Wednesday, March 16, 2022

Picking Parameters

When taking something from cryptographic theory into practice, it's very important to pick parameters. I don't mean picking the right parameters — although that certainly helps. I mean picking parameters at all.

That might seem obvious, but there are pressures pushing towards abdication: what if you get it wrong? Why not hedge bets and add another option? What about the two groups who already shipped something? We could just add options so that everyone's happy.

There are always exceptions, but the costs of being flexible are considerable. ANSI X9.62, from 1998, specified how elliptic curves were encoded in ASN.1 and included not just 27 possible curves, but allowed the parameters to be inherited from the issuing CA and allowed completely arbitrary elliptic curves to be defined inside a public key. That specifies almost nothing and avoids really standardising on anything. Thankfully I've not seen parameter inheriance implemented for ECC (it would be a security mess) but support for custom elliptic curves does, sadly, exist.

A couple of years ago, Microsoft had a signature bypass because of support for arbitrary curves [details]. Today, OpenSSL had an infinite loop in certificate parsing because of the same. On the flip side, I'm not aware that anyone has ever used the ability to specify arbitrary curves for anything useful.

It's not fair to just blame X9.62: don't get me started about RSA PSS. The cost of having too many options is frequently underestimated. Why does AES-192 exist, for example, other than to inflate test matrixes?

As an aside, it's interesting to wonder how many CPU decades have been spent fuzzing OpenSSL's certificate parsing and yet today's issue wasn't reported before. This isn't a 2-128 fraction of state space that fuzzers couldn't be expected to find, and I'm not sure that Tavis found it from fuzzing at all.



from Hacker News https://ift.tt/O9ZQW4w

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