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I've been told that email is a bad salt, because it's not unique and connected to the user.
And if a user uses the same password on 2 sites, there will be equal hash.

So, what's wrong with it? what is attack scenario?
Suppose we have both hash and salt. So, other site has the same hash in their database. How can we do any harm to this user on the other site? Can we at all?

I don't see any possibility, but I am not an expert in security, so, I'd like to hear from ones who are, with practical and concrete answers, of course.

I am not going to break anything. I am asking this question in the context of this one: is email or (registration timestamp) a good salt?

Certain and practical answers, please.

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Related:… – Tom Gullen Feb 21 '11 at 12:16
Ugh what a great article! But it seems it worth sparing some of my free time. Thanks, I'm gonna take a look on it. – Your Common Sense Feb 21 '11 at 12:22

The point of a salt is not to be unknown, it is to prevent attackers from amortizing the cost of a brute force or dictionary attack across all users of a site (or even all users of many sites).

Thus, the problem of using a non-random salt like the email address is that it would show an attacker which users are using the same password on several sites, and which would therefore yield access to several accounts at once if cracked via brute force or dictionary attack. For the email address (and everything that is unique per user), this is a rather hypothetical problem since it assumes the attacker has the account data of several sites with considerable overlap in users.

Another problem with using the email address is that users will want to change it - which would be impossible if you use it as salt unless you store it in a separate salt column as well or require people to always change their password together with their email.

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it would show an attacker which users are using the same password on several sites What? Correct me if I get you wrong: you're gonna say what without such a hint (an equal hash), an attacker, knowing user's password from one site, would not try it on others? – Your Common Sense Feb 21 '11 at 9:33
@Col. Shrapnel: no, I'm saying that the equal hash shows the attacker which passwords will definitely yield access to two (or more) accounts for the price of only one brute-force attack. Of course, if we assume that most users use the same password for multiple sites, this is not very valuable information. – Michael Borgwardt Feb 21 '11 at 9:38
@Col. Shrapnel actually he is correct. Thats why salts where only a few bits in size on old Unix systems. – rook Feb 21 '11 at 18:33
i'm curious what you have to say about my post. – rook Feb 21 '11 at 18:47

This is mostly a theoretical question. So, how does "cracking a hashed value" work? There are so called "rainbow tables", that are just list with common words and theire hash value. For salted hashes an attacker needs such tables also with salted hashes. So in theory with unique salts for every user an attacker needs one table for every salt (=> user). If you have a static salt, he "just" needs one table for your db. Its quite expensive to create such tables, so in most cases its not worth to create it just for a single page.

Conclusion: Its (of course) safer, to use unique salts for every user, but on a veeery high level. A static salts is usually "safe enough".

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The first attack I can think of is:

  • a user has the same salt and password at two sites
  • both sites have a flaw to allow reading the salted passwords
  • one site makes reading a password or brute-force guessing a password easy

An attacker could quickly look at identical salted passwords on both sites and find users with identical passwords at both sites. Then read the password or guess the password on the weaker site, and use it on the more secure site.

Granted, different salts wouldn't make the problem significantly better because all million passwords can be tried eventually. But knowing which users have identical passwords would be much 'quieter' than just blindly trying all the users' passwords on the stronger site.

share|improve this answer
The salt is only relevant in a scenario where the attacker has the password hash and is thus able to run a local brute-force attack, i.e. not interacting with the affected site at all (and thousands of times more efficient). – Michael Borgwardt Feb 21 '11 at 9:41
@michael Borgwardt, salts have multiple benefits: yours is the most important benefit, but salts are also useful for hiding the fact that users may have identical passwords. – sarnold Feb 21 '11 at 9:44
@Col. Shrapnel, perhaps one site uses HTTP and the other uses HTTPS. You could simply read the password for a user off the wire from the first site, and if you know which users have identical passwords on both sites, presto, you've got silent access to the stronger site. It is a stretch to assume both sites have flaws that expose salted passwords, but I've seen enough SQL injection attacks to believe it's non-trivial amount of sites. – sarnold Feb 21 '11 at 9:46
@Col. Shrapnel except it can take hours or days to brute-force a salted dictionary but only seconds to read a password off the wire if it is sent in cleartext to a weaker site first. – sarnold Feb 21 '11 at 10:54
@Col. Shrapnel, glad we finally connected :) you're right, "try the password anyway" is an obvious step, but noisy -- it'll be noticed in the logs when an attacker tries thousands of passwords much faster than usual password failure rates. So finding identical hashes --> identical passwords --> silent abuse. Well, the failure rate will go down :) but I doubt any admins would pay attention. – sarnold Feb 21 '11 at 11:06

Think of the web sites you've programmed - I bet the most powerful users in these systems have very common usernames like admin, root, etc. As an attacker I can generate a precomputed hash list containing the most common usernames with the weakest and most common passwords - that is, if a web programmer is naive enough to salt their passwords with usernames, my job as an attacker has become much, much easier - the collisions are very predictable.

