From: jose [mailto:jose-bounces@xxxxxxxx] On Behalf Of Richard Barnes I think I may have erred by trying to write a treatise on which algorithms are vulnerable :) Here's some updated text, trying to be more concise. Jim: Your points about SHA-256 vs. SHA-512/256 and SHA-256 vs. SHA-3 don't really apply, since JOSE hasn't defined algorithm identifiers for SHA-512/256 or SHA-3. [JLS] Richard – are you planning to update this text when (not if) they are defined? If not then this is still part of the problem even if currently not constrained. The same could also be said to be not a problem for all of the ECDSA algorithms since there is only one hash defined of any given length. (I will ignore the really fun problem for DSA and ECDSA where there is a modulus operation that occurs on the hash value thus creating collisions within the same hash function and making matching of hash function lengths and key lengths of primary importance.) However, as these will almost certainly be defined in the future, they merit inclusion in the potential problems. I believe that this should be included in the discussion as it is much easier to do than to break the mask function of RSA. (Breaking the same hash function twice is very non-trival, having two hash functions that produce the same length hash is much easier.)
In some usages of JWS, there is a risk of algorithm substitution attacks, in which an attacker can use an existing signature value with a different signature algorithm to make it appear that a signer has signed something that he actually has not. These attacks have been discussed in detail in the context of CMS {{RFC 6211}}. The risk arises when all of the following are true:
* Given an existing signature, an attacker can find another payload that produces the same signature value with a weaker algorithm * In particular, the payload crafted by the attacker is valid in a given application-layer context For example, suppose a verifier is willing to accept both "PS256" and "PS384" as "alg" values, and a signer creates a signature using "PS256". If the attacker can craft a payload that results in the same signature with SHA-256 as the signature with SHA-384 of the legitimate payload, then the "PS256" signature over the bogus payload will be the same as the "PS384" signature over the legitimate payload. There are several ways for an application using JOSE to mitigate algorithm substitution attacks The simplest mitigation is to not accept signatures using vulnerable algorithms: Algorithm substitution attacks do not arise for all signature algorithms. The only algorithms defined in JWA {{I-D.ietf-jose-json-web-algorithms}} that may be vulnerable to algorithm substitution attacks is RSA-PSS ("PS256", etc.). An implementation that does not support RSA-PSS is not vulnerable to algorithm substitution attacks. (Obviously, if other algorithms are added, then they may introduce new risks.) Without restricting algorithms, there are also mitigations at the JOSE and application layer: At the level of JOSE, an application could require that the "alg" parameter be carried in the protected header. (This is the approach taken by RFC 6211.) The application could also include a field reflecting the algorithm in the application payload, and require that it be matched with the "alg" parameter during verification. (This is the approach taken by PKIX {{RFC5280}}.) Of these mitigations, the only sure solution is the first, not to accept vulnerable algorithms. Signing over the "alg" parameter (directly or indirectly) only makes the attacker's work more difficult, by requiring that the bogus payload also contain bogus information about the signing algorithm. They do not prevent attack by a sufficiently powerful attacker. |