The weak point of the XOR operation in cryptography is that `A XOR B XOR A = B`

. So when you know the part of the plaintext message `M`

for the corresponding encrypted message `C`

, you immediately obtain that part of the key as `K = M XOR C`

.

In particular:

```
>>> cypher = bytes.fromhex('0e0b213f26041e480b26217f27342e175d0e070a3c5b103e2526217f27342e175d0e077e263451150104')
>>> plaintext = b'crypto{1'
>>> key = ''.join(chr(c ^ m) for c, m in zip(cypher, plaintext))
>>> key
'myXORkey'
```

The chances are high that this is the entire key (it actually is, which is left as an exercise). This string will repeat as many times as needed to match the plain text length.

Suppose now, that this was not the entire key. We know, however, that the key repeats in a loop, so that part we alreaydy know, `myXORkey`

, will be reused somewhere later. We can start applying it to various places in the cypher and see when it starts making sense. That way we know the key length and parts of the messages. There are few ways from here, the most simple is, because we know some parts of the plaintext, we can find the missing part by sense and from there find the remaining part of the key.

The following properties may help:

- the key is sufficiently short
- the key makes some sense
- you know the language the plain text is written in

If the key is as long as the message, is truly random, and used only once, the cypher cannot be broken (See One-time pad).

In a generic case when the plaintext or/and the key length is unknown, there is more sophisticated method based on the Hamming distance and transposition (The method was first discovered in 19th century by Friedrich Kasiski to analyze the Vigenère cipher.

`"crypto{1}"`

I get a message with len=42, so half of the encrypt message.