Take the 2-minute tour ×
Stack Overflow is a question and answer site for professional and enthusiast programmers. It's 100% free, no registration required.

I was just going through one of DavidHayden's articles on Hashing User Passwords.

Really I can't get what he is trying to achieve.

Here is his code:

private static string CreateSalt(int size)
{
    //Generate a cryptographic random number.
    RNGCryptoServiceProvider rng = new RNGCryptoServiceProvider();
    byte[] buff = new byte[size];
    rng.GetBytes(buff);

    // Return a Base64 string representation of the random number.
    return Convert.ToBase64String(buff);
}

private static string CreatePasswordHash(string pwd, string salt)
{
    string saltAndPwd = String.Concat(pwd, salt);
    string hashedPwd =
        FormsAuthentication.HashPasswordForStoringInConfigFile(
        saltAndPwd, "sha1");
    return hashedPwd;
}

Is there any other C# method for hashing passwords and adding salt to it?

share|improve this question
4  
What are you not getting here? There is one method for generating the salt and one for hashing a password with a salt. –  Mattias Jakobsson Jan 26 '10 at 9:28
    
@Mattias The below answer is what i understood? Now i got clear... –  Oscar Jan 26 '10 at 9:32
    
here is a library that does the hashing with salt encrypto.codeplex.com –  Omu Sep 14 '10 at 8:35
4  
What should you pass in for the size in the first method to generate salt? –  Shane LeBlanc May 21 '12 at 22:01
3  
Link is broken. –  osmanraifgunes Apr 11 at 15:23

6 Answers 6

up vote 128 down vote accepted

Actually this is kind of strange, with the string conversions - which the membership provider does to put them into config files. Hashes and salts are binary blobs, you don't need to convert them to strings unless you want to put them into text files.

In my book, Beginning ASP.NET Security, (oh finally, an excuse to pimp the book) I do the following

static byte[] GenerateSaltedHash(byte[] plainText, byte[] salt)
{
  HashAlgorithm algorithm = new SHA256Managed();

  byte[] plainTextWithSaltBytes = 
    new byte[plainText.Length + salt.Length];

  for (int i = 0; i < plainText.Length; i++)
  {
    plainTextWithSaltBytes[i] = plainText[i];
  }
  for (int i = 0; i < salt.Length; i++)
  {
    plainTextWithSaltBytes[plainText.Length + i] = salt[i];
  }

  return algorithm.ComputeHash(plainTextWithSaltBytes);            
}

The salt generation is as the example in the question. You can convert text to byte arrays using Encoding.UTF8.GetBytes(string). If you must convert a hash to its string representation you can use Convert.ToBase64String and Convert.FromBase64String to convert it back.

You should note that you cannot use the equality operator on byte arrays, it checks references and so you should simply loop through both arrays checking each byte thus

public static bool CompareByteArrays(byte[] array1, byte[] array2)
{
  if (array1.Length != array2.Length)
  {
    return false;
  }

  for (int i = 0; i < array1.Length; i++)
  {
    if (array1[i] != array2[i])
    {
      return false;
    }
  }

  return true;
}

Always use a new salt per password. Salts do not have to be kept secret and can be stored alongside the hash itself.

share|improve this answer
57  
+1 for your book pimping! ;-) –  PhilPursglove Jan 26 '10 at 10:01
3  
Thanks for this advice - really helped get me started. I also came across this link < dijksterhuis.org/creating-salted-hash-values-in-c > which I found was good practical advice and mirrors much of what was said in this post –  Alex P Jul 15 '10 at 9:29
15  
nifty LINQ statement refactor for CompareByteArrays return array1.Length == array2.Length && !array1.Where((t, i) => t != array2[i]).Any(); –  hunter Oct 10 '10 at 19:50
6  
@Brettski Technically, yes, but having a **unique** salt for each user renders Rainbow Tables (generally accepted as the most efficient way to crack hashed passwords) practically useless. This is a quick oveview gives a in-depth but not overwhelming overview of how to store passwords securely, and why/how it all works. –  Nex Terren Sep 15 '12 at 20:38
3  
-1 for using a fast hash-function. Use a slow construction like PBKDF2, bcrypt or scrypt. –  CodesInChaos Aug 16 '13 at 16:01

