# Cipher Feedback Mode

I can't understand what CFB really is. It said in Wikipedia that CFB is same as CBC, but I find that CFB is more difficult than CBC.

Can someone explain to me how CFB works. Such as how Initialization Vector(IV) work inside the Encryption Algorithm process together with the Key, and also how does the ciphertext message working to the next block cipher encryption.

And also my other question, is it okay to to use CFB with AES? I am confused because the plaintext message should enter AES algorithm to encrypt the plaintext message, but here in CFB, only Initialization Vector and Secret key will permuted by the block cipher.

Here is my another issue with CFB:

"To use CFB to make a self-synchronizing stream cipher that will synchronize for any multiple of $x$ bits lost, start by initializing a shift register the size of the block size with the initialization vector. This is encrypted with the block cipher, and the highest $x$ bits of the result are XOR'ed with $x$ bits of the plaintext to produce $x$ bits of ciphertext. These $x$ bits of output are shifted into the shift register, and the process repeats with the next $x$ bits of plaintext. Decryption is similar, start with the initialization vector, encrypt, and XOR the high bits of the result with $x$ bits of the ciphertext to produce $x$ bits of plaintext. Then shift the $x$ bits of the ciphertext into the shift register. This way of proceeding is known as CFB-8 or CFB-1 (according to the size of the shifting).

In notation, where $S_i$ is the $i$-th state of the shift register, $a \ll x$ is $a$ shifted up $x$ bits, $\operatorname{head}(a, x)$ is the $x$ highest bits of $a$ and $n$ is number of bits of IV:

\begin{aligned} C_i &= \operatorname{head}(E_K (S_{i-1}), x) \oplus P_i \\ P_i &= \operatorname{head}(E_K (S_{i-1}), x) \oplus C_i \\ S_i &= ((S_{i-1} \ll x) + C_i) \bmod 2^n \\ S_{0} &= \operatorname{IV} \\ \end{aligned}

If $x$ bits are lost from the ciphertext, the cipher will output incorrect plaintext until the shift register once again equals a state it held while encrypting, at which point the cipher has resynchronized. This will result in at most one blocksize of output being garbled."

I can't understand the formula and also what is the use of shift register. Can someone help me?

-

Well, with CFB mode, the encryption process is "take the most recent ciphertext block, pass it through the block cipher, and then exclusive-or that with the plaintext block to generate the next ciphertext block". As for the IV, that's used as "the most recent ciphertext block" when encrypting the first plaintext block (where you don't have a most recent ciphertext block yet).

Now, the advantage that CFB brings to the table is error recovery, including errors that add or delete ciphertext blocks. That is, is a ciphertext block is garbled (or a block is inserted or removed), the corresponding decrypted plaintext block and the one after that is also garbled; however, after that, the decryption process resyncs, and then it decrypts the rest of the text correctly. Now, CBC also has this same property in regards to entire blocks; however, if you take the last 128 bits of ciphertext, encrypt that, and then use (say) only 8 bits of each AES block output, and exclusive-or that is 8 bits of plaintext to form the next 8 bits of ciphertext, well, now you have something that is resilient against changes that inserts or removes individual bytes from the ciphertext (at the cost of having to run the block cipher N times to encrypt N bytes). Nowadays, this is not considered relevent (we generally want to encrypt and MAC entire messages, and if anything was changed, we reject the entire message); historically, this was considered a nice feature if (say) you were encrypting data going over an RS-232 interface (which really could add/drop individual bytes).

The other advantage that CFB mode has (over, say, CBC) is that the decryption process also uses the block cipher in encryption mode; depending on how different the block cipher encryption and decryption is, this can be convienent.