performing computationally expensive operations requested by unauthorized clients. Operational experience shows that clients can misuse unauthenticated access (simple bind with name but no password). For this reason, servers SHOULD by default reject authentication requests that have a DN with an empty password with an error of invalidCredentials. Access control SHOULD be applied when reading sensitive information or updating directory information. A connection on which the client has not performed the Start TLS operation or negotiated a suitable SASL mechanism for connection integrity and encryption services is subject to man-in-the-middle attacks to view and modify information in transit. 11.1. Start TLS Security Considerations The goals of using the TLS protocol with LDAP are to ensure connection confidentiality and integrity, and to optionally provide for authentication. TLS expressly provides these capabilities, as described in [RFC2246]. Harrison Expires September 2003 [Page 19] Authentication Methods for LDAPv3 All security gained via use of the Start TLS operation is gained by the use of TLS itself. The Start TLS operation, on its own, does not provide any additional security. Once established, TLS only provides for and ensures confidentiality and integrity of the operations and data in transit over the LDAP association--and only if the implementations on the client and server support and negotiate it. The use of TLS does not provide or ensure for confidentiality and/or non-repudiation of the data housed by an LDAP-based directory server. Nor does it secure the data from inspection by the server administrators. The level of security provided though the use of TLS depends directly on both the quality of the TLS implementation used and the style of usage of that implementation. Additionally, an active- intermediary attacker can remove the Start TLS extended operation from the supportedExtension attribute of the root DSE. Therefore, both parties SHOULD independently ascertain and consent to the security level achieved once TLS is established and before beginning use of the TLS connection. For example, the security level of the TLS connection might have been negotiated down to plaintext. Clients SHOULD either warn the user when the security level achieved does not provide confidentiality and/or integrity protection, or be configurable to refuse to proceed without an acceptable level of security. Client and server implementors SHOULD take measures to ensure proper protection of credentials and other confidential data where such measures are not otherwise provided by the TLS implementation. Server implementors SHOULD allow for server administrators to elect whether and when connection confidentiality and/or integrity is required, as well as elect whether and when client authentication via TLS is required. Additional security considerations relating to the EXTERNAL mechanism to negotiate TLS can be found in [RFC2222] and [RFC2246]. 12. Acknowledgements This document combines information originally contained in RFC 2829 and RFC 2830. The author acknowledges the work of Harald Tveit Alvestrand, Jeff Hodges, Tim Howes, Steve Kille, RL "Bob" Morgan , and Mark Wahl, each of whom authored one or more of these documents. RFC 2829 and RFC 2830 were products of the IETF LDAPEXT Working Group. RFC 2251 was a product of the ASID Working Group. This document is based upon input of the IETF LDAP Revision working group. The contributions of its members is greatly appreciated. 13. Normative References Harrison Expires September 2003 [Page 20] Authentication Methods for LDAPv3 [RFC2119] Bradner, S., "Key Words for use in RFCs to Indicate Requirement Levels", BCP 14, RFC 2119, March 1997. [RFC2222] Myers, J., "Simple Authentication and Security Layer (SASL)", draft-myers-saslrev-xx.txt, a work in progress. [RFC2234] Crocker, D., Ed. and P. Overell, "Augmented BNF for Syntax Specifications: ABNF", RFC 2234, November 1997. [RFC2246] Dierks, T. and C. Allen. "The TLS Protocol Version 1.0", RFC 2246, January 1999. [RFC2831] Leach, P. and C. Newman, "Using Digest Authentication as a SASL Mechanism", RFC 2831, May 2000. [LDAPDN] Zeilenga, Kurt D. (editor), "LDAP: String Representation of Distinguished Names", draft-ietf-ldapbis-dn-xx.txt, a work in progress. [Protocol] Sermersheim, J., "LDAP: The Protocol", draft-ietf- ldapbis-protocol-xx.txt, a work in progress. [ROADMAP] K. Zeilenga, "LDAP: Technical Specification Road Map", draft-ietf-ldapbis-roadmap-xx.txt, a work in progress. 14. Informative References [RFC2828] Shirey, R., "Internet Security Glossary", RFC 2828, May 2000. [RFC2401] Kent, S. and R. Atkinson, "Security Architecture for the Internet Protocol", RFC 2401, November 1998. 15. Author's Address Roger Harrison Novell, Inc. 1800 S. Novell Place Provo, UT 84606 +1 801 861 2642 roger_harrison@novell.com 16. Full Copyright Statement Copyright (C) The Internet Society (2000). All Rights Reserved. This document and translations of it may be copied and furnished to others, and derivative works that comment on or otherwise explain it or assist in its implementation may be prepared, copied, published and distributed, in whole or in part, without restriction of any kind, provided that the above copyright notice and this paragraph are included on all such copies and derivative works. However, this Harrison Expires September 2003 [Page 21] Authentication Methods for LDAPv3 document itself may not be modified in any way, such as by removing the copyright notice or references to the Internet Society or other Internet