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In a Linux system, passwords are stored using an MD5 hash. Why can the usage of "salt" protect the system more? Particularly, I want to make clear the following two

  1. The salt is said to be stored in clear text with the hash, then how it can prevent the attacker when the attacker knows the salt value. (Attacker can be the system administrator himself who can check /etc/shadow.
  2. If the salt is generated randomly everytime, how can the system compare the hash to authenticate the user?

For example, User A has user salt s1 and generate h1; h1 = md5(password.s1);. The next time, it uses salt s2 and the system must generate a different hash, h2 = md5(password.s2). Since h1 is not equal to h2, how can the system authenticate the user?

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MD5 is a hash as you know, so if you give it an input, like 'PASSWORD', you get a unique (hopefully - however MD5 has collisions these days) output, like '3DE2AF...'.

Now, as you know, it's quite hard to directly reverse that, until somebody thought... wait, why don't I pre-generate all the possible combinations of hashable values until I can reverse the hash. This is called a rainbow table.

The purpose of a salt is to add arbitrary random data to the string being hashed, such that you increase the length of input to hash. This means general rainbow tables that expect to reverse just a password input to a hash won't work. Of course, rainbow tables being just reverse lookups, you could simply generate a rainbow table to compensate for all the possible password+salt outputs. This is where the increase in length comes into its own; because of the nature of reversing hashes, the disk space to generate reverses for very long hash inputs soon becomes infeasible. Alphanumeric rainbow tables for 6-8 characters are already a couple of Gigabytes; increase the length and character classes and you start to talk in multiples of 10GB.

Of course, if you're salting with 'PASSWORD' and you hash 'PASSWORD' you're hashing 'PASSWORDPASSWORD' which isn't that much more secure, so the choice of salt is important too. Ideally, you should use a random salt with each hashed string, but of course, you need to know what it is. A common technique is to derive a salt from the username or some other property unique to this case. Adding arbitrary data isn't in itself useful; having user-determined salt data now adds an additional level of complexity, meaning rainbow tables are needed with specialised searches for each user. The more you make this difficult, the more computational power is needed. That's where the battle is.

However, there are some modern techniques. I am not an expert, so I can't tell you how secure these are, but they are worth a mention. The concept is slow hashing. Basically, through compound hash functions you make it take a while to compute each hash. As such, the ability for each user to check the password now has a constant amount of time added for each password you wish to check. If you're bruteforcing, that is Bad News(tm). Similarly, if the system is well designed, if there are no shortcuts (which probably equate to weaknesses) then generating a rainbow table for a slow hash function should also take a while.

Edit more detail here. See crypt() for the first example of this. @CodeInChaos has referenced PBKDF2 which forms part of PKCS#5. A newer development is scrypt.

As I say, I'm not an expert cryptanalyst. On the latter example, I have no particular specialist knowledge as to its suitability, I'm merely showing you where things are headed.

Edit 2 Clarified my write up of salt - I think I danced around the key issue of disk space before.

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  • While personally I like the idea of scrypt, I haven't seen much analysis done on it. So I'd rather go with one of the older standardized KDFs. The advantage of scrypt only comes into play if you face an attacker who uses custom hardware or perhaps FPGAs. Feb 19 '11 at 13:48
  • @CodeInChaos mmm. That's the one I've looked at / talked about most recently so the one that came to mind. But you're right, it hasn't had a chance to be thoroughly reviewed yet.
    – user257111
    Feb 19 '11 at 13:51
  • I am wondering if the salt is stored in the clear text, the attacker can just built a rainbow table based on the specific salt.
    – user496949
    Feb 19 '11 at 13:57
  • @user49 the salt isn't. It's added to what you hash. But yes, if you know or have an idea of how that string is constructed, you could nullify the benefit of the salt for that specific case. But that's the thing - it would be on a case-by-case basis. Cryptography/Hashes etc are not absolute security; the idea is to make it as difficult as possible for your attacker.
    – user257111
    Feb 19 '11 at 13:59
  • Usausally the system just append the salt to the password, then do the hash , is this right? Or this mechanism is not too hard to figure it out if I am an system admin.
    – user496949
    Feb 19 '11 at 14:08
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You can reverse a simple hash algorithm by brute force.

If you are using a common word for passwords, some prebuild tables (like rainbow ones) might contain them. That's why most algorithms call the hash function several times:

md5(md5(md5(password)));

Using salt gives a lot more of randomness to the generated password and thus make it less guessable. It consists of adding a random piece of string in the process

md5(md5(md5(password+string)+string)+string);
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  • Good answer but i have another question ! does md5(md5(md5(password))); allowed in programming languages ? and can yet the multiple hashed ciphers expose the rainbow and brute force?
    – Sudantha
    Feb 19 '11 at 13:30
  • Why shouldn't it ? md5 takes a string as parameter and returns a string. You can call it as many times you want. Reversing each hash costs more time and resources to the attacker than to the hasher.
    – vaugham
    Feb 19 '11 at 13:35
  • typcially you don't write something like md5(md5(...)) yourself but use but use a known and reviewed key derivation function. For example PBKDF2 based on HMAC. And repeatedly calling the hash function doesn't help much against rainbow tables. Many iterations are used to slow down brute-force, and the salt is used to prevent rainbow tables. Feb 19 '11 at 13:44
  • md5 is not reversible, but you can find strings pretty easily that hash to the same values making a pretty poor algorithm to use to obfuscate your passwords without using a salt. The salt doesn't give it randomness, but rather makes it so that if you do use a password that matches the hash value when hashed without a salt, it won't match the hash with the salt added. This adds security in that you'd have to know both the hashed value and the salt before you can figure out what value to use from the rainbow table.
    – tvanfosson
    Feb 19 '11 at 13:45
  • I should say that it "doesn't give it randomness unless you use a random salt" Without a random salt, it's a simple transformation.
    – tvanfosson
    Feb 19 '11 at 13:53
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One reason could be, if two people use same password unknowingly they will generate same MD5. One of them can just see /etc/shadow and guess other guys password.

Now with salt added to each password, even same passwords generate different hashes.

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  • If the password is so simple that it generates the same hash by accident it's trivially brute-forced too. Feb 19 '11 at 13:45
  • That is if shadow file uses md5, not to mention that those are salted as well. And even if they weren't, unless the OS has seriously messed up permissions, if a person can read shadow you have bigger problem then this issue:) Feb 19 '11 at 13:50
  • That's true if you use a different salt per password, but not if you share the salt between all passwords. If you use the same salt they will hash to the same value. It can happen, though, that even if you use different passwords they will hash to the same value. In that case using a salt should force them to hash to different values. In any event /etc/shadow should not be readable by anyone but root and if they've got root access you're screwed anyway.
    – tvanfosson
    Feb 19 '11 at 13:51
  • @CodeInChaos: hashes for each string are the same, whether it is 3 chars or 30 long, in fact that what allows attackers to bruteforce it... Feb 19 '11 at 13:52
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When you encrypt data it can be still attacked by bruce-force attacks and rainbow attacks. In salting, at the end of the encrypted data you add some additional bits. So the attacker cannot get the original data properly.

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