Much of what I'm about to explain can be gleaned from @ircmaxwell's excellent slidedeck: Cryptography For The Average Developer which you should check out immediately. I'll reiterate one of his main points:
Avoid writing code that deals with encryption/decryption. Unless you understand all the factors you will probably flub it. While this answer can be considered correct it's not enough to depend on. Hire an expert if you want to build a secure system.
MCRYPT_RIJNDAEL_128 is AES-128
AES-128, 192, and 256 are the three variants of the Advanced Encryption Standard.
The National Institute of Standards and Technology created AES and chose the Rijandael cipher from a competitive pool submitted by cryptographic experts.
The numbers in AES and Mycrpt refer to different things
For AES-* the numbers refer to key size. Thus, AES-128 requires a 128 bit key.
For MCRYPT_RIJNDAEL_* the numbers refer to block size. Thus,
MCRYPT_RIJNDAEL_256 refers to a 256 bit cipher block.
This leads to an important distinction:
MCRYPT_RIJNDAEL_256 is not AES-128 or AES-256
AES-256 requires a 256 bit key. All of Mcrypt's Rijndael implementations use 128 bit.
MCRYPT_RIJNDAEL_256 uses a 256 bit blocks, which does not conform to AES's 128 bit blocks.
Key size and block size
Key Size refers to the maximum input length of the secret (created by you, the developer) for the purpose of encrypting/decrypting the plaintext.
If you use a key/secret longer than than 128 bits, it will simply be truncated. 128 bits is roughly 32 characters of
[a-zA-Z0-9] (obviously depends on the character encoding and value of a particular entity).
Block Size is a property of block ciphers (i.e. all AES candidates) which chunk out the data to a specific size during the cipher process.
Null padding problem with ECB and CBC modes: use CFB
Both ECB and CBC pad the end of your plaintext to fit into the block size. If you're encrypting 1 byte of data with a 128 bit block size you will get 15 null bytes. Padding opens up the possibility for a padding oracle attack.
Beyond padding ECB does not make use of an Initialization Vector (IV) which leaves you open to a potential vulnerability: prefer CBC or CFB mode.
You can avoid both problems by using CFB mode which does not need padding and therefore does not require post-decryption trimming.
Create an IV with MCRYPT_DEV_URANDOM
MCRYPT_RAND is not random enough for cryptographic applications.
MCRYPT_DEV_URANDOM is preferred.
$iv_size = mcrypt_get_iv_size(
$iv = mcrypt_create_iv(
Finally, for your friends
In order to decrypt your friend will need to know:
- the cipher —
- the block mode —
- the IV — each element you encrypt should get a unique IV, so you'll want to append the IV to the encrypted data
- the key — this is secret, and should stay the same for all encryptions; if your key gets compromised rotate it out
Only the key needs to stay secret, everything else can be discovered/disclosed and you should be secure from known attacks; keep in mind that your key needs sufficiently high entropy to be protected against brute forcing, dictionaries, etc. (make it long, make it unpredictable).
Depending on your needs you may also consider implementing a data integrity check to ensure the encrypted data wasn't tampered with. Again, see @ircmaxwell's excellent slidedeck: Cryptography For The Average Developer for an example of creating an HMAC fingerprint using
It should be obvious that the maintenance all of these moving parts is rife with complexity. Tread carefully.
Mycrpt gives you many cipher options. Some, like DES, are not recommended. Others were candidates for AES, like Blowfish, TwoFish, and Serpent. Rijandael is a vetted, proven cipher, and is recommended.
But, AES-256 for Mcrypt?
One of the non-Rijndael ciphers may already provide one, but from the perspective of securing your data using a key larger than 128 bits is probably the least of your worries.