organizations, except as needed for the purpose of developing Internet standards in which case the procedures for copyrights defined in the Internet Standards process must be followed, or as required to translate it into languages other than English. The limited permissions granted above are perpetual and will not be revoked by the Internet Society or its successors or assigns. This document and the information contained herein is provided on an "AS IS" basis and THE INTERNET SOCIETY AND THE INTERNET ENGINEERING TASK FORCE DISCLAIMS ALL WARRANTIES, EXPRESS OR IMPLIED, INCLUDING BUT NOT LIMITED TO ANY WARRANTY THAT THE USE OF THE INFORMATION HEREIN WILL NOT INFRINGE ANY RIGHTS OR ANY IMPLIED WARRANTIES OF MERCHANTABILITY OR FITNESS FOR A PARTICULAR PURPOSE. Appendix A. Example Deployment Scenarios The following scenarios are typical for LDAP directories on the Internet, and have different security requirements. (In the following discussion, "sensitive data" refers to information whose disclosure, alteration, destruction, or loss would adversely affect the interests or business of its owner or user. Also note that there may be data that is protected but not sensitive.) This is not intended to be a comprehensive list; other scenarios are possible, especially on physically protected networks. (1) A read-only directory, containing no sensitive data, accessible to "anyone", and TCP connection hijacking or IP spoofing is not a problem. Anonymous authentication, described in section 7, is suitable for this type of deployment, and requires no additional security functions except administrative service limits. (2) A read-only directory containing no sensitive data; read access is granted based on identity. TCP connection hijacking is not currently a problem. This scenario requires data confidentiality for sensitive authentication information AND data integrity for all authentication information. (3) A read-only directory containing no sensitive data; and the client needs to ensure the identity of the directory server and that the directory data is not modified while being returned from the server. A data origin authentication service AND data integrity service are required. (4) A read-write directory, containing no sensitive data; read access is available to "anyone", update access to properly authorized persons. TCP connection hijacking is not currently a problem. This scenario requires data confidentiality for sensitive authentication information AND data integrity for all authentication information. Harrison Expires September 2003 [Page 22] Authentication Methods for LDAPv3 (5) A directory containing sensitive data. This scenario requires data confidentiality protection AND secure authentication. Appendix B. Authentication and Authorization: Definitions and Concepts This appendix defines basic terms, concepts, and interrelationships regarding authentication, authorization, credentials, and identity. These concepts are used in describing how various security approaches are utilized in client authentication and authorization. B.1. Access Control Policy An access control policy is a set of rules defining the protection of resources, generally in terms of the capabilities of persons or other entities accessing those resources. A common expression of an access control policy is an access control list. Security objects and mechanisms, such as those described here, enable the expression of access control policies and their enforcement. Access control policies are typically expressed in terms of access control attributes as described below. B.2. Access Control Factors A request, when it is being processed by a server, may be associated with a wide variety of security-related factors (section 4.2 of [Protocol]). The server uses these factors to determine whether and how to process the request. These are called access control factors (ACFs). They might include source IP address, encryption strength, the type of operation being requested, time of day, etc. Some factors may be specific to the request itself, others may be associated with the connection via which the request is transmitted, others (e.g. time of day) may be "environmental". Access control policies are expressed in terms of access control factors. E.g., a request having ACFs i,j,k can perform operation Y on resource Z. The set of ACFs that a server makes available for such expressions is implementation-specific. B.3. Authentication, Credentials, Identity Authentication credentials are the evidence supplied by one party to another, asserting the identity of the supplying party (e.g. a user) who is attempting to establish an association with the other party (typically a server). Authentication is the process of generating, transmitting, and verifying these credentials and thus the identity they assert. An authentication identity is the name presented in a credential. There are many forms of authentication credentials -- the form used depends upon the particular authentication mechanism negotiated by the parties. For example: X.509 certificates, Kerberos tickets, simple identity and password pairs. Note that an authentication mechanism may constrain the form of authentication identities used with it. Harrison Expires September 2003 [Page 23] Authentication Methods for LDAPv3 B.4. Authorization Identity An authorization identity is one kind of access control factor. It is the name of the user or other entity that requests that operations be performed. Access control policies are often expressed in terms of authorization identities; e.g., entity X can perform operation