Internet-Draft | Best practices for password hashing and storage | May 2020 |
Whited | Expires 7 November 2020 | [Page] |
This document outlines best practices for handling user passwords and other authenticator secrets in client-server systems making use of SASL.¶
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Following best practices when hashing and storing passwords for use with SASL impacts a great deal more than just a user's identity. It also affects usability, backwards compatibility, and interoperability by determining what authentication and authorization mechanisms can be used.¶
Various security-related terms are to be understood in the sense defined in [RFC4949]. Some may also be defined in [NISTSP63-3] Appendix A.1 and in [NISTSP132] section 3.1.¶
Throughout this document the term "password" is used to mean any password, passphrase, PIN, or other memorized secret.¶
Other common terms used throughout this document include:¶
The key words "MUST", "MUST NOT", "REQUIRED", "SHALL", "SHALL NOT", "SHOULD", "SHOULD NOT", "RECOMMENDED", "NOT RECOMMENDED", "MAY", and "OPTIONAL" in this document are to be interpreted as described in BCP 14 [RFC2119] [RFC8174] when, and only when, they appear in all capitals, as shown here.¶
For clients and servers that support password based authentication using SASL [RFC4422] it is RECOMMENDED that the following mechanisms be implemented:¶
System entities SHOULD NOT invent their own mechanisms that have not been standardized by the IETF or another reputable standards body. Similarly, entities SHOULD NOT implement any mechanism with a usage status of "OBSOLETE", "MUST NOT be used", or "LIMITED" in the IANA SASL Mechanisms Registry [IANA.sasl.mechanisms].¶
The SASL mechanisms discussed in this document do not negotiate a security layer. Because of this a strong security layer such as TLS [RFC8446] MUST be negotiated before SASL mechanisms can be advertised or negotiated.¶
Clients often maintain a list of preferred SASL mechanisms, generally ordered by perceived strength to enable strong authentication. To prevent downgrade attacks by a malicious actor that has successfully man in the middled a connection, or compromised a trusted server's configuration, clients SHOULD implement "mechanism pinning". That is, after the first successful authentication with a strong mechanism, clients SHOULD make a record of the authentication and thereafter only advertise and use mechanisms of equal or higher perceived strength.¶
The following mechanisms are ordered by their perceived strength from strongest to weakest with mechanisms of equal strength on the same line. The remainder of this section is merely informative. In particular this example does not imply that mechanisms in this list should or should not be implemented.¶
The EXTERNAL mechanism defined in [RFC4422] appendix A is placed at the top of the list. However, its perceived strength depends on the underlying authentication protocol. In this example, we assume that TLS [RFC8446] services are being used which can provide a strong authenticator assurance level.¶
The channel binding ("-PLUS") variants of SCRAM [RFC5802] are listed above their non-channel binding cousins, but may not always be available depending on the type of channel binding data available to the SASL negotiator.¶
The PLAIN mechanism sends the username and password in plain text, but does allow for the use of a strong key derivation function for the stored version of the password on the server.¶
Finally, the DIGEST-MD5 and CRAM-MD5 mechanisms are listed last because they use weak hashes and ciphers and prevent the server from storing passwords using a strong key derivation function. For a list of problems with DIGEST-MD5 see [RFC6331].¶
Clients SHOULD always store authenticators in a trusted and encrypted keystore such as the system keystore, or an encrypted store created specifically for the clients use. They SHOULD NOT store authenticators as plain text.¶
If clients know that they will only ever authenticate using a mechanism such as SCRAM [RFC5802] where the original password is not needed after the first authentication attempt they SHOULD store the SCRAM bits or the hashed and salted password instead of the original password. However, if backwards compatibility with servers that only support the PLAIN mechanism or other mechanisms that require using the original password is required, clients MAY choose to store the original password so long as an appropriate keystore is used.¶
Servers MUST NOT support any mechanism that would require authenticators to be stored in such a way that they could be recovered in plain text from the stored information. This includes mechanisms that store authenticators using reversable encryption, obsolete hashing mechanisms such as MD5, and hashes that are unsuitable for use with authenticators such as SHA256.¶
Servers MUST always store passwords only after they have been salted and hashed. A distinct salt SHOULD be used for each user, and each SCRAM family supported. Salts MUST be generated using a cryptographically secure random number generator. The salt MAY be stored in the same datastore as the password. If it is stored alongside the password, it SHOULD be combined with a pepper stored in the application configuration, an environment variable, or some location other than the datastore containing the salts.¶
The following restrictions MUST be observed when generating salts and peppers:¶
Parameter | Value |
---|---|
Minimum Salt Length | 16 bytes |
Minimum Pepper Length | 32 bytes |
When authenticating using PLAIN or similar mechanisms that involve transmitting the original password to the server the password MUST be hashed and compared against the salted and hashed password in the database using a constant time comparison.¶
Each time a password is changed a new random salt MUST be created and the iteration count and pepper (if applicable) MUST be updated to the latest value required by server policy.¶