Using an email address as a salt is better, but the same principle applies. Assuming I've cracked one database that uses an email-based salt I'll have a much easier time cracking every other database that does the same - at least, for email/password combinations that exist across databases. (Given the amount of login reuse, that's a very likely). It's not as simple as with the username salts, but the collisions are out there, waiting to be discovered.

As a programmer what I really want is a password hash that won't collide - ever. A universally unique hash for each user that can't be found in any other database in the world. That's a tall order, but it's doable with a sufficiently long, randomly generated salt.

There's a herd immunity effect in play - using a bad salt makes it easier for attackers to attack similar systems after they've compromised your database. A strong salt will always protect your users and help other userbases from being compromised.

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aren't weakest and most common passwords already breakable, despite of the salt? – Your Common Sense Feb 21 '11 at 12:15

Assume the hacker has both password and salt, AND access to your hashing formula.

This will NOT prevent a dictionary attack, contrary to popular beleif. It will stop a simple dictionary attack, but iterating the dictionary with the salts per user account is perfectly possible.

See: Why do salts make dictionary attacks 'impossible'? for more related information.

This is why when you generate the hash of the password, instead of hashing once with salt, IE:

hashedPW = sha1(rawPassword + salt)

You would do:

hashedPW = sha1(rawPassword + salt)
for i = 0; i < 2000; i++){
    hashedPW = sha1(hashedPW + salt)

The multi hash function should take a significant fraction of a second to calculate. This means when the hacker gains access to the database, the dictionary attack then becomes exponentially more time consuming only allowing him to crack a very small % of user accounts.

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It's still takes only seconds to break certain password. Isn't it better to allow complex passwords only? – Your Common Sense Feb 21 '11 at 12:21
Assume you realise this would have to be calculated for each authentication. Yikes. – Sam Stainsby Feb 21 '11 at 12:28
Having password rules that increase the combinations of possible password to as large a set as possible without compromising too much on usability is a delicate balance. But, yes, having password rules is a great way to make dictionary attacks near impossible. However, even with complex rule passwords + salts, these can be brute forced reasonably easily, which is why you rehash them over 1 thousand times to make this extremely time consuming so less accounts are compromised. – Tom Gullen Feb 21 '11 at 12:29
@Sam yes, it is an expensive operation. See… for more detailed information on it. It is a good security measure. Authentication is usually a one of irregular calculation though (only at login) so it is an acceptable tradeoff. – Tom Gullen Feb 21 '11 at 12:30
Use a longer hash and salt instead. – Sam Stainsby Feb 21 '11 at 12:31

Can't really help you in terms of security, but if you look at vBulletin for example, each user gets their own generated salt, which they use the encrypt the password like this:

$password = md5(md5($clear_password) + $salt);

So the salt will be different for each user and any site where vBulletin is running (at least a pretty good chance that it will be different), so the stored password, in turn will be different for each site.

It's not what you were asking for, but something to meditate on :)

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Sorry, I don't meditate. Nor pray or worship. I program. – Your Common Sense Feb 21 '11 at 9:28
-1 for explicitly not answering the question. – Zeemee Feb 21 '11 at 11:18
To explain a little my previous statement. To implement a random salt is not that big problem. I think that vBulletin guys were thinking the same: it will do no harm to create a random salt - so, we will do it. But my goal is slightly different: Not a protection that I look for, but rather knowledge. I want to confirm that I understand the things right. A point of view from the other side of the frontier, you may call it. – Your Common Sense Feb 21 '11 at 11:33

If the salt is already known, then you have bigger problems on your hands.

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Thank you. It says Proper key derivation functions employ salt to make this attack infeasible – Your Common Sense Feb 21 '11 at 10:35
Passwords are stored in a hash format in a DB. Some sites add a salt to protect passwords from being brute forced. Hashes have collisions thats why some of the familiar ones are retired, the idea of a Rainbow Attack is to find a keyword that would result to a similar hash. Password = MD5 (Weak if password is something simple) Password+SALT = MD5 (Harder to guess) So yes if you know the Salt and mount a Rainbow Attack on a desired hash you can attack a user password. – Nocturnal Feb 21 '11 at 11:01
I'm afraid you don't understand the meaning of the rainbow table. if you find the similar hash of salted password, using such table due to a collision, it won't help you to reveal password itself. As for the bruteforce, here is one little problem: to bruteforce a hash, one need to have that hash, isn't it? – Your Common Sense Feb 21 '11 at 11:09
You want to reveal the original password itself. Good luck! :) – Nocturnal Feb 21 '11 at 11:13
You don't? but how can you use a hash otherwise? – Your Common Sense Feb 21 '11 at 11:23

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