How does node.bcrypt.js compare hashed and plaintext passwords without the salt?
The salt is incorporated into the hash (as plaintext). The compare function simply pulls the salt out of the hash and then uses it to hash the password and perform the comparison.
Bcrypt compare hashed and plaintext passwords without the salt string because the hashed password contains the salt string which we created at the time of hashing.
For example :
Take this Plain Password :
546456546456546456456546111
Hashed Password of above plain text using Bcrypt :
$2b$10$uuIKmW3Pvme9tH8qOn/H7uZqlv9ENS7zlIbkMvCSDIv7aup3WNH9W
So in the above hashed password, There are three fields delimited by $ symbol.
i) First Part $2b$ identifies the bcrypt algorithm version used.
ii) Second Part $10$ 10 is the cost factor (nothing but salt rounds while we creating the salt string. If we do 15 rounds, then the value will be $15$
iii) Third Part is first 22 characters (that is nothing but salt string) In this case it is
uuIKmW3Pvme9tH8qOn/H7u
The remaining string is hashed password. So basically, the saltedHash = salt string + hashedPassword to protect from rainbow table attacks.
I had the same question too as the original poster and it took a look bit of looking around and trying different things to understand the mechanism. As has already been pointed out by others, the salt is concatenated to the final hash. So this means a couple of things:
- The algorithm must know the length of the salt
- Must also know the position of the salt in the final string. e.g. if offset by a specific number from left or right.
These two things are usually hard coded in the implementation e.g. the bcrypt implementation source for bcryptjs defines the salt length as 16
/**
* @type {number}
* @const
* @private
*/
var BCRYPT_SALT_LEN = 16;
So to illustrate the basic concept behind the idea if one wanted to do it manually, It would look similar to the below. I do not recommend implementing stuff like this yourself when there are libraries that you can get to do it.
var salt_length = 16;
var salt_offset = 0;
var genSalt = function(callback)
{
var alphaNum = '0123456789abcdefghijklmnopqurstuvwxyzABCDEFGHIJKLMNOPQURSTUVWXYZ';
var salt = '';
for (var i = 0; i < salt_length; i++) {
var j = Math.floor(Math.random() * alphaNum.length);
salt += alphaNum[j];
}
callback(salt);
}
// cryptographic hash function of your choice e.g. shar2
// preferably included from an External Library (dont reinvent the wheel)
var shar2 = function(str) {
// shar2 logic here
// return hashed string;
}
var hash = function(passwordText, callback)
{
var passwordHash = null;
genSalt(function(salt){
passwordHash = salt + shar2(passwordText + salt);
});
callback(null, passwordHash);
}
var compare = function(passwordText, passwordHash, callback)
{
var salt = passwordHash.substr(salt_offset, salt_length);
validatedHash = salt + shar2(passwordText + salt);
callback(passwordHash === validatedHash);
}
// sample usage
var encryptPassword = function(user)
{
// user is an object with fields like username, pass, email
hash(user.pass, function(err, passwordHash){
// use the hashed password here
user.pass = passwordHash;
});
return user;
}
var checkPassword = function(passwordText, user)
{
// user has been returned from database with a hashed password
compare(passwordText, user.pass, function(result){
// result will be true if the two are equal
if (result){
// succeeded
console.log('Correct Password');
}
else {
// failed
console.log('Incorrect Password');
}
});
}