1973

I've been looking for a simple Java algorithm to generate a pseudo-random alpha-numeric string. In my situation it would be used as a unique session/key identifier that would "likely" be unique over 500K+ generation (my needs don't really require anything much more sophisticated).

Ideally, I would be able to specify a length depending on my uniqueness needs. For example, a generated string of length 12 might look something like "AEYGF7K0DM1X".

8
  • 166
    Beware the birthday paradox. Oct 25, 2010 at 15:07
  • 64
    Even taking the birthday paradox in consideration, if you use 12 alphanumeric characters (62 total), you would still need well over 34 billion strings to reach the paradox. And the birthday paradox doesn't guarantee a collision anyways, it just says it's over 50% chance. Oct 29, 2012 at 4:13
  • 6
    @NullUserException 50 % success chance (per try) is damn high: even with 10 attempts, success rate is 0.999. With that and the fact that you can try A LOT in a period of 24 hours in mind, you don't need 34 billion strings to be pretty sure to guess at least one of them. That is the reason why some session tokens should be really, really long.
    – Pijusn
    Jan 31, 2015 at 10:28
  • 20
    These 3 single line codes are very much useful i guess.. Long.toHexString(Double.doubleToLongBits(Math.random())); UUID.randomUUID().toString(); RandomStringUtils.randomAlphanumeric(12);
    – Manindar
    Jun 8, 2016 at 7:31
  • 25
    @Pijusn I know this is old, but... the "50% chance" in the birthday paradox is NOT "per try", it's "50% chance that, out of (in this case) 34 billion strings, there exists at least one pair of duplicates". You'd need 1.6 septillion - 1.6e21 - entries in your database in order for there to be a 50% chance per try.
    – Tin Wizard
    Oct 11, 2017 at 19:21

46 Answers 46

1634

Algorithm

To generate a random string, concatenate characters drawn randomly from the set of acceptable symbols until the string reaches the desired length.

Implementation

Here's some fairly simple and very flexible code for generating random identifiers. Read the information that follows for important application notes.

public class RandomString {

    /**
     * Generate a random string.
     */
    public String nextString() {
        for (int idx = 0; idx < buf.length; ++idx)
            buf[idx] = symbols[random.nextInt(symbols.length)];
        return new String(buf);
    }

    public static final String upper = "ABCDEFGHIJKLMNOPQRSTUVWXYZ";

    public static final String lower = upper.toLowerCase(Locale.ROOT);

    public static final String digits = "0123456789";

    public static final String alphanum = upper + lower + digits;

    private final Random random;

    private final char[] symbols;

    private final char[] buf;

    public RandomString(int length, Random random, String symbols) {
        if (length < 1) throw new IllegalArgumentException();
        if (symbols.length() < 2) throw new IllegalArgumentException();
        this.random = Objects.requireNonNull(random);
        this.symbols = symbols.toCharArray();
        this.buf = new char[length];
    }

    /**
     * Create an alphanumeric string generator.
     */
    public RandomString(int length, Random random) {
        this(length, random, alphanum);
    }

    /**
     * Create an alphanumeric strings from a secure generator.
     */
    public RandomString(int length) {
        this(length, new SecureRandom());
    }

    /**
     * Create session identifiers.
     */
    public RandomString() {
        this(21);
    }

}

Usage examples

Create an insecure generator for 8-character identifiers:

RandomString gen = new RandomString(8, ThreadLocalRandom.current());

Create a secure generator for session identifiers:

RandomString session = new RandomString();

Create a generator with easy-to-read codes for printing. The strings are longer than full alphanumeric strings to compensate for using fewer symbols:

String easy = RandomString.digits + "ACEFGHJKLMNPQRUVWXYabcdefhijkprstuvwx";
RandomString tickets = new RandomString(23, new SecureRandom(), easy);

Use as session identifiers

Generating session identifiers that are likely to be unique is not good enough, or you could just use a simple counter. Attackers hijack sessions when predictable identifiers are used.

There is tension between length and security. Shorter identifiers are easier to guess, because there are fewer possibilities. But longer identifiers consume more storage and bandwidth. A larger set of symbols helps, but might cause encoding problems if identifiers are included in URLs or re-entered by hand.

The underlying source of randomness, or entropy, for session identifiers should come from a random number generator designed for cryptography. However, initializing these generators can sometimes be computationally expensive or slow, so effort should be made to re-use them when possible.

Use as object identifiers

Not every application requires security. Random assignment can be an efficient way for multiple entities to generate identifiers in a shared space without any coordination or partitioning. Coordination can be slow, especially in a clustered or distributed environment, and splitting up a space causes problems when entities end up with shares that are too small or too big.

Identifiers generated without taking measures to make them unpredictable should be protected by other means if an attacker might be able to view and manipulate them, as happens in most web applications. There should be a separate authorization system that protects objects whose identifier can be guessed by an attacker without access permission.

