As suggested by your question in comments. Here is a pattern slightly different than the one you are currently building.
First of all, if you cipher something, do it using well recognized and publicly known tools. The nowadays classic is AES. This is the raw cipher and performs encryption on 16-bytes blocks. All it needs is a secret key which can be of 128, 192 or 256 bit lengths.
Actually, the underlying cipher supports more lengths than that but the algorithm has been heavily tested on these 3 lengths so you might stick with them.
Now, you have to determine how you can use the cipher in your particular case. The choice of the encryption mode is very important. An encryption mode is a particular way to use a given cipher. The most basic is ECB (electronic code book). It simply consists of applying the cipher block after block with a given key. You should avoid it like the plague !
When you have the encryption mode, you are still not done. You must then find what we can call the key schedule. That is to say given a unique key such as a password or passphrase, you must derive the required cryptographic keys to supply to the underlying cryptosystem (the block cipher + the encryption mode).
I will begin with a simple pattern that is based on AES-128 (AES used with 128 bits key).
The key schedule
A good way to derive keys from a passphrase is to use hash functions. You only have to hash the passphrase and (optional) additional data to get a practical key. Here is what I suggest, based on HMAC construction :
Input : A password K of 7 to 80 characters, a string s that specifies the targeted user (like a pseudo) and hash function H.
Output : A cryptographic key Ks
You derive Ks using the following process
Ks = HMAC-H( s, K )
Depending on the digest length of H, you might have to truncate it to get only 128 bits. (Well known hash functions usually have an output with more than 128 bits). You can use H = SHA-1 or H = MD5 for example.
I don't know how long can be the data you store but I assume it is not too large. I suggest CBC (Cipher Block Chaining) mode. This mode requires the famous 128 bit key and an extra 128 bit vector called the Initialization Vector (IV in short). You must NEVER use the same (key, IV) pair twice ! (rule )
Now, here is what you could do, assuming :
- You have one file of data per user
- You accept a little overhead on your IO operations
You will cipher the data on a 512 bytes basis (that is 32 blocks of 16 bytes). The IV pattern will be simple : you start by encoding 0 on 16 bytes and you increment it each time a new 512 bytes block is appended.
A quick example :
User Cthulhu wants to stay in touch with his friends to share his evil plots. His passphrase is doom.
- His data file will be ciphered using KCthulhu, with K = doom, thus KCthulhu = HMAC-H(Cthulhu, doom)
- The file is divided into chunks of 512 bytes. The IV for data chunk number i is the common integer binary representation of i on 16 bytes.
I know that Cthulhu can have many many evil friends, but I can reasonably assume that the 16 bytes integer won't overflow, therefore rule  is enforced.
Here, you should have a basic cryptosystem which is not so bad but still can be improved :
- Using authenticated encryption with a MAC (message authentication code) scheme. Note that some execution modes include this, such as CCM
- Strengthening the key schedule : there might be rainbow tables attacks for the hash function you chose. To make things complicated for an attacker, introduce a random salt in the process.
- Changing the pattern "a file per user" since it still leaks some information such as "hey, what you will find here is related to the same user".
The first is quite easily introduced (juste use CCM instead of CBC and you're almost done). However, the last point is much more difficult to solve. The things you would have to do can be similar to the things made in a filesystem.