If a pepper is used, consideration should be taken to ensure that it can be easily rotated. For example, multiple peppers could be stored. New passwords and reset passwords would use the newest pepper and a hash of the pepper using a cryptographically secure hash function such as SHA256 could then be stored in the database next to the salt so that future logins can identify which pepper in the list was used. This is just one example, pepper rotation schemes are outside the scope of this document.¶
When properly configured, the following commonly used KDFs create suitable password hash results for server side storage. The recommendations in this section may change depending on the hardware being used and the security level required for the application.¶
With all KDFs proper tuning is required to ensure that it meets the needs of the specific application or service. For persistent login an iteration count or work factor that adds approximately a quarter of a second to login may be an acceptable tradeoff since logins are relatively rare. By contrast, verification tokens that are generated many times per second may need to use a much lower work factor.¶
Argon2 [ARGON2ESP] is the 2015 winner of the Password Hashing Competition and has been recomended by OWASP for password hashing.¶
Security considerations, test vectors, and parameters for tuning argon2 can be found in [I-D.irtf-cfrg-argon2]. They are copied here for easier reference.¶
Parameter | Value |
---|---|
Degree of parallelism (p) | 1 |
Memory size (m) | 32*1024 |
Number of iterations (t) | 1 |
Algorithm type (y) | Argon2id (2) |
bcrypt [BCRYPT] is a Blowfish-based KDF that is the current OWASP recommendation for password hashing.¶
Parameter | Value |
---|---|
Recommended Cost | 12 |
Maximum Password Length | 64 |
PBKDF2 [RFC8018] is used by the SCRAM [RFC5802] family of SASL mechanisms.¶
Parameter | Value |
---|---|
Minimum iteration count (c) | 10,000 |
Hash | SHA256 |
Output length (dkLen) | 64 (or length of chosen hash, hLen) |
The [SCRYPT] KDF is designed to be memory-hard and sequential memory-hard to prevent against custom hardware based attacks.¶
Security considerations, test vectors, and further notes on tuning scrypt may be found in [RFC7914].¶
Parameter | Value |
---|---|
N | 32768 (N=2^15) |
r | 8 |
p | 1 |
Before any other password complexity requirements are checked, the preparation and enforcement steps of the OpaqueString profile of [RFC8265] SHOULD be applied (for more information see the Internationalization Considerations section). Entities SHOULD enforce a minimum length of 8 characters for user passwords. If using a mechanism such as PLAIN where the server performs hashing on the original password, a maximum length between 64 and 128 characters MAY be imposed to prevent denial of service (DoS) attacks. Entities SHOULD NOT apply any other password restrictions.¶
In addition to these password complexity requirements, servers SHOULD maintain a password blacklist and reject attempts by a claimant to use passwords on the blacklist during registration or password reset. The contents of this blacklist are a matter of server policy. Some common recommendations include lists of common passwords that are not otherwise prevented by length requirements, passwords present in known breaches (when paired with the same email or other uniquely identifying information) to prevent reuse of compromised passwords, and password that match commonly used patterns such as "any single repeated character".¶
The PRECIS framework (Preparation, Enforcement, and Comparison of Internationalized Strings) defined in [RFC8264] is used to enforce internationalization rules on strings and to prevent common application security issues arrising from allowing the full range of Unicode codepoints in usernames, passwords, and other identifiers. The OpaqueString profile of [RFC8265] is used in this document to ensure that codepoints in passwords are treated carefully and consistently. This ensures that users typing certain characters on different keyboards that may provide different versions of the same character will still be able to log in. For example, some keyboards may output the full-width version of a character while other keyboards output the half-width version of the same character. The Width Mapping rule of the OpaqueString profile addresses this and ensures that comparison succeeds and the claimant is able to be authenticated.¶
This document contains recommendations that are likely to change over time. It should be reviewed regularly to ensure that it remains accurate and up to date. Many of the recommendations in this document were taken from [OWASP.CS.passwords], [NISTSP63b], and [NISTSP132].¶
The "-PLUS" variants of SCRAM [RFC5802] support channel binding to their underlying security layer, but lack a mechanism for negotiating what type of channel binding to use. In [RFC5802] the tls-unique [RFC5929] channel binding mechanism is specified as the default, and it is therefore likely to be used in most applications that support channel binding. However, in the absence of the TLS extended master secret fix [RFC7627] and the renegotiation indication TLS extension [RFC5746] the tls-unique and tls-server-endpoint channel binding data can be forged by an attacker that can MITM the connection. Before advertising a channel binding SASL mechanism, entities MUST ensure that both the TLS extended master secret fix and the renegotiation indication extension are in place and that the connection has not been renegotiated.¶
For TLS 1.3 [RFC8446] no channel binding types are currently defined. Channel binding SASL mechanisms MUST NOT be advertised or negotiated over a TLS 1.3 channel until such types are defined.¶
This document has no actions for IANA.¶
The author would like to thank the civil servants at the National Institute of Standards and Technology for their work on the Special Publications series. U.S. executive agencies are an undervalued national treasure, and they deserve our thanks.¶
Thanks also to Cameron Paul and Thomas Copeland for their reviews and suggestions.¶