Care must be also be taken to use identifiers that are long enough to make collisions unlikely given the anticipated total number of identifiers. This is referred to as "the birthday paradox." The probability of a collision, p, is approximately n2/(2qx), where n is the number of identifiers actually generated, q is the number of distinct symbols in the alphabet, and x is the length of the identifiers. This should be a very small number, like 2‑50 or less.

Working this out shows that the chance of collision among 500k 15-character identifiers is about 2‑52, which is probably less likely than undetected errors from cosmic rays, etc.

Comparison with UUIDs

According to their specification, UUIDs are not designed to be unpredictable, and should not be used as session identifiers.

UUIDs in their standard format take a lot of space: 36 characters for only 122 bits of entropy. (Not all bits of a "random" UUID are selected randomly.) A randomly chosen alphanumeric string packs more entropy in just 21 characters.

UUIDs are not flexible; they have a standardized structure and layout. This is their chief virtue as well as their main weakness. When collaborating with an outside party, the standardization offered by UUIDs may be helpful. For purely internal use, they can be inefficient.

15
  • 6
    If you need spaces in yours, you can tack on .replaceAll("\\d", " "); onto the end of the return new BigInteger(130, random).toString(32); line to do a regex swap. It replaces all digits with spaces. Works great for me: I'm using this as a substitute for a front-end Lorem Ipsum
    – weisjohn
    Oct 7, 2011 at 15:00
  • 4
    @weisjohn That's a good idea. You can do something similar with the second method, by removing the digits from symbols and using a space instead; you can control the average "word" length by changing the number of spaces in symbols (more occurrences for shorter words). For a really over-the-top fake text solution, you can use a Markov chain!
    – erickson
    Oct 7, 2011 at 16:02
  • 4
    These identifiers are randomly selected from space of a certain size. They could be 1 character long. If you want a fixed length, you can use the second solution, with a SecureRandom instance assigned to the random variable.
    – erickson
    Dec 20, 2011 at 0:15
  • 17
    @ejain because 32 = 2^5; each character will represent exactly 5 bits, and 130 bits can be evenly divided into characters.
    – erickson
    Feb 21, 2012 at 21:38
  • 3
    @erickson BigInteger.toString(int) doesn't work that way, it's actually calling Long.toString(long, String) to determine the character values (which gives a better JavaDoc description of what it actually does). Essentially doing BigInteger.toString(32) just means you only get characters 0-9 + a-v rather than 0-9 + a-z.
    – Vala
    Aug 29, 2012 at 15:51
894

Java supplies a way of doing this directly. If you don't want the dashes, they are easy to strip out. Just use uuid.replace("-", "")

import java.util.UUID;

public class randomStringGenerator {
    public static void main(String[] args) {
        System.out.println(generateString());
    }

    public static String generateString() {
        String uuid = UUID.randomUUID().toString();
        return "uuid = " + uuid;
    }
}

Output

uuid = 2d7428a6-b58c-4008-8575-f05549f16316
12
  • 36
    Beware that this solution only generates a random string with hexadecimal characters. Which can be fine in some cases.
    – Dave
    May 5, 2011 at 9:28
  • 6
    The UUID class is useful. However, they aren't as compact as the identifiers produced by my answers. This can be an issue, for example, in URLs. Depends on your needs.
    – erickson
    Aug 24, 2011 at 16:37
  • 6
    @Ruggs - The goal is alpha-numeric strings. How does broadening the output to any possible bytes fit with that?
    – erickson
    Oct 7, 2011 at 16:18
  • 76
    According to RFC4122 using UUID's as tokens is a bad idea: Do not assume that UUIDs are hard to guess; they should not be used as security capabilities (identifiers whose mere possession grants access), for example. A predictable random number source will exacerbate the situation. ietf.org/rfc/rfc4122.txt
    – Somatik
    Dec 31, 2012 at 11:31
  • 39
    UUID.randomUUID().toString().replaceAll("-", ""); makes the string alpha-numeric, as requested.
    – Numid
    Jan 22, 2014 at 9:58
637
static final String AB = "0123456789ABCDEFGHIJKLMNOPQRSTUVWXYZabcdefghijklmnopqrstuvwxyz";
static SecureRandom rnd = new SecureRandom();

String randomString(int len){
   StringBuilder sb = new StringBuilder(len);
   for(int i = 0; i < len; i++)
      sb.append(AB.charAt(rnd.nextInt(AB.length())));
   return sb.toString();
}
8
  • 72
    +1, the simplest solution here for generating a random string of specified length (apart from using RandomStringUtils from Commons Lang).
    – Jonik
    Apr 20, 2012 at 15:49
  • 15
    Consider using SecureRandom instead of the Random class. If passwords are generated on a server, it might be vulnerable to timing attacks.
    – foens
    Jun 25, 2014 at 13:34
  • 10
    I would add lowercase also: AB = "0123456789ABCDEFGHIJKLMNOPQRSTUVWXYZabcdefghijklmnopqrstuvwxyz"; and some other allowed chars.
    – ACV
    Sep 7, 2015 at 20:56
  • 1
    Why not put static Random rnd = new Random(); inside the method?
    – Micro
    Feb 8, 2016 at 1:25
  • 6
    @MicroR Is there a good reason to create the Random object in each method invocation? I don't think so. Feb 15, 2016 at 10:49
504

If you're happy to use Apache classes, you could use org.apache.commons.text.RandomStringGenerator (Apache Commons Text).