Y on resource Z. The authorization identity bound to an association is often exactly the same as the authentication identity presented by the client, but it may be different. SASL allows clients to specify an authorization identity distinct from the authentication identity asserted by the client's credentials. This permits agents such as proxy servers to authenticate using their own credentials, yet request the access privileges of the identity for which they are proxying [RFC2222]. Also, the form of authentication identity supplied by a service like TLS may not correspond to the authorization identities used to express a server's access control policy, requiring a server- specific mapping to be done. The method by which a server composes and validates an authorization identity from the authentication credentials supplied by a client is implementation-specific. Appendix C. RFC 2829 Change History This appendix lists the changes made to the text of RFC 2829 in preparing this document. C.0. General Editorial Changes Version -00 - Changed other instances of the term LDAP to LDAPv3 where v3 of the protocol is implied. Also made all references to LDAPv3 use the same wording. - Miscellaneous grammatical changes to improve readability. - Made capitalization in section headings consistent. Version -01 - Changed title to reflect inclusion of material from RFC 2830 and 2251. C.1. Changes to Section 1 Version -01 - Moved conventions used in document to a separate section. C.2. Changes to Section 2 Version -01 Harrison Expires September 2003 [Page 24] Authentication Methods for LDAPv3 - Moved section to an appendix. C.3. Changes to Section 3 Version -01 - Moved section to an appendix. C.4 Changes to Section 4 Version -00 - Changed "Distinguished Name" to "LDAP distinguished name". C.5. Changes to Section 5 Version -00 - Added the following sentence: "Servers SHOULD NOT allow clients with anonymous authentication to modify directory entries or access sensitive information in directory entries." C.5.1. Changes to Section 5.1 Version -00 - Replaced the text describing the procedure for performing an anonymous bind (protocol) with a reference to section 4.2 of RFC 2251 (the protocol spec). Version -01 - Brought text describing procedure for performing an anonymous bind from section 4.2 of RFC 2251 bis. This text will be removed from the draft standard version of that document. C.6. Changes to Section 6. Version -00 Reorganized text in section 6.1 as follows: 1. Added a new section (6.1) titled "Simple Authentication" and moved one of two introductory paragraphs for section 6 into section 6.1. Added sentences to the paragraph indicating: a. simple authentication is not suitable for environments where confidentiality is not available. b. LDAP implementations SHOULD NOT support simple authentication unless confidentiality and data integrity mechanisms are in force. Harrison Expires September 2003 [Page 25] Authentication Methods for LDAPv3 2. Moved first paragraph of section 6 (beginning with "LDAP implementations MUST support authentication with a passwordà") to section on Digest Authentication (Now section 6.2). C.6.1. Changes to Section 6.1. Version -00 Renamed section to 6.2 - Added sentence from original section 6 indicating that the DIGEST-MD5 SASL mechanism is required for all conforming LDAPv3 implementations C.6.2. Changes to Section 6.2 Version -00 - Renamed section to 6.3 - Reworded first paragraph to remove reference to user and the userPassword password attribute Made the first paragraph more general by simply saying that if a directory supports simple authentication that the simple bind operation MAY performed following negotiation of a TLS ciphersuite that supports confidentiality. - Replaced "the name of the user's entry" with "a DN" since not all bind operations are performed on behalf of a "user." - Added Section 6.3.1 heading just prior to paragraph 5. - Paragraph 5: replaced "The server" with "DSAs that map the DN sent in the bind request to a directory entry with a userPassword attribute." C.6.3. Changes to section 6.3. Version -00 - Renamed to section 6.4. C.7. Changes to section 7. none C.7.1. Changes to section 7.1. Version -00 - Clarified the entity issuing a certificate by moving the phrase "to have issued the certificate" immediately after "Certification Authority." C.8. Changes to section 8. Harrison Expires September 2003 [Page 26] Authentication Methods for LDAPv3 Version -00 - Removed the first paragraph because simple authentication is covered explicitly in section 6. - Added section 8.1. heading just prior to second paragraph. - Added section 8.2. heading just prior to third paragraph. - Added section 8.3. heading just prior to fourth paragraph. Version -01 - Moved entire section 8 of RFC 2829 into section 3.4 (Using SASL for Other Security Services) to bring material on SASL mechanisms together into one location. C.9. Changes to section 9. Version -00 - Paragraph 2: changed "EXTERNAL mechanism" to "EXTERNAL SASL mechanism." - Added section 9.1. heading. - Modified a comment in the ABNF from "unspecified userid" to "unspecified authz id". - Deleted sentence, "A utf8string is defined to be the UTF-8 encoding of one or more ISO 10646 characters," because it is redundant. - Added section 9.1.1. heading. - Added section 9.1.2. heading. Version -01 - Moved entire section 9 to become section 3.5 so that it would be with other SASL material. C.10. Changes to Section 10. Version -00 - Updated reference to cracking from a week of CPU time in 1997 to be a day of CPU time in 2000. - Added text: "These ciphersuites are NOT RECOMMENDED for use... and server implementers SHOULD" to sentence just prior the second list of ciphersuites. Harrison Expires September 2003 [Page 27] Authentication Methods for LDAPv3 - Added text: "and MAY support other ciphersuites offering equivalent or better protection," to the last paragraph of the section. C.11. Changes to Section 11. Version -01 - Moved to section 3.6 to be with other SASL material. C.12. Changes to Section 12. Version -00 - Inserted new section 12 that specifies when SASL protections begin following SASL negotiation, etc. The original section 12 is renumbered to become section 13. Version -01 - Moved to section 3.7 to be with other SASL material. C.13. Changes to Section 13 (original section 12). None Appendix D. RFC 2830 Change History This appendix lists the changes made to the text of RFC 2830 in preparing this document. D.0. General Editorial Changes - Material showing the PDUs for the Start TLS response was broken out into a new section. - The wording of the definition of the Start TLS request and Start TLS response was changed to make them parallel. NO changes were made to the ASN.1 definition or the associated values of the parameters. - A separate section heading for graceful TLS closure was added for parallelism with section on abrupt TLS closure. Appendix E. RFC 2251 Change History This appendix lists the changes made to the text of RFC 2251 in preparing this document. E.0. General Editorial Changes - All material from section 4.2 of RFC 2251 was moved into this document. Harrison Expires September 2003 [Page 28] Authentication Methods for LDAPv3 - A new section was created for the Bind Request - Section 4.2.1 of RFC 2251 (Sequencing Bind Request) was moved after the section on the Bind Response for parallelism with the presentation of the Start TLS operations. The section was also subdivided to explicitly call out the various effects being described within it. - All SASL profile information from RFC 2829 was brought within the discussion of the Bind operation (primarily sections 4.4 - 4.7). Appendix F. Change History to Combined Document F.1. Changes for draft-ldap-bis-authmeth-02 General - Added references to other LDAP standard documents, to sections within the document, and fixed broken references. - General editorial changesùpunctuation, spelling, formatting, etc. Section 1. - Added glossary of terms and added sub-section headings Section 2. - Clarified security mechanisms 3, 4, & 5 and brought language in line with IETF security glossary. Section 3. - Brought language in requirement (3) in line with security glossary. - Clarified that information fetched prior to initiation of TLS negotiation must be discarded -Clarified that information fetched prior to initiation of SASL negotiation must be discarded - Rewrote paragraph on SASL negotiation requirements to clarify intent Section 4.4. - Added stipulation that sasl choice allows for any SASL mechanism not prohibited by this document. (Resolved conflict between this statement and one that prohibited use of ANONYMOUS and PLAIN SASL mechanisms.) Harrison Expires September 2003 [Page 29] Authentication Methods for LDAPv3 Section 5.3.6 - Added a.x.bar.com to wildcard matching example on hostname check. Section 6 - Added LDAP Association State Transition Tables to show the various states through which an LDAP association may pass along with the actions and decisions required to traverse from state to state. Appendix A - Brought security terminology in line with IETF security glossary throughout the appendix. F.2. Changes for draft-ldap-bis-authmeth-03 General - Added introductory notes and changed title of document and references to conform to WG chair suggestions for the overall technical specification. - Several issues--G.13, G.14, G.16, G.17--were resolved without requiring changes to the document. Section 3 - Removed reference to /etc/passwd file and associated text. Section 4 - Removed sections 4.1, 4.2 and parts of section 4.3. This information was being duplicated in the protocol specification and will now reside there permanently. Section 4.2 - changed words, "not recommended" to "strongly discouraged" Section 4.3 - Based on ldapbis WG discussion at IETF52 two sentences were added indicating that clients SHOULD NOT send a DN value when binding with the sasl choice and servers SHALL ignore any value received in this circumstance. - Section 8.3.1 - Generalized the language of this section to not refer to any specific password attribute or to refer to the directory entry as a "user" entry. Harrison Expires September 2003 [Page 30] Authentication Methods for LDAPv3 Section 11 - Added security consideration regarding misuse of unauthenticated access. - Added security consideration requiring access control to be applied only to authenticated users and recommending it be applied when reading sensitive information or updating directory information. F.3. Changes for draft-ldap-bis-authmeth-04 General - Changed references to use [RFCnnnn] format wherever possible. (References to works in progress still use [name] format.) - Various edits to correct typos and bring field names, etc. in line with specification in [Protocol] draft. - Several issues--G.13, G.14, G.16, G.17--were resolved without requiring changes to the document. Section 4.4.1. - Changed ABNF grammar to use productions that are like those in the model draft. Section 5 - Removed sections 5.1, 5.2, and 5.4 that will be added to [Protocol]. Renumbered sections to accommodate this change. - Section 6 - Reviewed LDAP Association State