this post was submitted on 26 Sep 2024
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Which shouldn't even matter because passwords are salted and hashed before storing them, so you're not actually saving anything. At least they better be. If you're not hashing passwords you've got a much bigger problem than low complexity passwords.
The place that truncates passwords is probably not the place to look for best practices when it comes to security. :-)
Hashing passwords isn't even best practice at this point, it's the minimally acceptable standard.
What is the best practice currently?
Use a library. It's far too easy for developers or project managers to fuck up the minimum requirements for safely storing passwords.
But, if you are wanting to do it by hand...
Isn't that... the very definition of a Salt? A user-specific known string? Though my understanding is that the salt gets appended to the user-provided password, hashed and then checked against the record, so I wouldn't say that the hash is salted, but rather the password.
Also using a pepper is good practice in addition to a salt, though the latter is more important.
Some implementers reuse the same salt for all passwords. It's not the worst thing ever, but it does make it substantially easier to crack than if everything has its own salt.
That's a pepper not a salt. A constant value added to the password that's the same for every user is a pepper and prevents rainbow table attacks. A per-user value added is a salt and prevents a number of things, but the big one is being able to overwrite a users password entry with another known users password (perhaps with a SQL injection).
I remember hearing to not layer encryptions or hashes on top of themselves. It didn't make any sense to me at the time. It was presented as if that weakened the encryption somehow, though wasn't elaborated on (it was a security focused class, not encryption focused, so didn't go heavy into the math).
Like my thought was, if doing more encryption weakened the encryption that was already there, couldn't an attacker just do more encryption themselves to reduce entropy?
The class was overall good, but this was still a university level CS course and I really wish I had pressed on that bit of "advice" more. Best guess at this point is that I misunderstood what was really being said because it just never made any sense at all to me.
It's because layering doesn't really gain you anything so it only has downsides. It's important to differentiate encryption and hashing from here on since the dangers are different.
With hashing, layering different hashing algorithms can lead to increased collision chance and if done wrong a reduced entropy (for instance hashing a 256 bit hash with a 16 bit hashing algorithm). Done correctly it's probably fine and in fact rehashing a hash with the same algorithm is standard practice, but care should be taken.
With encryption things get much worse. When layering encryption algorithms a flaw in one can severely compromise them all. Presumably you're using the same secret across them all. If the attacker has a known piece of input or can potentially control the input a variety of potential attack vectors open up. If there's a flaw in one of the algorithms used that can make the process of extracting the encryption key much easier. Often times the key is more valuable than any single piece of input because keys are often shared across many encrypted files or data streams.
With the hash one, it doesn't look like that could be exploited by an attacker doing the bad hashing themselves, since any collisions they do find will only be relevant to the extra hashing they do on their end.
But that encryption one still sounds like it could be exploited by an attacker applying more encryption themselves. Though I'm assuming there's a public key the attacker has access to and if more layers of encryption make it easier to determine the associated private key, then just do that?
Though when you say they share the same secret, my assumption is that a public key for one algorithm doesn't map to the same private key as another algorithm, so wouldn't cracking one layer still be uncorrelated with cracking the other layers? Assuming it's not reusing a one time pad or something like that, so I guess context matters here.
Sorta. Not really.
Key derivation algorithms are still hashes in most practical ways. Though they're derived directly from block ciphers in most cases, so you could also say they're encrypted. Even though people say to hash passwords, not encrypt them.
I find the whole terminology here to be unenlightening. It obscures more than it understands.
A KDF is not reversible so it's not encryption (a bad one can be brute forced or have a collision, but that's different from decrypting it even if the outcome is effectively the same). As long as you're salting (and ideally peppering) your passwords and the iteration count is sufficiently high, any sufficiently long password will be effectively unrecoverable via any known means (barring a flaw being found in the KDF).
The defining characteristic that separates hashing from encryption is that for hashing there is no inverse function that can take the output and one or more extra parameters (secrets, salts, etc.) and produce the original input, unlike with encryption.
OK. How do you reconcile that with "Hashing passwords isn't even the best practice at this point"? Key derivation functions are certainly the recommended approach these days. If they are hashes, then your earlier post is wrong, and if they aren't hashes, then your next post was wrong.
The rest of that sentence is important. Hashing passwords is the minimum practice, not best practice. You should always be at least hashing passwords. Best practice would be salting and peppering them as well as picking a strong hashing function with as high a number of iterations as you can support. You would then pair that with 2FA (not SMS based), and a minimum password length of 16 with no maximum length.