I need to hash passwords for storage in a database. How can I do this in Java?

I was hoping to take the plain text password, add a random salt, then store the salt and the hashed password in the database.

Then when a user wanted to log in, I could take their submitted password, add the random salt from their account information, hash it and see if it equates to the stored hash password with their account information.

  • 11
    @YGL this is actually not a recombination nowadays with GPU attacks being so cheap, SHA family is actually a very bad choice for password hashing (too fast) even with salt. Use bcrypt, scrypt or PBKDF2
    – Eran Medan
    Nov 21, 2012 at 7:01
  • 11
    Why was this question closed? This is a question for a real engineering problem, and the answers are invaluable. The OP is not asking for a library, he is asking how to solve the engineering problem. Apr 14, 2015 at 5:23
  • 12
    Just amazing. This question has 52 upvotes, and someone decides to close it as "off-topic". Apr 14, 2015 at 5:32
  • 1
    Yeah, I've posted on Meta about this issue of closings before, got beaten up pretty badly though. Apr 14, 2015 at 18:42
  • 8
    This question should be re-opened. It's a question about how to write a program to solve the problem described (password authentication), with a short code solution. Seeing the trigger word "library" doesn't justify reflexively closing a question; he's not asking for a library recommendation, he's asking how to hash passwords. Edit: There, fixed it.
    – erickson
    Jul 30, 2015 at 13:36

12 Answers 12


You can actually use a facility built in to the Java runtime to do this. The SunJCE in Java 6 supports PBKDF2, which is a good algorithm to use for password hashing.

byte[] salt = new byte[16];
KeySpec spec = new PBEKeySpec("password".toCharArray(), salt, 65536, 128);
SecretKeyFactory f = SecretKeyFactory.getInstance("PBKDF2WithHmacSHA1");
byte[] hash = f.generateSecret(spec).getEncoded();
Base64.Encoder enc = Base64.getEncoder();
System.out.printf("salt: %s%n", enc.encodeToString(salt));
System.out.printf("hash: %s%n", enc.encodeToString(hash));

Here's a utility class that you can use for PBKDF2 password authentication:

import java.security.NoSuchAlgorithmException;
import java.security.SecureRandom;
import java.security.spec.InvalidKeySpecException;
import java.security.spec.KeySpec;
import java.util.Arrays;
import java.util.Base64;
import java.util.regex.Matcher;
import java.util.regex.Pattern;

import javax.crypto.SecretKeyFactory;
import javax.crypto.spec.PBEKeySpec;

 * Hash passwords for storage, and test passwords against password tokens.
 * Instances of this class can be used concurrently by multiple threads.
 * @author erickson
 * @see <a href="http://stackoverflow.com/a/2861125/3474">StackOverflow</a>
public final class PasswordAuthentication

   * Each token produced by this class uses this identifier as a prefix.
  public static final String ID = "$31$";

   * The minimum recommended cost, used by default
  public static final int DEFAULT_COST = 16;

  private static final String ALGORITHM = "PBKDF2WithHmacSHA1";

  private static final int SIZE = 128;

  private static final Pattern layout = Pattern.compile("\\$31\\$(\\d\\d?)\\$(.{43})");

  private final SecureRandom random;

  private final int cost;

  public PasswordAuthentication()

   * Create a password manager with a specified cost
   * @param cost the exponential computational cost of hashing a password, 0 to 30
  public PasswordAuthentication(int cost)
    iterations(cost); /* Validate cost */
    this.cost = cost;
    this.random = new SecureRandom();

  private static int iterations(int cost)
    if ((cost < 0) || (cost > 30))
      throw new IllegalArgumentException("cost: " + cost);
    return 1 << cost;

   * Hash a password for storage.
   * @return a secure authentication token to be stored for later authentication 
  public String hash(char[] password)
    byte[] salt = new byte[SIZE / 8];
    byte[] dk = pbkdf2(password, salt, 1 << cost);
    byte[] hash = new byte[salt.length + dk.length];
    System.arraycopy(salt, 0, hash, 0, salt.length);
    System.arraycopy(dk, 0, hash, salt.length, dk.length);
    Base64.Encoder enc = Base64.getUrlEncoder().withoutPadding();
    return ID + cost + '$' + enc.encodeToString(hash);