table for completeness and accuracy. Renumbered actions A3, A4, and A5 to be A5, A3, and A4 respectively. Re-ordered several lines in the table to ensure that actions are in ascending order (makes analyzing the table much more logical). Added action A2 to several states where it was missing and valid. Added actions A7 and A8 placeholders to states S1, S2, S4 and S5 pending resolution of issue G.28. Section 11 - Modified security consideration (originally added in -03) requiring access control to be applied only to authenticated users. This seems nonsensical because anonymous users may have access control applied to limit permissible actions. - Section 13 Harrison Expires September 2003 [Page 31] Authentication Methods for LDAPv3 - Verified all normative references and moved informative references to a new section 14. F.4. Changes for draft-ldap-bis-authmeth-05 General - General editory changes to fix punctuation, spelling, line length issues, etc. - Verified and updated intra- and inter-document references throughout. - Document-wide review for proper usage of RFC 2119 keywords with several changes to correct improper usage. Abstract - Updated to match current contents of documents. This was needed due to movement of material on Bind and Start TLS operations to [Protocol] in this revision. Section 3. - Renamed section to "Rationale for LDAPv3 Security Mechanisms" and removed text that did not support this theme. Part of the motivation for this change was to remove the implication of the previous section title, "Required Security Mechanisms", and other text found in the section that everything in the section was a requirement - Information from several removed paragraphs that describe deployment scenarios will be added Appendix A in the next revision of the draft. - Paragraph beginning, " If TLS is negotiated, the client MUST discard all information..." was moved to section 5.1.7 and integrated with related material there. - Paragraph beginning, "If a SASL security layer is negotiated..." was moved to section 4.2 Section 4.l. - Changed wording of first paragraph to clarify meaning. Section 4.2. - Added paragraph from section 3 of -04 beginning, "If a SASL security layer is negotiated..." Section 4.3.3. - Renamed to "Other SASL Mechanisms" and completely rewrote the section (one sentence) to generalize the treatment of SASL mechanisms not explicitly mentioned in this document. Section 4.4.1. Harrison Expires September 2003 [Page 32] Authentication Methods for LDAPv3 - Added paragraph beginning, "The dnAuthzID choice allows client applications..." to clarify whether DN form authorization identities have to also have a corresponding directory entry. This change was based on editor's perception of WG consensus. - Made minor clarifying edits in the paragraph beginning, "The uAuthzID choice allows for compatibility..." Section 5.1.1. - Made minor clarifying edits in the last paragraph of the section. Section 5.1.7. - Wording from section 3 paragraph beginning " If TLS is negotiated, the client MUST discard all information..." was moved to this section and integrated with existing text. Section 5.2. - Changed usage of "TLS connection" to "TLS session" throughout. - Removed empty section 5.2.1 and renumbered sections it had previously contained. Section 8. - Added introductory paragraph at beginning of section. Section 8.1. - Changed term "data privacy" to "data confidentiality" to be consistent with usage in rest of document. Section 8.2. - Changed first paragraph to require implementations that implement *password-based* authentication to implement and support DIGEST-MD5 SASL authentication. Section 11. - First paragraph: changed "session encryption" to "session confidentiality protection" to be consistent with usage in rest of document. Appendix A. - Began changes to incorporate information on deployment scenarios removed from section 3. Harrison Expires September 2003 [Page 33] Authentication Methods for LDAPv3 Appendix G. Issues to be Resolved This appendix lists open questions and issues that need to be resolved before work on this document is deemed complete. G.1. Section 1 lists 6 security mechanisms that can be used by LDAP servers. I'm not sure what mechanism 5, "Resource limitation by means of administrative limits on service controls" means. Status: resolved. Changed wording to "administrative service limits" to clarify meaning. G.2. Section 2 paragraph 1 defines the term, "sensitive." Do we want to bring this term and other security-related terms in alignment with usage with the IETF security glossary (RFC 2828)? Status: resolved. WG input at IETF 51 was that we should do this, so the appropriate changes have been made. G.3. Section 2, deployment scenario 2: What is meant by the term "secure authentication function?" Status: resolved. Based on the idea that a "secure authentication function" could be provided by TLS, I changed the wording to require data confidentiality for sensitive authentication information and data integrity for all authentication information. G.4. Section 3, deployment scenario 3: What is meant by the phrase, "directory data is authenticated by the server?" Status: resolved. I interpreted this to mean the ability to ensure the identity of the directory server and the integrity of the data sent from that server to the client, and explictly stated such. G.5. Section 4 paragraph 3: What is meant by the phrase, "this means that either this data is useless for faking authentication (like the Unix "/etc/passwd" file format used to be)?" Status: resolved. Discussion at IETF 52 along