This can be easily done by putting any block encryption algorithm into CTR mode. CTR mode with a single key looks like:

```
ciphertext = plaintext XOR cipher(key, counter)
```

Where counter is initialized to your IV and incremented for each block. Decryption is exactly the same operation. As such, if you CTR-encrypt twice with two keys, you get:

```
ciphertext = plaintext XOR cipher(key0, counter) XOR cipher(key1, counter)
```

And since XOR is commutative, you can reverse it in either order.

This has the nice property that you don't need to have all keys in the same location. Consider: Alice, Bob, and Charlie are participating in a protocol in which Charlie will double encrypt data for both Alice and Bob (this protocol will assume all point-to-point communication is secured through usual SSL-like channels):

- Alice and Bob perform an authenticated Diffie-Helmann exchange to produce the IV. This IV is then sent to Charlie.
- Alice computes digest(key0, IV + ctr) for ctr = 0...number-of-ciphertext-blocks, and sends the result KS_A to Charlie
- Bob computes digest(key1, IV + ctr) for ctr = 0...number-of-ciphertext-blocks, and sends the result KS_B to Charlie
- Charlie computes KS_A XOR KS_B XOR plaintext, and sends the resulting ciphertext to both Alice and Bob.
- Alice and Bob each sign a tuple (IV, hash(ciphertext), description-of-encrypted-data). This is attached to the ciphertext.

Later, to decrypt:

- Charlie (performing the decryption) sends the signed (IV, hash(ciphertext)) tuples to each of Alice and Bob, as well as the ciphertext.
- Alice verifies his signed tuple, computes KS_A, and sends ciphertext XOR KS_A = D_A to Charlie
- Bob verifies his signed tuple, computes KS_B, and sends ciphertext XOR KS_B = D_B to Charlie
- Charlie computes KS = D_A XOR D_B = KS_A XOR KS_B
- Charlie computes plaintext = ciphertext XOR KS

The purpose of the signed tuple here and DH exchange is to ensure Alice and Bob can't be tricked into decryption the wrong stream by sending them a different IV. This may not be relevant in your usage scenario. Also, the role of Charlie may be played by Alice or Bob in a real implementation.

If you're worried about the potential security risks of CTR mode, one other option would be to use CTR-mode encryption on a session key, which in turn is used to encrypt in a more normal mode, such as CBC. That is:

```
sessionkey = RANDOM
IV_0 = RANDOM
IV_1 = RANDOM
enc_sessionkey = sessionkey XOR cipher(key0, IV_0) XOR cipher(key1, IV_0)
ciphertext = enc_sessionkey + IV_0 + IV_1 + cipherCBC(IV_1, sessionkey, plaintext)
```

Although some other posters have commented on secret sharing, this is overkill if you don't need the property that only a subset of keys are needed for decryption - ie, with secret sharing you might encrypt with three keys, but require only any two to decrypt. If you want to require all keys, secret sharing schemes aren't really necessary.

`Key2(plaintext)`

and`Key1(plaintext)`

? – CodesInChaos Jun 17 '11 at 18:04