Example:

RandomStringGenerator randomStringGenerator =
        new RandomStringGenerator.Builder()
                .withinRange('0', 'z')
                .filteredBy(CharacterPredicates.LETTERS, CharacterPredicates.DIGITS)
                .build();
randomStringGenerator.generate(12); // toUpperCase() if you want

Since Apache Commons Lang 3.6, RandomStringUtils is deprecated.

5
  • 24
    Has just looked through mentioned class of Apache Commons Lang 3.3.1 library - and it is using only java.util.Random to provide random sequences, so it is producing insecure sequences. Apr 3, 2014 at 14:51
  • 16
    Make sure you use SecureRandom when using RandomStringUtils: public static java.lang.String random(int count, int start, int end, boolean letters, boolean numbers, @Nullable char[] chars, java.util.Random random) Mar 3, 2015 at 13:28
  • DO NOT USE. This creates insecure sequences!
    – Patrick
    Apr 4, 2019 at 13:03
  • 2
    Build your RandomStringGenerator using this so that the sequences are secure: new RandomStringGenerator.Builder().usingRandom(RANDOM::nextInt).build();
    – Rohan
    Sep 14, 2020 at 21:36
  • 1
    @YuriyNakonechnyy return RandomStringUtils.random(12, 0, length, true, true,characterSetArray, new SecureRandom()); here characterSetArray is the set of characters you would want. Example (say all numbers and all small cases) will be "0123456789abcdefghijklmnopqrstuvwxyz".toCharArray(). And length is the length of characterArray Sep 6, 2021 at 12:03
146

You can use an Apache Commons library for this, RandomStringUtils:

RandomStringUtils.randomAlphanumeric(20).toUpperCase();
10
  • 20
    @kamil, I looked at the source code for RandomStringUtils, and it uses an instance of java.util.Random instantiated without arguments. The documentation for java.util.Random says it uses current system time if no seed is provided. This means that it can not be used for session identifiers/keys since an attacker can easily predict what the generated session identifiers are at any given time.
    – Inshallah
    Sep 26, 2012 at 10:14
  • 44
    @Inshallah : You are (unnecessarily) overengineering the system. While I agree that it uses time as seed, the attacker has to have the access to following data to to actually get what he wants 1. Time to the exact millisecond, when the code was seeded 2. Number of calls that have occurred so far 3. Atomicity for his own call (so that number of calls-so-far ramains same) If your attacker has all three of these things, then you have much bigger issue at hand... Oct 13, 2013 at 23:36
  • 4
    gradle dependency: compile 'commons-lang:commons-lang:2.6'
    – younes0
    Jan 19, 2015 at 14:35
  • 5
    @Ajeet this isn't true. You can derive the state of the random number generator from its output. If an attacker can generate a few thousand calls to generate random API tokens the attacker will be able to predict all future API tokens. Dec 20, 2016 at 13:52
  • 5
    @AjeetGanga Nothing to do with over engineering. If you want to create session ids, you need a cryptographic pseudo random generator. Every prng using time as seed is predictable and very insecure for data that should be unpredictable. Just use SecureRandom and you are good.
    – Patrick
    Sep 19, 2017 at 10:37
115

In one line:

Long.toHexString(Double.doubleToLongBits(Math.random()));

Source: Java - generating a random string

5
  • 2
    It helped me too but only hexadecimal digits :(
    – noquery
    Sep 5, 2011 at 5:31
  • @Zippoxer, you could concat that several times =) May 17, 2014 at 15:10
  • 7
    The OP's example showed the following String as an example AEYGF7K0DM1X which is not hexadecimal. It worries me how often people mistake alphanumeric with hexadecimal. They are not the same thing.
    – hfontanez
    Nov 20, 2014 at 2:31
  • @daniel.bavrin, Zippoxer means hexadecimal string has only 6 letters (ABCDEF). He is not talking about the length, it doesn't matter how many times you concat Jan 16, 2015 at 8:34
  • 9
    This is much less random than it should be given the string length as Math.random() produces a double between 0 and 1, so the exponent part is mostly unused. Use random.nextLong for a random long instead of this ugly hack.
    – maaartinus
    Jul 22, 2015 at 1:13
91

This is easily achievable without any external libraries.

1. Cryptographic Pseudo Random Data Generation (PRNG)

First you need a cryptographic PRNG. Java has SecureRandom for that and typically uses the best entropy source on the machine (e.g. /dev/random). Read more here.