This is how I do it.. I create the hash and store it using the ProtectedData api:

    public static string GenerateKeyHash(string Password)
    {
        if (string.IsNullOrEmpty(Password)) return null;
        if (Password.Length < 1) return null;

        byte[] salt = new byte[20];
        byte[] key = new byte[20];
        byte[] ret = new byte[40];

        try
        {
            using (RNGCryptoServiceProvider randomBytes = new RNGCryptoServiceProvider())
            {
                randomBytes.GetBytes(salt);

                using (var hashBytes = new Rfc2898DeriveBytes(Password, salt, 10000))
                {
                    key = hashBytes.GetBytes(20);
                    Buffer.BlockCopy(salt, 0, ret, 0, 20);
                    Buffer.BlockCopy(key, 0, ret, 20, 20);
                }
            }
            // returns salt/key pair
            return Convert.ToBase64String(ret);
        }
        finally
        {
            if (salt != null)
                Array.Clear(salt, 0, salt.Length);
            if (key != null)
                Array.Clear(key, 0, key.Length);
            if (ret != null)
                Array.Clear(ret, 0, ret.Length);
        } 
    }

    public static bool ComparePasswords(string PasswordHash, string Password)
    {
        if (string.IsNullOrEmpty(PasswordHash) || string.IsNullOrEmpty(Password)) return false;
        if (PasswordHash.Length < 40 || Password.Length < 1) return false;

        byte[] salt = new byte[20];
        byte[] key = new byte[20];
        byte[] hash = Convert.FromBase64String(PasswordHash);

        try
        {
            Buffer.BlockCopy(hash, 0, salt, 0, 20);
            Buffer.BlockCopy(hash, 20, key, 0, 20);

            using (var hashBytes = new Rfc2898DeriveBytes(Password, salt, 10000))
            {
                byte[] newKey = hashBytes.GetBytes(20);

                if (newKey != null)
                    if (newKey.SequenceEqual(key))
                        return true;
            }
            return false;
        }
        finally
        {
            if (salt != null)
                Array.Clear(salt, 0, salt.Length);
            if (key != null)
                Array.Clear(key, 0, key.Length);
            if (hash != null)
                Array.Clear(hash, 0, hash.Length);
        }
    }

    public static byte[] DecryptData(string Data, byte[] Salt)
    {
        if (string.IsNullOrEmpty(Data)) return null;

        byte[] btData = Convert.FromBase64String(Data);

        try
        {
            return ProtectedData.Unprotect(btData, Salt, DataProtectionScope.CurrentUser);
        }
        finally
        {
            if (btData != null)
                Array.Clear(btData, 0, btData.Length);
        }
    }

    public static string EncryptData(byte[] Data, byte[] Salt)
    {
        if (Data == null) return null;
        if (Data.Length < 1) return null;

        byte[] buffer = new byte[Data.Length];

        try
        {
            Buffer.BlockCopy(Data, 0, buffer, 0, Data.Length);
            return System.Convert.ToBase64String(ProtectedData.Protect(buffer, Salt, DataProtectionScope.CurrentUser));
        }
        finally
        {
            if (buffer != null)
                Array.Clear(buffer, 0, buffer.Length);
        }
    }
share|improve this answer

Bah, this is better! http://sourceforge.net/projects/pwdtknet/ and it is better because ..... it performs Key Stretching AND uses HMACSHA512 :)

share|improve this answer

I've been reading that hashing functions like SHA256 weren't really intended for use with storing passwords: http://throwingfire.com/storing-passwords-securely/#notpasswordhashes

Instead adaptive key derivation functions like PBKDF2, bcrypt or scrypt were. Here is a PBKDF2 based one that Microsoft wrote for their System.Web.Helpers library:

/* =======================
 * HASHED PASSWORD FORMATS
 * =======================
 * 
 * Version 0:
 * PBKDF2 with HMAC-SHA1, 128-bit salt, 256-bit subkey, 1000 iterations.
 * (See also: SDL crypto guidelines v5.1, Part III)
 * Format: { 0x00, salt, subkey }
 */

private const int PBKDF2IterCount = 1000; // default for Rfc2898DeriveBytes
private const int PBKDF2SubkeyLength = 256 / 8; // 256 bits
private const int SaltSize = 128 / 8; // 128 bits

public static string HashPassword(string password)
{
   byte[] salt;
   byte[] subkey;
   using (var deriveBytes = new Rfc2898DeriveBytes(password, SaltSize, PBKDF2IterCount))
   {
      salt = deriveBytes.Salt;
      subkey = deriveBytes.GetBytes(PBKDF2SubkeyLength);
   }

   byte[] outputBytes = new byte[1 + SaltSize + PBKDF2SubkeyLength];
   Buffer.BlockCopy(salt, 0, outputBytes, 1, SaltSize);
   Buffer.BlockCopy(subkey, 0, outputBytes, 1 + SaltSize, PBKDF2SubkeyLength);
   return Convert.ToBase64String(outputBytes);
}

public static bool VerifyHashedPassword(string hashedPassword, string password)
{
   byte[] hashedPasswordBytes = Convert.FromBase64String(hashedPassword);

