Secure hash and salt for PHP passwords

DISCLAIMER: This answer was written in 2008.

Since then, PHP has given us password_hash and password_verify and, since their introduction, they are the recommended password hashing & checking method.

The theory of the answer is still a good read though.

TL;DR

Don'ts

  • Don't limit what characters users can enter for passwords. Only idiots do this.
  • Don't limit the length of a password. If your users want a sentence with supercalifragilisticexpialidocious in it, don't prevent them from using it.
  • Don't strip or escape HTML and special characters in the password.
  • Never store your user's password in plain-text.
  • Never email a password to your user except when they have lost theirs, and you sent a temporary one.
  • Never, ever log passwords in any manner.
  • Never hash passwords with SHA1 or MD5 or even SHA256! Modern crackers can exceed 60 and 180 billion hashes/second (respectively).
  • Don't mix bcrypt and with the raw output of hash(), either use hex output or base64_encode it. (This applies to any input that may have a rogue \0 in it, which can seriously weaken security.)

Dos

  • Use scrypt when you can; bcrypt if you cannot.
  • Use PBKDF2 if you cannot use either bcrypt or scrypt, with SHA2 hashes.
  • Reset everyone's passwords when the database is compromised.
  • Implement a reasonable 8-10 character minimum length, plus require at least 1 upper case letter, 1 lower case letter, a number, and a symbol. This will improve the entropy of the password, in turn making it harder to crack. (See the "What makes a good password?" section for some debate.)

Why hash passwords anyway?

The objective behind hashing passwords is simple: preventing malicious access to user accounts by compromising the database. So the goal of password hashing is to deter a hacker or cracker by costing them too much time or money to calculate the plain-text passwords. And time/cost are the best deterrents in your arsenal.

Another reason that you want a good, robust hash on a user accounts is to give you enough time to change all the passwords in the system. If your database is compromised you will need enough time to at least lock the system down, if not change every password in the database.

Jeremiah Grossman, CTO of Whitehat Security, stated on White Hat Security blog after a recent password recovery that required brute-force breaking of his password protection:

Interestingly, in living out this nightmare, I learned A LOT I didn’t know about password cracking, storage, and complexity. I’ve come to appreciate why password storage is ever so much more important than password complexity. If you don’t know how your password is stored, then all you really can depend upon is complexity. This might be common knowledge to password and crypto pros, but for the average InfoSec or Web Security expert, I highly doubt it.

(Emphasis mine.)

What makes a good password anyway?

Entropy. (Not that I fully subscribe to Randall's viewpoint.)

In short, entropy is how much variation is within the password. When a password is only lowercase roman letters, that's only 26 characters. That isn't much variation. Alpha-numeric passwords are better, with 36 characters. But allowing upper and lower case, with symbols, is roughly 96 characters. That's a lot better than just letters. One problem is, to make our passwords memorable we insert patterns—which reduces entropy. Oops!

Password entropy is approximated easily. Using the full range of ascii characters (roughly 96 typeable characters) yields an entropy of 6.6 per character, which at 8 characters for a password is still too low (52.679 bits of entropy) for future security. But the good news is: longer passwords, and passwords with unicode characters, really increase the entropy of a password and make it harder to crack.

There's a longer discussion of password entropy on the Crypto StackExchange site. A good Google search will also turn up a lot of results.

In the comments I talked with @popnoodles, who pointed out that enforcing a password policy of X length with X many letters, numbers, symbols, etc, can actually reduce entropy by making the password scheme more predictable. I do agree. Randomess, as truly random as possible, is always the safest but least memorable solution.

So far as I've been able to tell, making the world's best password is a Catch-22. Either its not memorable, too predictable, too short, too many unicode characters (hard to type on a Windows/Mobile device), too long, etc. No password is truly good enough for our purposes, so we must protect them as though they were in Fort Knox.

Best practices

Bcrypt and scrypt are the current best practices. Scrypt will be better than bcrypt in time, but it hasn't seen adoption as a standard by Linux/Unix or by webservers, and hasn't had in-depth reviews of its algorithm posted yet. But still, the future of the algorithm does look promising. If you are working with Ruby there is an scrypt gem that will help you out, and Node.js now has its own scrypt package. You can use Scrypt in PHP either via the Scrypt extension or the Libsodium extension (both are available in PECL).

I highly suggest reading the documentation for the crypt function if you want to understand how to use bcrypt, or finding yourself a good wrapper or use something like PHPASS for a more legacy implementation. I recommend a minimum of 12 rounds of bcrypt, if not 15 to 18.

I changed my mind about using bcrypt when I learned that bcrypt only uses blowfish's key schedule, with a variable cost mechanism. The latter lets you increase the cost to brute-force a password by increasing blowfish's already expensive key schedule.

Average practices

I almost can't imagine this situation anymore. PHPASS supports PHP 3.0.18 through 5.3, so it is usable on almost every installation imaginable—and should be used if you don't know for certain that your environment supports bcrypt.

But suppose that you cannot use bcrypt or PHPASS at all. What then?

Try an implementation of PDKBF2 with the maximum number of rounds that your environment/application/user-perception can tolerate. The lowest number I'd recommend is 2500 rounds. Also, make sure to use hash_hmac() if it is available to make the operation harder to reproduce.

Future Practices

Coming in PHP 5.5 is a full password protection library that abstracts away any pains of working with bcrypt. While most of us are stuck with PHP 5.2 and 5.3 in most common environments, especially shared hosts, @ircmaxell has built a compatibility layer for the coming API that is backward compatible to PHP 5.3.7.