SecureRandom rnd = new SecureRandom();
byte[] token = new byte[byteLength];
rnd.nextBytes(token);

Note: SecureRandom is the slowest, but most secure way in Java of generating random bytes. I do however recommend not considering performance here since it usually has no real impact on your application unless you have to generate millions of tokens per second.

2. Required Space of Possible Values

Next you have to decide "how unique" your token needs to be. The whole and only point of considering entropy is to make sure that the system can resist brute force attacks: the space of possible values must be so large that any attacker could only try a negligible proportion of the values in non-ludicrous time1.

Unique identifiers such as random UUID have 122 bits of entropy (i.e., 2^122 = 5.3x10^36) - the chance of collision is "*(...) for there to be a one in a billion chance of duplication, 103 trillion version 4 UUIDs must be generated2". We will choose 128 bits since it fits exactly into 16 bytes and is seen as highly sufficient for being unique for basically every, but the most extreme, use cases, and you don't have to think about duplicates. Here is a simple comparison table of entropy including simple analysis of the birthday problem.

Comparison of token sizes

For simple requirements, 8 or 12 byte length might suffice, but with 16 bytes you are on the "safe side".

And that's basically it. The last thing is to think about encoding, so it can be represented as a printable text (read, a String).

3. Binary to Text Encoding

Typical encodings include:

  • Base64 every character encodes 6 bits, creating a 33% overhead. Fortunately there are standard implementations in Java 8+ and Android. With older Java you can use any of the numerous third-party libraries. If you want your tokens to be URL safe use the URL-safe version of RFC4648 (which usually is supported by most implementations). Example encoding 16 bytes with padding: XfJhfv3C0P6ag7y9VQxSbw==

  • Base32 every character encodes 5 bits, creating a 40% overhead. This will use A-Z and 2-7, making it reasonably space efficient while being case-insensitive alphanumeric. There isn't any standard implementation in the JDK. Example encoding 16 bytes without padding: WUPIL5DQTZGMF4D3NX5L7LNFOY

  • Base16 (hexadecimal) every character encodes four bits, requiring two characters per byte (i.e., 16 bytes create a string of length 32). Therefore, hexadecimal is less space efficient than Base32, but it is safe to use in most cases (URL) since it only uses 0-9 and A to F. Example encoding 16 bytes: 4fa3dd0f57cb3bf331441ed285b27735. See a Stack Overflow discussion about converting to hexadecimal here.

Additional encodings like Base85 and the exotic Base122 exist with better/worse space efficiency. You can create your own encoding (which basically most answers in this thread do), but I would advise against it, if you don't have very specific requirements. See more encoding schemes in the Wikipedia article.

4. Summary and Example

  • Use SecureRandom
  • Use at least 16 bytes (2^128) of possible values
  • Encode according to your requirements (usually hex or base32 if you need it to be alphanumeric)

Don't

  • ... use your home brew encoding: better maintainable and readable for others if they see what standard encoding you use instead of weird for loops creating characters at a time.
  • ... use UUID: it has no guarantees on randomness; you are wasting 6 bits of entropy and have a verbose string representation

Example: Hexadecimal Token Generator

public static String generateRandomHexToken(int byteLength) {
    SecureRandom secureRandom = new SecureRandom();
    byte[] token = new byte[byteLength];
    secureRandom.nextBytes(token);
    return new BigInteger(1, token).toString(16); // Hexadecimal encoding (omits leading zeros)
}

//generateRandomHexToken(16) -> 2189df7475e96aa3982dbeab266497cd

Example: Base64 Token Generator (URL Safe)

public static String generateRandomBase64Token(int byteLength) {
    SecureRandom secureRandom = new SecureRandom();
    byte[] token = new byte[byteLength];
    secureRandom.nextBytes(token);
    return Base64.getUrlEncoder().withoutPadding().encodeToString(token); //base64 encoding
}

//generateRandomBase64Token(16) -> EEcCCAYuUcQk7IuzdaPzrg

Example: Java CLI Tool

If you want a ready-to-use CLI tool you may use dice:

Example: Related issue - Protect Your Current IDs

If you already have an ID you can use (e.g., a synthetic long in your entity), but don't want to publish the internal value, you can use this library to encrypt it and obfuscate it: https://github.com/patrickfav/id-mask

