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I want to allow Alice to create a public/private key pair so that Bob can send her confidential messages. However, I want Alice to be able to check her messages from anywhere, and it would be a pain for her to have to carry around a memory stick containing her private key. Is there some way that Alice can create a public/private key pair based on a password which she remembers? In this way she could simply generate the private key (and public key) whenever she wanted to.

The short version of this question is: Where can I find the Java equivalent of cryptico.js.

Also, here's the same question on Stack Overflow, but for javascript.

Edit: Here's my first attempt at a solution:

    SecureRandom saltRand = new SecureRandom(new byte[] { 1, 2, 3, 4 });
    byte[] salt = new byte[16];

    int keyLength = 3248;
    SecretKeyFactory factory = SecretKeyFactory
    KeySpec spec = new PBEKeySpec(password.toCharArray(), salt, 8192, keyLength);
    SecretKey key = factory.generateSecret(spec);

    SecureRandom keyGenRand = SecureRandom.getInstance("SHA1PRNG");

    KeyPairGenerator gen = KeyPairGenerator.getInstance("RSA");
    gen.initialize(keyLength, keyGenRand);
    java.security.KeyPair p = gen.generateKeyPair();
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When talking RSA: You could use the result of PBKDF2 to seed a pseudo random number generator, which can in turn be used to generate a key pair. Note that using SecureRandom won't work as it will add the seed to the pool instead of full reinitializing the rng. RSA needs a PRNG to find a random prime.

You are better off if you can use Elliptic Curve Cryptography. You could choose a standard NIST or Brainpool curve over F(p). Then you could use 32 bytes output of the PBKDF2 as the private key and calculte the public key. ECC only requires a random private key and as the output of PBKDF2 should be indistinguishable from random, the output would be fine. Not only don't you need an additional PRNG, you are saving yourself the time to calculate an RSA key pair as well - and this can be substantial.

Note that nothing will prevent a brute force attack against something encrypted with said calculated key, so you should better ask for a passphrase of 16 characters or more, containing non-dictionary words, numbers and signs. Anything less will likely fail, especially if the users are unaware of possible attacks. Note that if you don't have storage, you cannot use a random salt. If you cannot have a random salt you cannot defend against rainbow tables (for your specific application, you can use a application specific salt of course). Furthermore, persons with the same passphrase will generate the same private key.

Of course the default way - for instance in PGP - is to store the private key encrypted using password based encryption. This however requires a storage. The advantage of that approach is that you can have a fully random key, which means that without access to the key storage, brute force attacks against cipher texts are impossible. It adds an important extra layer.

share|improve this answer
Very interesting, owlstead. Thanks - I'll check out Elliptic Curve Cryptography. But is a 32-byte private key large enough to resist a brute-force attack? – Mark Jul 22 '12 at 14:45
See keylength.com/en/3, that would be a 256 bit Elliptic Curve... The passphase itself definitely has less strength than that. – Maarten Bodewes Jul 22 '12 at 14:52
WARNING: Creating even the ECC scheme goes against that all important rule: don't try to implement a cryptographic algorithm or protocol yourself. You've been warned. End of standard disclaimer. – Maarten Bodewes Jul 22 '12 at 14:57
Yes I'd much prefer to use an off-the-shelf implementation (similar to cryptico.js) but there doesn't seem to be one around. To answer your earlier question; the salt would be stored with Alice's public key so she (and anyone else) would always have access to it. – Mark Jul 22 '12 at 15:32
Hmmm...maybe Alice should just encrypt her private key using a symmetric key based on her password, then publish the result alongside her public key? – Mark Jul 22 '12 at 15:46

You don't provide many details but if you want to generate your keypair using the java.security.KeyPairGenerator you will have to define your own class that extends SecureRandom, but uses only the supplied password as the entropy source.

You don't need to implement a SecureRandomSpi class, you can just call the protected constructor of the superclass with (null, null) arguments.

share|improve this answer
Interesting approach GregS, nicely extends my answer too (for RSA). Didn't know about the protected constructor - I'll certainly remember that one. – Maarten Bodewes Jul 22 '12 at 14:19

RSA key length is typically 1024 or 2048 bits. That makes 128 or 256 bytes.

Passwords are typically 8 bytes long (and use only a around 64 different bytes).

You would lose much of the strength of the algorithm if the RSA key was derived from the password. Attackers would only have to guess or brute-force an 8-bytes password rather than a 128 or 256-bytes long key.

share|improve this answer
That's true, but what if I used an intentionally slow algorithm like bcrypt or PBKDF2 to convert the 8 byte password into 256 bytes which are then used to initialize the key generation procedure. Wouldn't that thwart a brute-force attack on the password? – Mark Jul 22 '12 at 13:42
It would help for brute-force attacks, but not for social-engineering attacks and dictionary attacks. – JB Nizet Jul 22 '12 at 14:11
I've extended my answer to include a bit of discussion regarding these brute force attacks, which are certainly not completely twarted by using PBKDF2. Besides that, where would you store the salt required to make PBKDF2 resistant against rainbow tables? – Maarten Bodewes Jul 22 '12 at 14:22

Why don't you allow access to your web app via password (since that's effectively what you are doing) and just use https?

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How does that help Bob in sending an encryped message to Alice? He needs to get a public key from Alice, and Alice needs to be able to generate the key on demand from her passphrase (to avoid having to store the private key somewhere). – Thilo Dec 11 '15 at 7:51

use a shared key.

String encryptionKey = "53616d706c6550617373776f726453616d706c6550617373776f726453616d70"; // string to hex of "SamplePasswordSamplePasswordSamp"
String sampleText = "sampletext";
String encrypted = null;
String decrypted = null;

To encrypt use:

Cipher cipher = Cipher.getInstance("AES");
cipher.init(Cipher.ENCRYPT_MODE, new SecretKeySpec(Hex.decodeHex(encryptionKey.toCharArray()), "AES"));
encrypted = Hex.encodeHexString(cipher.doFinal((sampleText.toString()).getBytes()));

To decrypt use:

   Cipher cipher = Cipher.getInstance("AES");
    cipher.init(Cipher.DECRYPT_MODE, new SecretKeySpec(Hex.decodeHex(encryptionKey.toCharArray()), "AES"));
    decrypted = new String(cipher.doFinal(Hex.decodeHex(enc.toCharArray())));

note Hex is: import org.apache.commons.codec.binary.Hex; in maven:

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