   // Wrong length or version header.
   if (hashedPasswordBytes.Length != (1 + SaltSize + PBKDF2SubkeyLength) || hashedPasswordBytes[0] != 0x00)
      return false;

   byte[] salt = new byte[SaltSize];
   Buffer.BlockCopy(hashedPasswordBytes, 1, salt, 0, SaltSize);
   byte[] storedSubkey = new byte[PBKDF2SubkeyLength];
   Buffer.BlockCopy(hashedPasswordBytes, 1 + SaltSize, storedSubkey, 0, PBKDF2SubkeyLength);

   byte[] generatedSubkey;
   using (var deriveBytes = new Rfc2898DeriveBytes(password, salt, PBKDF2IterCount))
   {
      generatedSubkey = deriveBytes.GetBytes(PBKDF2SubkeyLength);
   }
   return storedSubkey.SequenceEqual(generatedSubkey);
}
share|improve this answer
    
Note it maybe worth increasing PBKDF2IterCount to a higher number, see security.stackexchange.com/q/3959 for more. –  Michael Nov 6 '13 at 5:34

What blowdart said, but with a little less code. Use Linq or CopyTo to concatenate arrays.

public static byte[] Hash(string value, byte[] salt)
{
    return Hash(Encoding.UTF8.GetBytes(value), salt);
}

public static byte[] Hash(byte[] value, byte[] salt)
{
    byte[] saltedValue = value.Concat(salt).ToArray();
    // Alternatively use CopyTo.
    //var saltedValue = new byte[value.Length + salt.Length];
    //value.CopyTo(saltedValue, 0);
    //salt.CopyTo(saltedValue, value.Length);

    return new SHA256Managed().ComputeHash(saltedValue);
}

Linq has an easy way to compare your byte arrays too.

public bool ConfirmPassword(string password)
{
    byte[] passwordHash = Hash(password, _passwordSalt);

    return _passwordHash.SequenceEqual(passwordHash);
}

Before implementing any of this however, check out this post. For password hashing you may want a slow hash algorithm, not a fast one.

To that end there is the Rfc2898DeriveBytes class which is slow (and can be made slower), and may answer the second part of the original question in that it can take a password and salt and return a hash. See this question for more information. Note, Stack Exchange is using Rfc2898DeriveBytes for password hashing (source code here).

share|improve this answer
2  
The link to "this post" (chargen.matasano.com/chargen/2007/9/7/…) is broken. –  Kjell Rilbe Nov 24 '12 at 6:48
1  
@KjellRilbe I fixed that link. –  Jon-Eric Apr 3 '13 at 18:59

Salt is used to add an extra level of complexity to the hash, to make it harder to brute-force crack.

From an article on Sitepoint:

A hacker can still perform what's called a dictionary attack. Malicious parties may make a dictionary attack by taking, for instance, 100,000 passwords that they know people use frequently (e.g. city names, sports teams, etc.), hash them, and then compare each entry in the dictionary against each row in the database table. If the hackers find a match, bingo! They have your password. To solve this problem, however, we need only salt the hash.

To salt a hash, we simply come up with a random-looking string of text, concatenate it with the password supplied by the user, then hash both the randomly generated string and password together as one value. We then save both the hash and the salt as separate fields within the Users table.

In this scenario, not only would a hacker need to guess the password, they'd have to guess the salt as well. Adding salt to the clear text improves security: now, if a hacker tries a dictionary attack, he must hash his 100,000 entries with the salt of every user row. Although it's still possible, the chances of hacking success diminish radically.

There is no method automatically doing this in .NET, so you'll have go with the solution above.

share|improve this answer
1  
@seb thanks now i get what davidhayden was trying to acheive.. –  Oscar Jan 26 '10 at 9:33

Your Answer

 
discard

By posting your answer, you agree to the privacy policy and terms of service.

Not the answer you're looking for? Browse other questions tagged or ask your own question.