with discussions with the original authors of this material have convinced us that this reference is simply too arcane to be left in place. In -03 the text has been modified to focus on the need to either update password information in a protected fashion outside of the protocol or to Harrison Expires September 2003 [Page 34] Authentication Methods for LDAPv3 update it in session well protected against snooping, and the reference to /etc/passwd has been removed. G.6. Section 4 paragraph 7 begins: "For a directory needing session protection..." Is this referring to data confidentiality or data integrity or both? Status: resolved. Changed wording to say, "For a directory needing data security (both data integrity and data confidentiality)..." G.7. Section 4 paragraph 8 indicates that "information about the server fetched fetched prior to the TLS negotiation" must be discarded. Do we want to explicitly state that this applies to information fetched prior to the *completion* of the TLS negotiation or is this going too far? Status: resolved. Based on comments in the IETF 51 LDAPBIS WG meeting, this has been changed to explicitly state, "fetched prior to the initiation of the TLS negotiation..." G.8. Section 4 paragraph 9 indicates that clients SHOULD check the supportedSASLMechanisms list both before and after a SASL security layer is negotiated to ensure that they are using the best available security mechanism supported mutually by the client and server. A note at the end of the paragraph indicates that this is a SHOULD since there are environments where the client might get a list of supported SASL mechanisms from a different trusted source. I wonder if the intent of this could be restated more plainly using one of these two approaches (I've paraphrased for the sake of brevity): Approach 1: Clients SHOULD check the supportedSASLMechanisms list both before and after SASL negotiation or clients SHOULD use a different trusted source to determine available supported SASL mechanisms. Approach 2: Clients MUST check the supportedSASLMechanisms list both before and after SASL negotiation UNLESS they use a different trusted source to determine available supported SASL mechanisms. Status: resolved. WG input at IETF 51 was that Approach 1 was probably best. I ended up keeping the basic structure similar to the original to meet this intent. G.9. Harrison Expires September 2003 [Page 35] Authentication Methods for LDAPv3 Section 6.3.1 states: "DSAs that map the DN sent in the bind request to a directory entry with a userPassword attribute will... compare [each value in the named user's entry]... with the presented password." This implies that this applies only to user entries with userPassword attributes. What about other types of entries that might allow passwords and might store in the password information in other attributes? Do we want to make this text more general? Status: resolved in -03 draft by generalizing section 8.3.1 to not refer to any specific password attribute and by removing the term "user" in referring to the directory entry specified by the DN in the bind request. G.10 userPassword and simple bind We need to be sure that we don't require userPassword to be the only attribute used for authenticating via simple bind. (See 2251 sec 4.2 and authmeth 6.3.1. Work with Jim Sermersheim on resolution to this. On publication state something like: "This is the specific implementation of what we discussed in our general reorg conversation on the list." (Source: Kurt Zeilenga) Status: resolved in -03 draft by generalizing section 8.3.1 to not refer to any specific password attribute and by removing the term "user" in referring to the directory entry specified by the DN in the bind request. G.11. Meaning of LDAP Association The original RFC 2830 uses the term "LDAP association" in describing a connection between an LDAP client and server regardless of the state of TLS on that connection. This term needs to be defined or possibly changed. Status: resolved. at IETF 51 Bob Morgan indicated that the term "LDAP association" was intended to distinguish the LDAP-level connection from the TLS-level connection. This still needs to be clarified somewhere in the draft. Added "LDAP association" to a glossary in section 1. G.12. Is DIGEST-MD5 mandatory for all implementations? Reading 2829bis I think DIGEST-MD5 is mandatory ONLY IF your server supports password based authentication...but the following makes it sound mandatory to provide BOTH password authentication AND DIGEST- MD5: "6.2. Digest authentication LDAP implementations MUST support authentication with a password using the DIGEST-MD5 SASL mechanism for password protection, as defined in section 6.1." The thing is for acl it would be nice (though not critical) to be Harrison Expires September 2003 [Page 36] Authentication Methods for LDAPv3 able to default the required authentication level for a subject to a single "fairly secure" mechanism--if there is no such mandatory authentication scheme then you cannot do that. (Source: Rob Byrne) Status: resolved. -00 version of the draft added a sentence at the beginning of section 8.2 stating that LDAP server implementations must support this method. G.13. Ordering of authentication levels requested Again on the subject of authentication level, is it possible to define an ordering on authentication levels which defines their relative "strengths" ? This would be useful in acl as you could say things like"a given aci grants access to a given subject at this authentication level AND ABOVE". David Chadwick raised this before