   * Authenticate with a password and a stored password token.
   * @return true if the password and token match
  public boolean authenticate(char[] password, String token)
    Matcher m = layout.matcher(token);
    if (!m.matches())
      throw new IllegalArgumentException("Invalid token format");
    int iterations = iterations(Integer.parseInt(m.group(1)));
    byte[] hash = Base64.getUrlDecoder().decode(m.group(2));
    byte[] salt = Arrays.copyOfRange(hash, 0, SIZE / 8);
    byte[] check = pbkdf2(password, salt, iterations);
    int zero = 0;
    for (int idx = 0; idx < check.length; ++idx)
      zero |= hash[salt.length + idx] ^ check[idx];
    return zero == 0;

  private static byte[] pbkdf2(char[] password, byte[] salt, int iterations)
    KeySpec spec = new PBEKeySpec(password, salt, iterations, SIZE);
    try {
      SecretKeyFactory f = SecretKeyFactory.getInstance(ALGORITHM);
      return f.generateSecret(spec).getEncoded();
    catch (NoSuchAlgorithmException ex) {
      throw new IllegalStateException("Missing algorithm: " + ALGORITHM, ex);
    catch (InvalidKeySpecException ex) {
      throw new IllegalStateException("Invalid SecretKeyFactory", ex);

   * Hash a password in an immutable {@code String}. 
   * <p>Passwords should be stored in a {@code char[]} so that it can be filled 
   * with zeros after use instead of lingering on the heap and elsewhere.
   * @deprecated Use {@link #hash(char[])} instead
  public String hash(String password)
    return hash(password.toCharArray());

   * Authenticate with a password in an immutable {@code String} and a stored 
   * password token. 
   * @deprecated Use {@link #authenticate(char[],String)} instead.
   * @see #hash(String)
  public boolean authenticate(String password, String token)
    return authenticate(password.toCharArray(), token);

  • 11
    You may want to be a bit wary of byte to hex conversions with BigInteger: leading zeros are removed. That's ok for quick debug, but I have seen bugs in production code due to that effect. May 19, 2010 at 12:21
  • 24
    @thomas-pornin's highlights why we need a library, not a code block that's almost there. Scary that the accepted answer does not answer the question on such an important topic.
    – Nilzor
    Apr 24, 2013 at 18:40
  • 10
    Use the algorithm PBKDF2WithHmacSHA512 starting with Java 8. It is a bit stronger.
    – iwan.z
    Nov 3, 2014 at 13:05
  • 1
    Note, existing algs are not deleted in later versions: java_4:PBEWithMD5AndDES,DESede,DES java_5/6/7:PBKDF2WithHmacSHA1,PBE (only in Java 5),PBEWithSHA1AndRC2_40,PBEWithSHA1And,PBEWithMD5AndTriple java_8:PBEWithHmacSHA224AndAES_128, PBEWithHmacSHA384AndAES_128, PBEWithHmacSHA512AndAES_128, RC4_40, PBKDF2WithHmacSHA256, PBEWithHmacSHA1AndAES_128, RC4_128, PBKDF2WithHmacSHA224, PBEWithHmacSHA256AndAES_256, RC2_128, PBEWithHmacSHA224AndAES_256, PBEWithHmacSHA384AndAES_256,PBEWithHmacSHA512AndAES_256,PBKDF2WithHmacSHA512,PBEWithHmacSHA256AndAES_128, PBKDF2WithHmacSHA384,PBEWithHmacSHA1AndAES_256
    – iwan.z
    Nov 5, 2014 at 6:26
  • 4
    @TheTosters Yes, the execution time will be longer for incorrect passwords; more specifically, wrong passwords will take the same time as correct passwords. It prevents timing attacks, although I confess I can't think of a practical way to exploit such a vulnerability in this case. But you don't cut corners. Just because I can't see it, doesn't mean a more devious mind won't.
    – erickson
    Nov 22, 2016 at 21:40

BCrypt is a very good library, and there is a Java port of it.


You could use Spring Security Crypto (has only 2 optional compile dependencies), which supports PBKDF2, BCrypt, SCrypt and Argon2 password encryption.

Argon2PasswordEncoder argon2PasswordEncoder = new Argon2PasswordEncoder();
String aCryptedPassword = argon2PasswordEncoder.encode("password");
boolean passwordIsValid = argon2PasswordEncoder.matches("password", aCryptedPassword);
SCryptPasswordEncoder sCryptPasswordEncoder = new SCryptPasswordEncoder();
String sCryptedPassword = sCryptPasswordEncoder.encode("password");
boolean passwordIsValid = sCryptPasswordEncoder.matches("password", sCryptedPassword);
BCryptPasswordEncoder bCryptPasswordEncoder = new BCryptPasswordEncoder();
String bCryptedPassword = bCryptPasswordEncoder.encode("password");
boolean passwordIsValid = bCryptPasswordEncoder.matches("password", bCryptedPassword);
Pbkdf2PasswordEncoder pbkdf2PasswordEncoder = new Pbkdf2PasswordEncoder();
String pbkdf2CryptedPassword = pbkdf2PasswordEncoder.encode("password");
boolean passwordIsValid = pbkdf2PasswordEncoder.matches("password", pbkdf2CryptedPassword);

You can comput hashes using MessageDigest, but this is wrong in terms of security. Hashes are not to be used for storing passwords, as they are easily breakable.