IdMask<Long> idMask = IdMasks.forLongIds(Config.builder(key).build());
String maskedId = idMask.mask(id);
// Example: NPSBolhMyabUBdTyanrbqT8
long originalId = idMask.unmask(maskedId);
7
  • 3
    This answer is complete and works without adding any dependency. If you want to avoid possible minus signs in the output, you can prevent negative BigIntegers using a constructor parameter: BigInteger(1, token) instead of BigInteger(token).
    – francoisr
    Jul 11, 2017 at 7:50
  • Tanks @francoisr for the hint, I edited the code example
    – Patrick
    Jul 11, 2017 at 8:38
  • import java.security.SecureRandom; and import java.math.BigInteger; are needed to make the example work, but it works great!
    – anothermh
    Oct 4, 2018 at 1:45
  • Good answer but /dev/random is a blocking method which is the reason it is slow to the point of blocking if entropy is too low. The better and non-blocking method is /dev/urandom. This can be configured via <jre>/lib/security/java.security and set securerandom.source=file:/dev/./urandom
    – Muzammil
    May 10, 2020 at 16:27
  • @Muzammil See tersesystems.com/blog/2015/12/17/… (also linked in the answer) - new SecureRandom() uses /dev/urandom
    – Patrick
    May 11, 2020 at 8:25
42

Using Dollar should be as simple as:

// "0123456789" + "ABCDE...Z"
String validCharacters = $('0', '9').join() + $('A', 'Z').join();

String randomString(int length) {
    return $(validCharacters).shuffle().slice(length).toString();
}

@Test
public void buildFiveRandomStrings() {
    for (int i : $(5)) {
        System.out.println(randomString(12));
    }
}

It outputs something like this:

DKL1SBH9UJWC
JH7P0IT21EA5
5DTI72EO6SFU
HQUMJTEBNF7Y
1HCR6SKYWGT7
1
  • is it possible to use SecureRandom with shuffle?
    – iwein
    Nov 16, 2016 at 10:58
36

Here it is in Java:

import static java.lang.Math.round;
import static java.lang.Math.random;
import static java.lang.Math.pow;
import static java.lang.Math.abs;
import static java.lang.Math.min;
import static org.apache.commons.lang.StringUtils.leftPad

public class RandomAlphaNum {
  public static String gen(int length) {
    StringBuffer sb = new StringBuffer();
    for (int i = length; i > 0; i -= 12) {
      int n = min(12, abs(i));
      sb.append(leftPad(Long.toString(round(random() * pow(36, n)), 36), n, '0'));
    }
    return sb.toString();
  }
}

Here's a sample run:

scala> RandomAlphaNum.gen(42)
res3: java.lang.String = uja6snx21bswf9t89s00bxssu8g6qlu16ffzqaxxoy
2
  • 4
    This will produce insecure sequences i.e. sequences which can be easily guessed. Apr 3, 2014 at 14:53
  • 9
    All this double-infested random int generation is broken by design, slow and unreadable. Use Random#nextInt or nextLong. Switch to SecureRandom if needed.
    – maaartinus
    Jul 22, 2015 at 1:17
35

A short and easy solution, but it uses only lowercase and numerics:

Random r = new java.util.Random ();
String s = Long.toString (r.nextLong () & Long.MAX_VALUE, 36);

The size is about 12 digits to base 36 and can't be improved further, that way. Of course you can append multiple instances.

5
  • 11
    Just keep in mind, that there is a 50 % chance of a minus sign infront of the result ! So wrapping r.nextLong() in a Math.abs() can be used, if you don't want the minus sign: Long.toString(Math.abs(r.nextLong()), 36);
    – Ray Hulha
    Jan 27, 2013 at 2:12
  • 5
    @RayHulha: If you don't want the minus sign, you should cut it off, because, surprisingly, Math.abs returns a negative value for Long.MIN_VALUE. Jan 27, 2013 at 13:28
  • Interesting the Math.abs returning negative. More here: bmaurer.blogspot.co.nz/2006/10/…
    – Phil
    Nov 10, 2013 at 20:34
  • 1
    The issue with abs is solved by using a bitwise operator to clear the most significant bit. This will work for all values.
    – Radiodef
    Apr 2, 2018 at 23:27
  • 1
    @Radiodef That's essentially what @userunkown said. I suppose you could also do << 1 >>> 1.
    – shmosel
    Apr 2, 2018 at 23:35
32

Surprising, no one here has suggested it, but:

import java.util.UUID

UUID.randomUUID().toString();

Easy.

The benefit of this is UUIDs are nice, long, and guaranteed to be almost impossible to collide.

Wikipedia has a good explanation of it:

" ...only after generating 1 billion UUIDs every second for the next 100 years, the probability of creating just one duplicate would be about 50%."

The first four bits are the version type and two for the variant, so you get 122 bits of random. So if you want to, you can truncate from the end to reduce the size of the UUID. It's not recommended, but you still have loads of randomness, enough for your 500k records easy.

