I agree with Daniel that I’d be a bit wary of assuming that this could never be exploited. For example, a server-side web app that signs DPoP proofs on behalf of client-side Javascript (to keep the key safe on the server) and reuses the key for different users could be a risk.
IMO this is another symptom of the general issue of using signatures for authentication - they are too strong for the job. The fact that a signature is equally valid to all parties and at all times means you have to be very careful to include enough context in the signature calculation to ensure all these kinds of attacks are eliminated. And you have to ensure that all RSes check the context. Contrast that to my suggestion to use ECDH [1], which was already immune to such attacks by including the access token in the key derivation step. (And in such a way that requires no additional data on the wire and is almost impossible for the RS not to verify). Even without including the access token in the KDF, the attack could only happen if the client reused its key and the RS reused a challenge key pair. Macaroon access tokens [2] are also immune to this attack, as in that case the constraints that go in the DPoP proof are directly attached to the access token itself so there is no way to reuse them separately. (Interestingly, macaroons have a more direct analogue of DPoP in the form of discharge macaroons. Such discharge macaroons are required to be “prepared” before use, which cryptographically binds them to the equivalent of the access token - so this kind of attack was also considered and addressed there). [1]: https://mailarchive.ietf.org/arch/msg/oauth/1Zltt75p5taPw0DRmhoKLbavu9s/ [2]: https://neilmadden.blog/2020/07/29/least-privilege-with-less-effort-macaroon-access-tokens-in-am-7-0/ — Neil > On 24 Nov 2020, at 09:38, Daniel Fett <[email protected]> wrote: > > > Thanks Justin for bringing this to our attention. > > Right now, I don't think that this is a big problem and I wasn't able to come > up with a way to improve the attack. I hope that it doesn't come back to > haunt us when somebody does a more in-depth analysis... > > That said, the lack of binding to the access token makes it easier to > precompute proofs if somebody has a limited code execution opportunity in the > client. We have this paragraph in the spec: > > Malicious XSS code executed in the context of the browser-based > client application is also in a position to create DPoP proofs with > timestamp values in the future and exfiltrate them in conjunction > with a token. These stolen artifacts can later be used together > independent of the client application to access protected resources. > The impact of such precomputed DPoP proofs can be limited somewhat by > a browser-based client generating and using a new DPoP key for each > new authorization code grant. > > The recommendation could be to use a fresh key pair for each token request. > > -Daniel > > > Am 20.11.20 um 20:26 schrieb Justin Richer: >> While working on an implementation of DPoP recently, I realized that the >> value of the access token itself is not covered by the DPoP signature at >> all. What I’m wondering is whether or not this constitutes an attack surface >> that we care about here. Here’s how it works: >> >> >> Let’s say that a client creates a DPoP key and uses that key to request two >> tokens, T1 and T2, for different users, Alice and Bob, respectively. Alice >> is malicious and wants to get Bob’s stuff. Alice manages to get a hold of >> Bob’s token value, T2, through some means. Normally DPoP wouldn’t let Alice >> create a new request using T2 since Alice doesn’t have the client’s key. >> However, if Alice gets the client to create a request for her using T1, she >> can copy the signature from that request onto a new request using T2. Since >> the signature doesn’t cover the token value and the key is the same, the RS >> should accept both requests, right? >> >> An important aspect is that the parts needed to make this attack work are a >> little weird: you’d need access to a valid signed request from the client >> with T1 as well as access to a valid T2 attached to the same key in order to >> make this substitution. However, this is effectively the same attack area >> that bearer tokens have in a lot of ways, since it doesn’t require the >> attacker gaining access to the singing key to generate or modify a >> signature, nor does it require the attacker to generate or modify an access >> token (merely obtain one). >> >> >> I’d like to understand if this is an actual attack against DPoP. If it >> isn’t, how is it countered by DPoP today? If it is, do we discuss in the >> DPoP draft? I didn’t see a mention of it there. If it’s not, should we >> discuss it there? >> >> >> The old OAuth PoP draft mitigates this attack by putting the access token >> itself inside the signature body instead of a second header. Another option >> would be to include a hash of the token value (such as OIDC’s “at_hash” >> method used in ID Tokens) in the DPoP payload. With either of these >> approaches, Alice having access to T1, T2, and a signed message for T1 does >> not allow her to use T2 effectively. >> >> — Justin >> _______________________________________________ >> OAuth mailing list >> [email protected] >> https://www.ietf.org/mailman/listinfo/oauth > > -- > https://danielfett.de > _______________________________________________ > OAuth mailing list > [email protected] > https://www.ietf.org/mailman/listinfo/oauth -- ForgeRock values your Privacy <https://www.forgerock.com/your-privacy>
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