# Guessing the hash function?

I'd like to know which algorithm is employed. I strongly assume it's something simple and hopefully common. There's no lag in generating the results, for instance.

Input: any string
Output: 5 hex characters (0-F)

I have access to as many keys and results as I wish, but I don't know how exactly I could harness this to attack the function. Is there any method? If I knew any functions that converted to 5-chars to start with then I might be able to brute force for a salt or something.

I know for example that:
a=06a07
b=bfbb5
c=63447
(in case you have something in mind)

In normal use it converts random 32-char strings into 5-char strings.

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Could you provide a larger number of input output pairs? A few millions? I would like to analyze the function just for fun. –  Daniel Brückner Jan 26 '10 at 15:53
If you have the executable, you'd have to reverse engineer. Otherwise, there is no way (in general) of determining the algorithm, if it is decent (for example, a good cryptographic hash of the text appended to a large salt, then truncated; there is no way for us to know the salt without brute-forcing). If it's on the web, perhaps you could give us the link? –  BlueRaja - Danny Pflughoeft Jan 26 '10 at 16:58
I don't really want to raise suspicions on the smaller website so I won't give the link sorry but thanks for your interest. –  graw Jan 26 '10 at 17:30

The only way to derive a hash function from data is through brute force, perhaps combined with some cleverness. There are an infinite number of hash functions, and the good ones perform what is essentially one-way encryption, so it's a question of trial and error.

It's practically irrelevant that your function converts 32-character strings into 5-character hashes; the output is probably truncated. For fun, here are some perfectly legitimate examples, the last 3 of which are cryptographically terrible:

• Use the MD5 hashing algorithm, which generates a 16-character hash, and use the 10th through the 14th characters.
• Use the SHA-1 algorithm and take the last 5 characters.
• If the input string is alphabetic, use the simple substitution `A=1`, `B=2`, `C=3`, ... and take the first 5 digits.
• Find each character on your keyboard, measure its distance from the left edge in millimeters, and use every other digit, in reverse order, starting with the last one.
• Create a stackoverflow user whose name is the 32-bit string, divide 113 by the corresponding user ID number, and take the first 5 digits after the decimal. (But don't tell 'em I told you to do it!)
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Funny! OK I guess you are right. I already tried MD5, SHA-1, CRC32 and didn't see any relations. Out of curiosity do you know any public tools that calculate a whole bunch of different common hashes for something like this? –  graw Jan 26 '10 at 12:24
Sure: For starters you can look here: en.wikipedia.org/wiki/… but there's a good chance yours may be a home-grown algorithms, in which case it's probably a simple combination of XOR and scrambling bits. –  Adam Liss Jan 26 '10 at 12:49
Was looking for something more like this fileformat.info/tool/hash.htm?text=test :P –  graw Jan 26 '10 at 17:40
@graw: nice! Thanks for posting the link. –  Adam Liss Jan 27 '10 at 0:27

Depending on what you need this for, if you have access to as many keys and results as you wish, you might want to try a rainbow table approach. 5 hex chars is only 1mln combinations. You should be able to brute-force generate a map of strings that match all of the resulting hashes in no time. Then you don't need to know the original string, just an equivalent string that generates the same hash, or brute-force entry by iterating over the 1mln input strings.

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Interesting solution... yes it would be possible. Unfortunately since it's for a web app it wouldn't be practical in this case (I hoped to implement something in js :P). –  graw Jan 26 '10 at 12:34

Following on from a comment I just made to Pontus Gagge, suppose the hash algorithm is as follows:

• Append some long, constant string to the input
• Compute the SHA-256 hash of the result
• Output the last 5 chars of the hash.

Then I'm pretty sure there's no computationally feasible way from your chosen-plaintext attack to figure out what the hashing function is. To even prove that SHA-256 is in use (assuming it's a good hash function, which as far as we currently know it is), I think you'd need to know the long string, which is only stored inside the "black box".

That said, if I knew any published 20-bit hash functions, then I'd be checking those first. But I don't know any: all the usual non-crypto string hashing functions are 32 bit, because that's the expected size of an integer type. You should perhaps compare your results to those of CRC, PJW, and BUZ hash on the same strings, as well as some variants of DJB hash with different primes, and any string hash functions built in to well-known programming languages, like `java.lang.String.hashCode`. It could be that the 5 output chars are selected from the 8 hex chars generated by one of those.

Beyond that (and any other well-known string hashes you can find), I'm out of ideas. To cryptanalyse a black box hash, you start by looking for correlations between the bits of the input and the bits of the output. This gives you clues what functions might be involved in the hash. But that's a huge subject and not one I'm familiar with.

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This sounds mildly illicit.

Not to rain on your parade or anything, but if the implementors have done their work right, you wouldn't notice lags beyond a few tens of milliseconds on modern CPU's even with strong cryptographic hashes, and knowing the algorithm won't help you if they have used salt correctly. If you don't have access to the code or binaries, your only hope is a trivial mistake, whether caused by technical limitations or carelesseness.

There is an uncountable infinity of potential (hash) functions for any given set of inputs and outputs, and if you have no clue better than an upper bound on their computational complexity (from the lag you detect), you have a very long search ahead of you...

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I doubt that it is illicit - 20 bits is not a big enough output for this to be part of any sensible security system. –  Steve Jessop Jan 26 '10 at 12:14
Good point about an infinity of potential functions. The truth here is that I know the implementers didn't do it right anywhere else, so I don't think their hash function will be too complex or obscure. I already know there's no salt for instance. –  graw Jan 26 '10 at 12:18
"Sensible" and "security systems" has a nonempty but rather small intersection, I'm afraid! Especially homegrown. –  Pontus Gagge Jan 26 '10 at 12:26
Breaking non-sensible security systems isn't illicit either, it's "research" ;-). Thinking about it, there are uses for hash functions where it doesn't matter that collisions are easily generated, and so a small hash could be OK. Challenge-response protocols, for instance, where the "secret" is some value which is hashed together with the challenge to give the response. But in such systems, it doesn't matter if the hash algorithm itself is known, provided that the secret can't be deduced. –  Steve Jessop Jan 26 '10 at 12:58
Re 'research': Good luck with the DMCA if you're within US jurisdiction... Concur otherwise. –  Pontus Gagge Jan 26 '10 at 13:03