1
18

An alternative in Java 8 is:

static final Random random = new Random(); // Or SecureRandom
static final int startChar = (int) '!';
static final int endChar = (int) '~';

static String randomString(final int maxLength) {
  final int length = random.nextInt(maxLength + 1);
  return random.ints(length, startChar, endChar + 1)
        .collect(StringBuilder::new, StringBuilder::appendCodePoint, StringBuilder::append)
        .toString();
}
1
  • 3
    That's great - but if you want to keep it to strictly alphanumeric (0-9, a-z, A-Z) see here rationaljava.com/2015/06/…
    – Dan
    Jun 23, 2015 at 14:08
12
public static String generateSessionKey(int length){
    String alphabet =
        new String("0123456789ABCDEFGHIJKLMNOPQRSTUVWXYZabcdefghijklmnopqrstuvwxyz"); // 9

    int n = alphabet.length(); // 10

    String result = new String();
    Random r = new Random(); // 11

    for (int i=0; i<length; i++) // 12
        result = result + alphabet.charAt(r.nextInt(n)); //13

    return result;
}
1
  • An explanation would be in order. Nov 12, 2020 at 15:47
11
import java.util.Random;

public class passGen{
    // Version 1.0
    private static final String dCase = "abcdefghijklmnopqrstuvwxyz";
    private static final String uCase = "ABCDEFGHIJKLMNOPQRSTUVWXYZ";
    private static final String sChar = "!@#$%^&*";
    private static final String intChar = "0123456789";
    private static Random r = new Random();
    private static StringBuilder pass = new StringBuilder();

    public static void main (String[] args) {
        System.out.println ("Generating pass...");
        while (pass.length () != 16){
            int rPick = r.nextInt(4);
            if (rPick == 0){
                int spot = r.nextInt(26);
                pass.append(dCase.charAt(spot));
            } else if (rPick == 1) {
                int spot = r.nextInt(26);
                pass.append(uCase.charAt(spot));
            } else if (rPick == 2) {
                int spot = r.nextInt(8);
                pass.append(sChar.charAt(spot));
            } else {
                int spot = r.nextInt(10);
                pass.append(intChar.charAt(spot));
            }
        }
        System.out.println ("Generated Pass: " + pass.toString());
    }
}

This just adds the password into the string and... yeah, it works well. Check it out... It is very simple; I wrote it.

1
  • 1
    I allowed myself to make some minor modifications. Why do you add + 0 that often? Why do you split declaration of spot and initialisxation? What is the advantage of indexes 1,2,3,4 instead of 0,1,2,3? Most importantly: you took a random value, and compared with if-else 4 times a new value, which could always mismatch, without gaining more randomness. But feel free to rollback. Apr 17, 2012 at 9:50
11

Using UUIDs is insecure, because parts of the UUID aren't random at all. The procedure of erickson is very neat, but it does not create strings of the same length. The following snippet should be sufficient:

/*
 * The random generator used by this class to create random keys.
 * In a holder class to defer initialization until needed.
 */
private static class RandomHolder {
    static final Random random = new SecureRandom();
    public static String randomKey(int length) {
        return String.format("%"+length+"s", new BigInteger(length*5/*base 32,2^5*/, random)
            .toString(32)).replace('\u0020', '0');
    }
}

Why choose length*5? Let's assume the simple case of a random string of length 1, so one random character. To get a random character containing all digits 0-9 and characters a-z, we would need a random number between 0 and 35 to get one of each character.

BigInteger provides a constructor to generate a random number, uniformly distributed over the range 0 to (2^numBits - 1). Unfortunately 35 is not a number which can be received by 2^numBits - 1.

So we have two options: Either go with 2^5-1=31 or 2^6-1=63. If we would choose 2^6 we would get a lot of "unnecessary" / "longer" numbers. Therefore 2^5 is the better option, even if we lose four characters (w-z). To now generate a string of a certain length, we can simply use a 2^(length*numBits)-1 number. The last problem, if we want a string with a certain length, random could generate a small number, so the length is not met, so we have to pad the string to its required length prepending zeros.

1
  • could you explain better the 5? Mar 9, 2016 at 16:56
9

I found this solution that generates a random hex encoded string. The provided unit test seems to hold up to my primary use case. Although, it is slightly more complex than some of the other answers provided.

/**
 * Generate a random hex encoded string token of the specified length
 *  
 * @param length
 * @return random hex string
 */
public static synchronized String generateUniqueToken(Integer length){ 
    byte random[] = new byte[length];
    Random randomGenerator = new Random();
    StringBuffer buffer = new StringBuffer();

    randomGenerator.nextBytes(random);

    for (int j = 0; j < random.length; j++) {
        byte b1 = (byte) ((random[j] & 0xf0) >> 4);
        byte b2 = (byte) (random[j] & 0x0f);
        if (b1 < 10)
            buffer.append((char) ('0' + b1));
        else
            buffer.append((char) ('A' + (b1 - 10)));
        if (b2 < 10)
            buffer.append((char) ('0' + b2));
        else
            buffer.append((char) ('A' + (b2 - 10)));
    }
    return (buffer.toString());
}

@Test
public void testGenerateUniqueToken(){
    Set set = new HashSet();
    String token = null;
    int size = 16;

    /* Seems like we should be able to generate 500K tokens 
     * without a duplicate 
     */
    for (int i=0; i<500000; i++){
        token = Utility.generateUniqueToken(size);

        if (token.length() != size * 2){
            fail("Incorrect length");
        } else if (set.contains(token)) {
            fail("Duplicate token generated");
        } else{
            set.add(token);
        }
    }
}
1
  • I don't think it is fair to fail for duplicate tokens which is purely based on probability. Jun 2, 2012 at 15:22
8
  1. Change String characters as per as your requirements.

