I'm not sure how password hashing works (will be implementing it later), but need to create database schema now.

I'm thinking of limiting passwords to 4-20 characters, but as I understand after encrypting hash string will be of different length.

So, how to store these passwords in the database?

  • Also see Openwall's PHP password hashing framework (PHPass). Its portable and hardened against a number of common attacks on user passwords. The guy who wrote the framework (SolarDesigner) is the same guy who wrote John The Ripper and sits as a judge in the Password Hashing Competition. So he knows a thing or two about attacks on passwords.
    – jww
    Oct 12, 2014 at 1:33
  • 2
    Please do not put an upper limit on your passwords. You are hashing them, there is no storage reason for an upper limit. If you are worried about DoS attacks using the password hash, 1000 or 1024 is a reasonable upper limit.
    – Iiridayn
    Feb 15, 2016 at 4:57
  • why limit password length? At least let a user create a 100 character password :)
    – Andrew
    Mar 20, 2016 at 19:33
  • 4 characters is a pretty dangerous lower bound for passwords as those are trivial to crack. At the very least use 8 but 14 or 16 is much better.
    – quikchange
    Nov 20, 2016 at 1:50
  • This is a very old question with an outdated answer. See the Gilles answer for up to date.
    – kelalaka
    Apr 18, 2019 at 21:43

10 Answers 10


Update: Simply using a hash function is not strong enough for storing passwords. You should read the answer from Gilles on this thread for a more detailed explanation.

For passwords, use a key-strengthening hash algorithm like Bcrypt or Argon2i. For example, in PHP, use the password_hash() function, which uses Bcrypt by default.

$hash = password_hash("rasmuslerdorf", PASSWORD_DEFAULT);

The result is a 60-character string similar to the following (but the digits will vary, because it generates a unique salt).


Use the SQL data type CHAR(60) to store this encoding of a Bcrypt hash. Note this function doesn't encode as a string of hexadecimal digits, so we can't as easily unhex it to store in binary.

Other hash functions still have uses, but not for storing passwords, so I'll keep the original answer below, written in 2008.

It depends on the hashing algorithm you use. Hashing always produces a result of the same length, regardless of the input. It is typical to represent the binary hash result in text, as a series of hexadecimal digits. Or you can use the UNHEX() function to reduce a string of hex digits by half.

  • MD5 generates a 128-bit hash value. You can use CHAR(32) or BINARY(16)
  • SHA-1 generates a 160-bit hash value. You can use CHAR(40) or BINARY(20)
  • SHA-224 generates a 224-bit hash value. You can use CHAR(56) or BINARY(28)
  • SHA-256 generates a 256-bit hash value. You can use CHAR(64) or BINARY(32)
  • SHA-384 generates a 384-bit hash value. You can use CHAR(96) or BINARY(48)
  • SHA-512 generates a 512-bit hash value. You can use CHAR(128) or BINARY(64)
  • BCrypt generates an implementation-dependent 448-bit hash value. You might need CHAR(56), CHAR(60), CHAR(76), BINARY(56) or BINARY(60)

As of 2015, NIST recommends using SHA-256 or higher for any applications of hash functions requiring interoperability. But NIST does not recommend using these simple hash functions for storing passwords securely.

Lesser hashing algorithms have their uses (like internal to an application, not for interchange), but they are known to be crackable.

  • 57
    @Hippo: Please, don't use the username as the salt. Generate a random salt per user. Sep 15, 2010 at 18:38
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    Yes, there's no reason not to store it in the same row. Even if an attacker gains access to your database, they'd have to construct their rainbow table based on that salt. And that's just as much work as simply guessing the password. Sep 16, 2010 at 7:14
  • 5
    @SgtPooki: You need another column to store the salt in plaintext. Then you can hash the user's password with the same salt when they type it in, and compare the result to the hash digest stored in the table. Oct 14, 2011 at 6:23
  • 13
    If you're storing the salt in the same table (or any other location with the same access permissions) there's no reason not to use the username as the salt, since it will be unique per user. However, any known salt makes the hash cryptographically weaker than if there were no known salt. A salt only adds value if it is also unknown.
    – fijiaaron
    May 18, 2012 at 13:39
  • 10
    I don't understand the deal with known vs. unknown salt. If you're implementing a site - the salt needs to be known to the login page/script/sevice that's testing the password. So - you "unknown" salt advocates - are you assuming that the code for the login process is unknown to the attacker? Otherwise - won't the attacker always know the salt, whether it's random, unique, stored together with the hashed password or apart? Jan 4, 2013 at 19:31

Always use a password hashing algorithm: Argon2, scrypt, bcrypt or PBKDF2.

Argon2 won the 2015 password hashing competition. Scrypt, bcrypt and PBKDF2 are older algorithms that are considered less preferred now, but still fundamentally sound, so if your platform doesn't support Argon2 yet, it's ok to use another algorithm for now.

Never store a password directly in a database. Don't encrypt it, either: otherwise, if your site gets breached, the attacker gets the decryption key and so can obtain all passwords. Passwords MUST be hashed.