in the context of denying access to a subject at a given authentication level, in which case he wanted to express "deny access to this subject at this authentication level AND TO ALL IDENTITIES AUTHENTICATED BELOW THAT LEVEL". (Source: Rob Byrne) Status: out of scope. This is outside the scope of this document and will not be addressed. G.14. Document vulnerabilities of various mechanisms While I'm here...in 2829, I think it would be good to have some comments or explicit reference to a place where the security properties of the particular mandatory authentication schemes are outlined. When I say "security properties" I mean stuff like "This scheme is vulnerable to such and such attacks, is only safe if the key size is > 50, this hash is widely considered the best, etc...". I think an LDAP implementor is likely to be interested in that information, without having to wade through the security RFCs. (Source: Rob Byrne) Status: out of scope. This is outside the scope of this document and will not be addressed. G.15. Include a StartTLS state transition table The pictoral representation it is nominally based on is here (URL possibly folded): http://www.stanford.edu/~hodges/doc/LDAPAssociationStateDiagram- 1999-12-14.html (Source: Jeff Hodges) Status: In Process. Table provided in -03. Review of content for accuracy in -04. Additional review is needed, plus comments from WG members indicate that additional description of each state's meaning would be helpful. Harrison Expires September 2003 [Page 37] Authentication Methods for LDAPv3 G.16. Empty sasl credentials question I spent some more time looking microscopically at ldap-auth-methods and ldap-ext-tls drafts. The drafts say that the credential must have the form dn:xxx or u:xxx or be absent, and although they don't say what to do in the case of an empty octet string I would say that we could send protocolError (claim it is a bad PDU). There is still the question of what to do if the credential is 'dn:' (or 'u:') followed by the empty string. (Source: ariel@columbia.edu via Jeff Hodges) Status: resolved. Kurt Zeilenga indicated during ldapbis WG discussion at IETF 52 that SASL AuthzID credentials empty and absent are equivalent in the latest SASL ID. This resolves the issue. G.17. Hostname check from MUST to SHOULD? I am uneasy about the hostname check. My experience from PKI with HTTP probably is a contributing factor; we have people using the short hostname to get to a server which naturally has the FQDN in the certificate, no end of problems. I have a certificate on my laptop which has the FQDN for the casse when the system is on our Columbia network with a fixed IP; when I dial in however, I have some horrible dialup name, and using the local https server becomes annoying. Issuing a certificate in the name 'localhost' is not a solution! Wildcard match does not solve this problem. For these reasons I am inclined to argue for 'SHOULD' instead of 'MUST' in paragraph... Also, The hostname check against the name in the certificate is a very weak means of preventing man-in-the-middle attacks; the proper solution is not here yet (SecureDNS or some equivalent). Faking out DNS is not so hard, and we see this sort of thing in the press on a pretty regular basis, where site A hijacks the DNS server for site B and gets all their requests. Some mention of this should be made in the draft. (Source: ariel@columbia.edu via Jeff Hodges) Status: resolved. Based on discussion at IETF 52 ldapbis WG meeting, this text will stand as it is. The check is a MUST, but the behavior afterward is a SHOULD. This gives server implementations the room to maneuver as needed. G.18. Must SASL DN exist in the directory? If the 'dn:' form of sasl creds is used, is it the intention of the draft(ers) that this DN must exist in the directory and the client will have the privileges associated with that entry, or can the server map the sasl DN to perhaps some other DN in the directory, in an implementation-dependent fashion? We already know that if *no* sasl credentials are presented, the DN or altname in the client certificate may be mapped to a DN in an implementation-dependent fashion, or indeed to something not in the Harrison Expires September 2003 [Page 38] Authentication Methods for LDAPv3 directory at all. (Right?) (Source: ariel@columbia.edu via Jeff Hodges) Status: resolved. (11/12/02)Based on my research I propose that the DN MUST exist in the directory when the DN form of sasl creds is used. I have made this proposal to the ldapbis mailing list. (11/21/02) Feedback from mailing list has proposed removing this paragraph entirely because (1) explicit assertion of authorization identity should only be done when proxying (2) mapping of the asserted authorization identity is implementation specific and policy driven [SASL] section 4.2, and (3) keeping this paragraph is not required for interoperability. G.19. DN used in conjunction with SASL mechanism We need to specify whether the DN field in Bind operation can/cannot be used when SASL mechanism is specified. (source: RL Bob) Status: resolved. (-03) Based on ldapbis WG discussion at IETF52 two sentences were added to section 4.3 indicating that clients SHOULD NOT send a DN value when binding with the sasl choice and servers SHALL ignore any value received in this circumstance. During edits for -04 version of draft it was noted that [Protocol] section 4.2 conflicts with this draft. The editor of [Protocol] has been notified of the discrepancy, and they have been handled. G.20. Bind states Differences between unauthenticated and