  2. String is immutable. Here StringBuilder.append is more efficient than string concatenation.


public static String getRandomString(int length) {
    final String characters = "abcdefghijklmnopqrstuvwxyzABCDEFGHIJLMNOPQRSTUVWXYZ1234567890!@#$%^&*()_+";
    StringBuilder result = new StringBuilder();

    while(length > 0) {
        Random rand = new Random();
        result.append(characters.charAt(rand.nextInt(characters.length())));
        length--;
    }
    return result.toString();
}
1
  • 3
    This adds nothing the dozens of answers given previously didn't cover. And creating a new Random instance in each iteration of the loop is inefficient.
    – erickson
    Feb 10, 2014 at 5:17
7
import java.util.Date;
import java.util.Random;

public class RandomGenerator {

  private static Random random = new Random((new Date()).getTime());

    public static String generateRandomString(int length) {
      char[] values = {'a','b','c','d','e','f','g','h','i','j',
               'k','l','m','n','o','p','q','r','s','t',
               'u','v','w','x','y','z','0','1','2','3',
               '4','5','6','7','8','9'};

      String out = "";

      for (int i=0;i<length;i++) {
          int idx=random.nextInt(values.length);
          out += values[idx];
      }
      return out;
    }
}
7

I don't really like any of these answers regarding a "simple" solution :S

I would go for a simple ;), pure Java, one liner (entropy is based on random string length and the given character set):

public String randomString(int length, String characterSet) {
    return IntStream.range(0, length).map(i -> new SecureRandom().nextInt(characterSet.length())).mapToObj(randomInt -> characterSet.substring(randomInt, randomInt + 1)).collect(Collectors.joining());
}

@Test
public void buildFiveRandomStrings() {
    for (int q = 0; q < 5; q++) {
        System.out.println(randomString(10, "ABCDEFGHIJKLMNOPQRSTUVWXYZ0123456789")); // The character set can basically be anything
    }
}

Or (a bit more readable old way)

public String randomString(int length, String characterSet) {
    StringBuilder sb = new StringBuilder(); // Consider using StringBuffer if needed
    for (int i = 0; i < length; i++) {
        int randomInt = new SecureRandom().nextInt(characterSet.length());
        sb.append(characterSet.substring(randomInt, randomInt + 1));
    }
    return sb.toString();
}

@Test
public void buildFiveRandomStrings() {
    for (int q = 0; q < 5; q++) {
        System.out.println(randomString(10, "ABCDEFGHIJKLMNOPQRSTUVWXYZ0123456789")); // The character set can basically be anything
    }
}

But on the other hand you could also go with UUID which has a pretty good entropy:

UUID.randomUUID().toString().replace("-", "")
7

I'm using a library from Apache Commons to generate an alphanumeric string:

import org.apache.commons.lang3.RandomStringUtils;

String keyLength = 20;
RandomStringUtils.randomAlphanumeric(keylength);

It's fast and simple!

1
  • Works great! and it has random case as well, which I needed. May 13, 2020 at 2:32
6

You mention "simple", but just in case anyone else is looking for something that meets more stringent security requirements, you might want to take a look at jpwgen. jpwgen is modeled after pwgen in Unix, and is very configurable.

1
  • Thanks, fixed it. So it least there is source and the link is valid. On the downside, it doesn't look like it has been updated in a while, though I see pwgen has been updated fairly recently.
    – michaelok
    Jun 26, 2017 at 22:50
6
import java.util.*;
import javax.swing.*;

public class alphanumeric {
    public static void main(String args[]) {
        String nval, lenval;
        int n, len;

        nval = JOptionPane.showInputDialog("Enter number of codes you require: ");
        n = Integer.parseInt(nval);

        lenval = JOptionPane.showInputDialog("Enter code length you require: ");
        len = Integer.parseInt(lenval);

        find(n, len);
    }

    public static void find(int n, int length) {
        String str1 = "0123456789ABCDEFGHIJKLMNOPQRSTUVWXYZ";
        StringBuilder sb = new StringBuilder(length);
        Random r = new Random();

        System.out.println("\n\t Unique codes are \n\n");
        for(int i=0; i<n; i++) {
            for(int j=0; j<length; j++) {
                sb.append(str1.charAt(r.nextInt(str1.length())));
            }
            System.out.println("  " + sb.toString());
            sb.delete(0, length);
        }
    }
}
5

Here is the one-liner by abacus-common:

String.valueOf(CharStream.random('0', 'z').filter(c -> N.isLetterOrDigit(c)).limit(12).toArray())

Random doesn't mean it must be unique. To get unique strings, use:

