# Is it possible to reverse engineer AES256?

Imagine I have this:

``````\$cdata = AES_256(\$data, \$pass);
``````

AES_256 implements the AES algorithm.

If I know the content of `\$cdata` and the content of `\$data` and also have the `AES_256()` code, can I reverse engineer and find `\$pass`?

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You're going to need alot of paper and pens –  Chad Grant May 1 '09 at 8:07
Just a matter of wording: Reverse engineering AES would give you the AES algorithm. You already know that algorithm. What you are asking is called "breaking AES". –  Magnus Hoff May 1 '09 at 9:23
Yes, of course, given sufficient time. :-) –  Nemo Jun 20 '11 at 4:00
I found a related answer on security.stackexchange.com regarding known-plaintext with AES which may be helpful. –  CLM Sep 4 '12 at 15:59

This has been tested, and mentioned in the Wiki link.

A related-key attack can break up to 9 rounds of 256-bit AES. A chosen-plaintext attack can break 8 rounds of 192- and 256-bit AES, and 7 rounds of 128-bit AES, although the workload is impractical at 2128 - 2119.

Or put it another way: you have a better chance of being struck by lighting... on the same day you win the Lottery, than breaking it!

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"break up to 9 rounds of 256-bit AES" What is a "round" in this definition? –  acemtp May 3 '09 at 17:32
Block ciphers scrambles the message repeatedly using the same algorithm. A single "pass" of scrambling is called a "round". How many rounds are needed create a secure algorithm depends on how much a single round scrambles the input. AES-256 uses 14 rounds. –  Nuoji Mar 9 '11 at 13:01
@Nuoji I get what a 'round' is for AES and in the context of an encryption algorithm but what does it mean when something says when "an attack can break up to x rounds..."? –  greatwolf Aug 5 '11 at 5:43
This means, if you only use x rounds of the algorithm, there is an attack less complex than brute force to retrieve the plaintext. –  Nuoji Jun 29 '12 at 14:00

This is called a known-plaintext attack. A good cipher like AES should be immune to it, as the others explained.

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If `\$pass` is actually a password and not a 256-bit key, you may be in luck.

While it is far from trivial to perform, a brute-force attack against a normal password is much faster than brute-forcing a 256-bit key.

So modify one of the many password-brute-forcing tools, and you have a attack that (depending on the strength of the password) might take weeks to several years - but that is fast compared to 3x10^51 years...

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You could brute force it, but it would take a long time. As in decades or even longer. That's the point of encryption algorithms like AES.

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The duration you are looking for is not "decades". It's more like "heat death of the universe". –  joeforker May 19 '09 at 18:20
@joeforker and in 20-30 years I'm sure we'll be laughing about how trivial it is to break AES 256 and current encryption uses megabyte keys to keep up with computers. –  Chris Marisic Nov 16 '09 at 19:05

Another quote, from Wikipedia:

AES permits the use of 256-bit keys. Breaking a symmetric 256-bit key by brute force requires 2^128 times more computational power than a 128-bit key. A device that could check a billion billion (10^18) AES keys per second would require about 3 x 10^51 years to exhaust the 256-bit key space.

Brute forcing when you know the original text might be faster but still, 3 x 10^51 years is a long time. Plus there's the problem of probably not having a device that can check a billion billion (10^18) keys/second.

In short: everything is possible, but this is not feasible in the world we are now living in.

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AES, like all good crypto algorithms, doesn't rely on security through obscurity.

In other words, there are no "secrets" in the code, so you having the code won't help you particularly.

Known plaintext is a separate issue, which I don't know much about so I'll leave that up to the other answerers.

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2x2^256 possible combinations is a lot to bruteforce. But bruteforcing is the only way. It would actually take about 3 decades. AES is the best Encryption possible right now I'd say. But that would only take that much time using a CPU. Because GPU's (Graphic Processing Units) are strictly math based, people have been making programs that only use the GPU to crack math based algorithms much more quickly than a CPU could. In other words AES might not last 3 decades. If only eternity codes were possible. Well looks like dynamic encryption may be the only way people can really hide their information in the near future.

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