anonymous. There are four states you can get into. One is completely undefined (this is now explicitly called out in [Protocol]). This text needs to be moved from [Protocol] to this draft. (source: Jim Sermersheim) Status: Resolved. There are four states: (1) no name, no password (anon); (2) name, no password (anon); (3) no name, password (invalid); (4) name, password (simple bind). States 1, 2, and 4 are called out in [AuthMeth]. State 3 is called out in [Protocol]; this seems appropriate based on review of alternatives. G.21. Misuse of unauthenticated access Add a security consideration that operational experience shows that clients can misuse unauthenticated access (simple bind with name but no password). Servers SHOULD by default reject authentication requests that have a DN with an empty password with an error of invalidCredentials. (Source: Kurt Zeilenga and Chris Newman (Sun)) Status: Resolved. Added to security considerations in û03. G.22. Need to move StartTLS protocol information to [Protocol] Status: Resolved. Removed Sections 5.1, 5.2, and 5.4 for -04 and they are [Protocol] -11. Harrison Expires September 2003 [Page 39] Authentication Methods for LDAPv3 G.23. Split Normative and Non-normative references into separate sections. Status: Resolved. Changes made in -04 G.24. What is the authentication state if a Bind operation is abandoned? Status: In process. (11/12/02) This text was suggested to be added to [Protocol] -11 to cover what happens if a bind operation is abandoned: "If a server receives an Abandon request for a Bind operation, the server SHOULD leave the connection in the anonymous state. Clients that abandon a Bind operation MUST rebind after abandoning the Bind request in order to have a known authentication state on the connection." (11/21/02) Jim Sermersheim prposed the following wording on the ldapbis mail list: "Authentication from earlier binds are subsequently ignored. A failed or abandoned Bind Operation has the effect of leaving the connection in an anonymous state. Clients MUST rebind after abandoning a bind operation in order to determine a known authentication state." Once this is resolved in [Protocol] the state table in section 6 of [AuthMeth] will need to be updated to reflect the consensus wording. G.25. Difference between checking server hostname and server's canonical DNS name in Server Identity Check? Section 5.1.6: I now understand the intent of the check (prevent man-in-the-middle attacks). But what is the subtle difference between the "server hostname" and the "server's canonical DNS name"? (Source: Tim Hahn) Status: In Process. (11/12/02) Sent suggested wording change to this paragraph to the ldapbis mail list and also asked for opinion as to whether we should discuss the distinction between server DNS hostname and server canonical DNS hostname in [AuthMeth]. (11/21/02): RL Bob Morgan will provide wording that allows derivations of the name that are provided securely. 6.26. Server Identity Check using servers located via SRV records Section 5.1.6: What should be done if the server was found using SRV records based on the "locate" draft/RFC? (Source: Tim Hahn). Status: Resolved. Section 5 of draft-ietf-ldapext-locate-08 specifically calls out how the server identity should be performed if the server is located using the method defined in that draft. Harrison Expires September 2003 [Page 40] Authentication Methods for LDAPv3 This is the right location for this information, and the coverage appears to be adequate. G.27 Inconsistency in effect of TLS closure on LDAP association. Section 5.4.1 of authmeth -03 (section 4.1 of RFC2830) states that TLS closure alert will leave the LDAP association intact. Contrast this with Section 5.5.2 (section 5.2 of RFC2830) that says that the closure of the TLS connection MUST cause the LDAP association to move to an anonymous authentication. Status: in process. (11/12/02) This is actually a [Protocol] issue because these sections have now been moved to [Protocol] -11. I have proposed the following text for Section 5.4.1 of [AuthMeth] -03 (section 4.13.3.1 of [Protocol]) to resolve this apparent discrepancy: "Either the client or server MAY terminate the TLS connection on an LDAP association by sending a TLS closure alert. The LDAP connection remains open for further communication after TLS closure occurs although the authentication state of the LDAP connection is affected (see [AuthMeth] section 5.2.2). (11/21/02): resolution to this is expected in [Protocol] -12 G.28 Ordering of external sources of authorization identities Section 4.3.2 implies that external sources of authorization identities other than TLS are permitted. What is the behavior when two external sources of authentication credentials are available (e.g. TLS and IPsec are both present (is this possible?)) and a SASL EXTERNAL Bind operation is performed? Status: resolved. 11/20/02: Resolved by Section 4.2 of [SASL] which states that the decision to allow or disallow the asserted identity is based on an implementation defined policy. G.29 Rewrite of Section 10, TLS Ciphersuites This section contains anachronistic references and needs to be updated/rewritten in a way that provides useful guidance for future readers in a way that will transcend the passage of time. G.30 Update to Appendix A, Example Deployment Scenarios This section needs to be updated to indicate which security mechanisms and/or combinations of security mechanisms described elsewhere in the document can provide the types of protections suggested in this appendix. Harrison Expires September 2003 [Page 41]