N.uuid() // E.g.: "e812e749-cf4c-4959-8ee1-57829a69a80f". length is 36.
N.guid() // E.g.: "0678ce04e18945559ba82ddeccaabfcd". length is 32 without '-'
0
4

You can use the following code, if your password mandatory contains numbers and alphabetic special characters:

private static final String NUMBERS = "0123456789";
private static final String UPPER_ALPHABETS = "ABCDEFGHIJKLMNOPQRSTUVWXYZ";
private static final String LOWER_ALPHABETS = "abcdefghijklmnopqrstuvwxyz";
private static final String SPECIALCHARACTERS = "@#$%&*";
private static final int MINLENGTHOFPASSWORD = 8;

public static String getRandomPassword() {
    StringBuilder password = new StringBuilder();
    int j = 0;
    for (int i = 0; i < MINLENGTHOFPASSWORD; i++) {
        password.append(getRandomPasswordCharacters(j));
        j++;
        if (j == 3) {
            j = 0;
        }
    }
    return password.toString();
}

private static String getRandomPasswordCharacters(int pos) {
    Random randomNum = new Random();
    StringBuilder randomChar = new StringBuilder();
    switch (pos) {
        case 0:
            randomChar.append(NUMBERS.charAt(randomNum.nextInt(NUMBERS.length() - 1)));
            break;
        case 1:
            randomChar.append(UPPER_ALPHABETS.charAt(randomNum.nextInt(UPPER_ALPHABETS.length() - 1)));
            break;
        case 2:
            randomChar.append(SPECIALCHARACTERS.charAt(randomNum.nextInt(SPECIALCHARACTERS.length() - 1)));
            break;
        case 3:
            randomChar.append(LOWER_ALPHABETS.charAt(randomNum.nextInt(LOWER_ALPHABETS.length() - 1)));
            break;
    }
    return randomChar.toString();
}
4

You can use the UUID class with its getLeastSignificantBits() message to get 64 bit of random data, and then convert it to a radix 36 number (i.e. a string consisting of 0-9,A-Z):

Long.toString(Math.abs( UUID.randomUUID().getLeastSignificantBits(), 36));

This yields a string up to 13 characters long. We use Math.abs() to make sure there isn't a minus sign sneaking in.

1
  • 3
    Why in the world would you use UUID to get random bits? Why not just use random.nextLong()? Or even Double.doubleToLongBits(Math.random())?
    – erickson
    Oct 4, 2013 at 5:31
3

Here it is a Scala solution:

(for (i <- 0 until rnd.nextInt(64)) yield { 
  ('0' + rnd.nextInt(64)).asInstanceOf[Char] 
}) mkString("")
1
  • An explanation would be in order. Nov 12, 2020 at 15:47
3

Using an Apache Commons library, it can be done in one line:

import org.apache.commons.lang.RandomStringUtils;
RandomStringUtils.randomAlphanumeric(64);

Documentation

0
3
public static String randomSeriesForThreeCharacter() {
    Random r = new Random();
    String value = "";
    char random_Char ;
    for(int i=0; i<10; i++)
    {
        random_Char = (char) (48 + r.nextInt(74));
        value = value + random_char;
    }
    return value;
}
1
  • 2
    That string concatenation is unnecessarily inefficient. And the crazy indentation makes your code nearly unreadable. This is the same as Jamie's idea, but poorly executed.
    – erickson
    Oct 4, 2013 at 5:36
3

I think this is the smallest solution here, or nearly one of the smallest:

 public String generateRandomString(int length) {
    String randomString = "";

    final char[] chars = "ABCDEFGHIJKLMNOPQRSTUVWXYZabcdefghijklmnopqrstuvwxyz01234567890".toCharArray();
    final Random random = new Random();
    for (int i = 0; i < length; i++) {
        randomString = randomString + chars[random.nextInt(chars.length)];
    }

    return randomString;
}

The code works just fine. If you are using this method, I recommend you to use more than 10 characters. A collision happens at 5 characters / 30362 iterations. This took 9 seconds.

3
public class Utils {
    private final Random RANDOM = new SecureRandom();
    private final String ALPHABET = "0123456789QWERTYUIOPASDFGHJKLZXCVBNMqwertyuiopasdfghjklzxcvbnm";

    private String generateRandomString(int length) {
        StringBuffer buffer = new StringBuffer(length);
        for (int i = 0; i < length; i++) {
            buffer.append(ALPHABET.charAt(RANDOM.nextInt(ALPHABET.length())));
        }
        return new String(buffer);
    } 
}
3
  • 1
    Can you please add some explanations about the specificity of this snippet with respect to other answers?
    – Raphael D.
    Apr 9, 2021 at 14:36
  • this one is clean! like the usage of securerandom
    – jksevend
    Jun 16, 2021 at 16:25
  • 1
    I would replace StringBuffer with StringBuilder, just because the Builder, being not Thread-safe, is just faster. But thanks for the quick answer! :·) Nov 22, 2021 at 15:00

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