You should use another algorithm like bcrypt, PBKDF2 and scrypt to store you passwords. See here.

  • 3
    How would you hash the password at login without storing salt in database?
    – ZZ Coder
    May 18, 2010 at 20:43
  • 9
    Using the username as the salt is not a fatal flaw, but it's nowhere near as good as using a salt from a cryptographic RNG. And there is absolutely no problem storing the salt in the database. The salt is not secret.
    – erickson
    May 18, 2010 at 20:44
  • 1
    Wouldn't the username and e-mail also be stored in the database? May 18, 2010 at 20:47
  • @ZZ Coder, @erickson correct, I somehow assumed that it will be one salt for all passwords, which would lead to an easily computable rainbow table.
    – Bozho
    May 18, 2010 at 21:12
  • 14
    One problem with using the username (or other ID like email) as a salt is that you can't then change the ID without having the user also set a new password. May 19, 2010 at 2:37

You can use the Shiro library's (formerly JSecurity) implementation of what is described by OWASP.

It also looks like the JASYPT library has a similar utility.

  • Thats actually what I was using. But since we decided not to use Shiro, there was some concern about the inefficiency of having to include the whole Shiro library for just that one package. May 18, 2010 at 21:15
  • I don't know of a library made up of just a password hashing utility. You're probably better off rolling your own if dependencies are a concern. The answer by erickson looks pretty good to me. Or just copy the code from that OWASP link I referenced if you'd rather use SHA in a secure manner.
    – laz
    May 18, 2010 at 21:26

In addition to bcrypt and PBKDF2 mentioned in other answers, I would recommend looking at scrypt

MD5 and SHA-1 are not recommended as they are relatively fast thus using "rent per hour" distributed computing (e.g. EC2) or a modern high end GPU one can "crack" passwords using brute force / dictionary attacks in relatively low costs and reasonable time.

If you must use them, then at least iterate the algorithm a predefined significant amount of times (1000+).


Fully agree with Erickson that PBKDF2 is the answer.

If you don't have that option, or only need to use a hash, Apache Commons DigestUtils is much easier than getting JCE code right: https://commons.apache.org/proper/commons-codec/apidocs/org/apache/commons/codec/digest/DigestUtils.html

If you use a hash, go with sha256 or sha512. This page has good recommendations on password handling and hashing (note it doesn't recommend hashing for password handling): http://www.daemonology.net/blog/2009-06-11-cryptographic-right-answers.html

  • it's worth noting that SHA512 isn't better than SHA256 (for this purpose) just because the number is bigger.
    – Azsgy
    Mar 27, 2019 at 15:51

While the NIST recommendation PBKDF2 has already been mentioned, I'd like to point out that there was a public password hashing competition that ran from 2013 to 2015. In the end, Argon2 was chosen as the recommended password hashing function.

There is a fairly well adopted Java binding for the original (native C) library that you can use.

In the average use-case, I don't think it does matter from a security perspective if you choose PBKDF2 over Argon2 or vice-versa. If you have strong security requirements, I recommend considering Argon2 in your evaluation.

For further information on the security of password hashing functions see security.se.

  • @zaph I edited the answer to be more objective. Please be aware that the NIST recommendation may not always be the best choice (see here for an example) - of course this is true for anything that is recommended somewhere else as well. Therefore I do think this answer provides a value to this question.
    – Qw3ry
    Jul 5, 2017 at 10:37

Here you have two links for MD5 hashing and other hash methods:

Javadoc API: https://docs.oracle.com/javase/1.5.0/docs/api/java/security/MessageDigest.html