Cryptography Recap & Disclaimer

The computational power required to actually crack a hashed password doesn't exist. The only way for computers to "crack" a password is to recreate it and simulate the hashing algorithm used to secure it. The speed of the hash is linearly related to its ability to be brute-forced. Worse still, most hash algorithms can be easily parallelized to perform even faster. This is why costly schemes like bcrypt and scrypt are so important.

You cannot possibly foresee all threats or avenues of attack, and so you must make your best effort to protect your users up front. If you do not, then you might even miss the fact that you were attacked until it's too late... and you're liable. To avoid that situation, act paranoid to begin with. Attack your own software (internally) and attempt to steal user credentials, or modify other user's accounts or access their data. If you don't test the security of your system, then you cannot blame anyone but yourself.

Lastly: I am not a cryptographer. Whatever I've said is my opinion, but I happen to think it's based on good ol' common sense ... and lots of reading. Remember, be as paranoid as possible, make things as hard to intrude as possible, and then, if you are still worried, contact a white-hat hacker or cryptographer to see what they say about your code/system.


A much shorter and safer answer - don't write your own password mechanism at all, use a tried and tested mechanism.

  • PHP 5.5 or higher: password_hash() is good quality and part of PHP core.
  • PHP 4.x (obsolete): OpenWall's phpass library is much better than most custom code - used in WordPress, Drupal, etc.

Most programmers just don't have the expertise to write crypto related code safely without introducing vulnerabilities.

Quick self-test: what is password stretching and how many iterations should you use? If you don't know the answer, you should use password_hash(), as password stretching is now a critical feature of password mechanisms due to much faster CPUs and the use of GPUs and FPGAs to crack passwords at rates of billions of guesses per second (with GPUs).

As of 2012, you could crack all 8-character Windows passwords in 6 hours using 25 GPUs installed in 5 desktop PCs. This is brute-forcing i.e. enumerating and checking every 8-character Windows password, including special characters, and is not a dictionary attack. With modern GPUs, you can of course crack more passwords or use fewer GPUs - or rent the GPUs in the cloud for a few hours at reasonable cost.

There are also many rainbow table attacks on Windows passwords that run on ordinary CPUs and are very fast.

All this is because Windows still doesn't salt or stretch its passwords, even in Windows 10. This is still true in 2021. Don't make the same mistake as Microsoft did!

See also:

  • excellent answer with more about why password_hash() or phpass are the best way to go.
  • good blog article giving recommmended 'work factors' (number of iterations) for main algorithms including bcrypt, scrypt and PBKDF2.

I would not store the password hashed in two different ways, because then the system is at least as weak as the weakest of the hash algorithms in use.


As of PHP 5.5, PHP has simple, secure functions for hashing and verifying passwords, password_hash() and password_verify()

$password = 'anna';
$hash = password_hash($password, PASSWORD_DEFAULT);
$expensiveHash = password_hash($password, PASSWORD_DEFAULT, array('cost' => 20));

password_verify('anna', $hash); //Returns true
password_verify('anna', $expensiveHash); //Also returns true
password_verify('elsa', $hash); //Returns false

When password_hash() is used, it generates a random salt and includes it in the outputted hash (along with the the cost and algorithm used.) password_verify() then reads that hash and determines the salt and encryption method used, and verifies it against the provided plaintext password.

Providing the PASSWORD_DEFAULT instructs PHP to use the default hashing algorithm of the installed version of PHP. Exactly which algorithm that means is intended to change over time in future versions, so that it will always be one of the strongest available algorithms.

Increasing cost (which defaults to 10) makes the hash harder to brute-force but also means generating hashes and verifying passwords against them will be more work for your server's CPU.

Note that even though the default hashing algorithm may change, old hashes will continue to verify just fine because the algorithm used is stored in the hash and password_verify() picks up on it.


Though the question has been answered, I just want to reiterate that salts used for hashing should be random and not like email address as suggested in first answer.

More explanation is available at- http://www.pivotalsecurity.com/blog/password-hashing-salt-should-it-be-random/

Recently I had a discussion whether password hashes salted with random bits are more secure than the one salted with guessable or known salts. Let’s see: If the system storing password is compromised as well as the system which stores the random salt, the attacker will have access to hash as well as salt, so whether the salt is random or not, doesn’t matter. The attacker will can generate pre-computed rainbow tables to crack the hash. Here comes the interesting part- it is not so trivial to generate pre-computed tables. Let us take example of WPA security model. Your WPA password is actually never sent to Wireless Access Point. Instead, it is hashed with your SSID (the network name- like Linksys, Dlink etc). A very good explanation of how this works is here. In order to retrieve password from hash, you will need to know the password as well as salt (network name). Church of Wifi has already pre-computed hash tables which has top 1000 SSIDs and about 1 million passwords. The size is of all tables is about 40 GB. As you can read on their site, someone used 15 FGPA arrays for 3 days to generate these tables. Assuming victim is using the SSID as “a387csf3″ and password as “123456″, will it be cracked by those tables? No! .. it cannot. Even if the password is weak, the tables don’t have hashes for SSID a387csf3. This is the beauty of having random salt. It will deter crackers who thrive upon pre-computed tables. Can it stop a determined hacker? Probably not. But using random salts does provide additional layer of defense. While we are on this topic, let us discuss additional advantage of storing random salts on a separate system. Scenario #1 : Password hashes are stored on system X and salt values used for hashing are stored on system Y. These salt values are guessable or known (e.g. username) Scenario#2 : Password hashes are stored on system X and salt values used for hashing are stored on system Y. These salt values are random. In case system X has been compromised, as you can guess, there is a huge advantage of using random salt on a separate system (Scenario #2) . The attacker will need to guess addition values to be able to crack hashes. If a 32 bit salt is used, 2^32= 4,294,967,296 (about 4.2 billion) iterations will can be required for each password guessed.