A password hash has different properties from a hash table hash or a cryptographic hash. Never use an ordinary cryptographic hash such as MD5, SHA-256 or SHA-512 on a password. A password hashing algorithm uses a salt, which is unique (not used for any other user or in anybody else's database). The salt is necessary so that attackers can't just pre-calculate the hashes of common passwords: with a salt, they have to restart the calculation for every account. A password hashing algorithm is intrinsically slow — as slow as you can afford. Slowness hurts the attacker a lot more than you because the attacker has to try many different passwords. For more information, see How to securely hash passwords.

A password hash encodes four pieces of information:

  • An indicator of which algorithm is used. This is necessary for agility: cryptographic recommendations change over time. You need to be able to transition to a new algorithm.
  • A difficulty or hardness indicator. The higher this value, the more computation is needed to calculate the hash. This should be a constant or a global configuration value in the password change function, but it should increase over time as computers get faster, so you need to remember the value for each account. Some algorithms have a single numerical value, others have more parameters there (for example to tune CPU usage and RAM usage separately).
  • The salt. Since the salt must be globally unique, it has to be stored for each account. The salt should be generated randomly on each password change.
  • The hash proper, i.e. the output of the mathematical calculation in the hashing algorithm.

Many libraries include a pair functions that conveniently packages this information as a single string: one that takes the algorithm indicator, the hardness indicator and the password, generates a random salt and returns the full hash string; and one that takes a password and the full hash string as input and returns a boolean indicating whether the password was correct. There's no universal standard, but a common encoding is


where algorithm is a number or a short alphanumeric string encoding the choice of algorithm, parameters is a printable string, and salt and output are encoded in Base64 without terminating =.

16 bytes are enough for the salt and the output. (See e.g. recommendations for Argon2.) Encoded in Base64, that's 21 characters each. The other two parts depend on the algorithm and parameters, but 20–40 characters are typical. That's a total of about 82 ASCII characters (CHAR(82), and no need for Unicode), to which you should add a safety margin if you think it's going to be difficult to enlarge the field later.

If you encode the hash in a binary format, you can get it down to 1 byte for the algorithm, 1–4 bytes for the hardness (if you hard-code some of the parameters), and 16 bytes each for the salt and output, for a total of 37 bytes. Say 40 bytes (BINARY(40)) to have at least a couple of spare bytes. Note that these are 8-bit bytes, not printable characters, in particular the field can include null bytes.

Note that the length of the hash is completely unrelated to the length of the password.


You can actually use CHAR(length of hash) to define your datatype for MySQL because each hashing algorithm will always evaluate out to the same number of characters. For example, SHA1 always returns a 40-character hexadecimal number.


You might find this Wikipedia article on salting worthwhile. The idea is to add a set bit of data to randomize your hash value; this will protect your passwords from dictionary attacks if someone gets unauthorized access to the password hashes.

  • 2
    That is indeed very worthwhile (+1), but it doesn't answer the question! (-1) Oct 29, 2008 at 16:59
  • 5
    Yes, but definitely relevant in this context (+1)
    – Treb
    Oct 29, 2008 at 20:37

As a fixed length string (VARCHAR(n) or however MySQL calls it). A hash has always a fixed length of for example 12 characters (depending on the hash algorithm you use). So a 20 char password would be reduced to a 12 char hash, and a 4 char password would also yield a 12 char hash.

  • 3
    'or however MySQL calls it' - MYSQL call it CHAR. This type is for fixed length value. So I think CHAR is better type than VARCHAR.
    – Alex
    Oct 13, 2016 at 20:35

You should use TEXT (storing unlimited number of characters) for the sake of forward compatibility. Hashing algorithms (need to) become stronger over time and thus this database field will need to support more characters over time. Additionally depending on your migration strategy you may need to store new and old hashes in the same field, so fixing the length to one type of hash is not recommended.


Hashes are a sequence of bits (128 bits, 160 bits, 256 bits, etc., depending on the algorithm). Your column should be binary-typed, not text/character-typed, if MySQL allows it (SQL Server datatype is binary(n) or varbinary(n)). You should also salt the hashes. Salts may be text or binary, and you will need a corresponding column.

  • Justice is completely correct here - MySQL will store these as numerical values and will make searching on this column much more efficient than doing a string match, however salts should not be stored in the database beside the salted data - that eliminates the safety that salts provide.
    – Tony Maro
    Sep 20, 2011 at 14:54
  • 6
    Salts are not secret. The only secret is the password. Just make sure that every new password gets a new salt. Each time the user changes his password, the system should generate a new salt for that password. Salts should be long and random, such as 16 bytes generated from a cryptographically secure PRNG.
    – yfeldblum
    Sep 20, 2011 at 15:31
  • 1
    @TonyMaro Not sure whether a password string match on the SQL level is a good strategy. In other words, you should not search your database for a password, instead retrieve the user based on his username and compare passwords in code, rather than SQL.
    – bart
    Jul 25, 2017 at 22:27

It really depends on the hashing algorithm you're using. The length of the password has little to do with the length of the hash, if I remember correctly. Look up the specs on the hashing algorithm you are using, run a few tests, and truncate just above that.


I've always tested to find the MAX string length of an encrypted string and set that as the character length of a VARCHAR type. Depending on how many records you're going to have, it could really help the database size.


for md5 vARCHAR(32) is appropriate. For those using AES better to use varbinary.


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