Tutorial: http://www.twmacinta.com/myjava/fast_md5.php

  • 3
    Just keep in mind that for password hashing, slower is better. You should use thousands of iterations of the hash function as a "key strengthening" technique. Also, salt is imperative.
    – erickson
    May 18, 2010 at 21:08
  • I was under the impression that multiple iterations of a quality hashing algorithm would produce about the same security as one iteration since the length of bytes would still be the same? May 18, 2010 at 21:17
  • @erickson It would be better to slow down attackers explicitly.
    – deamon
    May 18, 2010 at 21:18
  • 6
    About key strengthening: Salts exist to make precomputed hashes unusable. But attackers do not have to precompute. Attackers can just hash strings + salt "on the fly" until they find the right one. But if you iterate thousands of times for your hashes they will have to do the same. Your server will not be impacted much by 10k iterations as it doesn't happen that often. Attackers will need 10k times the computing power.
    – zockman
    May 19, 2010 at 6:26
  • 2
    @Simon today MD5 is considered useless for password hashing as it can be cracked in seconds using GPU brute force / dictionary attacks. See here: codahale.com/how-to-safely-store-a-password
    – Eran Medan
    Nov 21, 2012 at 7:27

As of 2020, the most reliable password hashing algorithm in use, most likely to optimise its strength given any hardware, is Argon2id or Argon2i but not its Spring implementation.

The PBKDF2 standard includes the the CPU-greedy/computationally-expensive feature of the block cipher BCRYPT algo, and add its stream cipher capability. PBKDF2 was overwhelmed by the memory exponentially-greedy SCRYPT then by the side-channel-attack-resistant Argon2

Argon2 provides the necessary calibration tool to find optimized strength parameters given a target hashing time and the hardware used.

  • Argon2i is specialized in memory greedy hashing
  • Argon2d is specialized in CPU greedy hashing
  • Argon2id use both methods.

Memory greedy hashing would help against GPU use for cracking.

Spring security/Bouncy Castle implementation is not optimized and relatively week given what attacker could use. cf: Spring doc Argon2 and Scrypt

The currently implementation uses Bouncy castle which does not exploit parallelism/optimizations that password crackers will, so there is an unnecessary asymmetry between attacker and defender.

The most credible implementation in use for java is mkammerer's one,

a wrapper jar/library of the official native implementation written in C.

It is well written and simple to use.

The embedded version provides native builds for Linux, windows and OSX.

As an example, it is used by jpmorganchase in its tessera security project used to secure Quorum, its Ethereum cryptocurency implementation.

Here is an example:

    final char[] password = "a4e9y2tr0ngAnd7on6P১M°RD".toCharArray();
    byte[] salt = new byte[128];
    new SecureRandom().nextBytes(salt);
    final Argon2Advanced argon2 = Argon2Factory.createAdvanced(Argon2Factory.Argon2Types.ARGON2id);
    byte[] hash = argon2.rawHash(10, 1048576, 4, password, salt);

(see tessera)

Declare the lib in your POM:


or with gradle:

compile 'de.mkammerer:argon2-jvm:2.7'

Calibration may be performed using de.mkammerer.argon2.Argon2Helper#findIterations

SCRYPT and Pbkdf2 algorithm might also be calibrated by writing some simple benchmark, but current minimal safe iterations values, will require higher hashing times.


Among all the standard hash schemes, LDAP ssha is the most secure one to use,


I would just follow the algorithms specified there and use MessageDigest to do the hash.

You need to store the salt in your database as you suggested.

  • 1
    Because SSHA doesn't iterate the hash function, it is too fast. This allows attackers to try passwords more quickly. Better algorithms like Bcrypt, PBBKDF1, and PBKDF2 use "key strengthening" techniques to slow attackers to the point where a password should expire before they can brute force even an 8-letter password space.
    – erickson
    May 18, 2010 at 21:14
  • The problem with all these mechanisms is that you don't get client support. The problem with hashed password is that you can't support password hashed with another algorithms. With ssha, at least all the LDAP clients support it.
    – ZZ Coder
    May 18, 2010 at 21:19
  • It is not "most secure" it is merely "pretty compatible". bcrypt/scrypt are way more ressource intensitive.
    – eckes
    Nov 22, 2012 at 16:44

i leaned that from a video on udemy and edited to be stronger random password


private String pass() {
        String passswet="1234567890zxcvbbnmasdfghjklop[iuytrtewq@#$%^&*" ;

        char icon1;
        char[] t=new char[20];

         int rand1=(int)(Math.random()*6)+38;//to make a random within the range of special characters

            icon1=passswet.charAt(rand1);//will produce char with a special character

        int i=0;
        while( i <11) {

             int rand=(int)(Math.random()*passswet.length());
             //notice (int) as the original value of Math>random() is double

             t[i] =passswet.charAt(rand);

//to replace the specified item with icon1
        return new String(t);

  • I'm open to being corrected, but I think you shouldn't use random numbers when hashing. This is so that your hash function remains deterministic; that is if you hash a string multiple times you will always get the same hash value back for that string.
    – duldi
    Jun 6, 2020 at 1:29

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