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Little confused with below constructor code

With 2048

 RSAKeyPairGenerator gen = new RSAKeyPairGenerator();
 gen.init(new RSAKeyGenerationParameters(BigInteger.valueOf(3),
                                new SecureRandom(), 2048, 80));

With 1024

 RSAKeyPairGenerator gen = new RSAKeyPairGenerator();
 gen.init(new RSAKeyGenerationParameters(BigInteger.valueOf(3),
                                new SecureRandom(), 1024, 80));

Here is the RSAKeyGenerationParameters, from BouncyCastle library to generate certificates.

My question how what is the effect on public and private key by passing 1024 and 2048

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2^1024 times as hard to break, which is a fairly large number. The CAs that I deal with won't accept 1024-bit keys any more. –  EJP Oct 10 '13 at 7:58
Yep, the documentation for the RSAKeyGenerationParameters class is a bit weak (pardon the pun), but the description of the constructor of the super, KeyGenerationParameters class sheds some light on it: initialise the generator with a source of randomness **and a strength (in bits)**. So in plain English: it specifies how long the keys will be. –  ppeterka Oct 10 '13 at 7:59
@ppeterka66 Thanks for looking in to this. Length of the both keys are same. But I can see the difference in the keys. –  sᴜʀᴇsʜ ᴀᴛᴛᴀ Oct 10 '13 at 8:03
@sᴜʀᴇsʜᴀᴛᴛᴀ EJP is right, the question today is 2048 or 4096... (even the wiki has a quote saying 1024 bit encryption is dead...) –  ppeterka Oct 10 '13 at 8:09
@EJP It's not 2^1024 times as hard to break. It's "only" a few billion times as hard. Unlike symmetric encryption, RSA's security doesn't scale like 2^n. –  CodesInChaos Oct 10 '13 at 8:30

2 Answers 2

The third parameter of RSAKeyGenerationParameters is

strength - the size, in bits, of the keys we want to produce.

2048-bit RSA encryption is theoretically harder to break than 1024. But the number of bits in the public/private pair is typically defined by the system you're interacting with.

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Unlike the difference between 128 and 256 bit AES, the difference between RSA-1024 and RSA-2048 is not merely theoretical. RSA-1024 is withing the range of computational power affordable to larger attackers (e.g. the NSA). –  CodesInChaos Oct 10 '13 at 8:33

Asymmetric keys are typically easier to crack than symmetric keys of the same length. The longer the asymmetric key, the more computational power is required to determine the private key from the public key. Therefore, the longer the keys, the stronger the encryption.

Also, note that with RSA encryption, the plain text message cannot be longer than the key. So, if you are using a 1024 bit key, you can only encrypt a message body of up to 128 bytes (minus a few for overhead), or 256 bytes for a 2048 bit key.

So, the longer the asymmetric key, the longer the symmetric key or hash value can be passed inside.

It also takes longer (more computational power required) to generate longer key pairs, but unless you're dynamically creating key pairs, this isn't often an issue.

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The size of the asymmetric key often does not matter for RSA encryption, as hybrid encryption is the norm. Same goes for the hash value really, even SHA-512 will easily fit into a signature generated by an RSA 1024 public key. So apart from the security, the size of the key should not matter too much. –  Maarten Bodewes Oct 12 '13 at 20:26
@owlstead, Of course a SHA-512 hash value, which is 512 bits, will fit into a RSA 1024 bit cipher, but people do all kinds of interesting things with their asymmetric keys besides signing, and this limitation doesn't seem to be well known. –  Marcus Adams Oct 13 '13 at 2:34

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