# How are hash functions like MD5 unique?

Im aware that MD5 has had some collisions but this is more of a high level question about hashing functions. If MD5 hashes any arbitrary string into a 32-digit hex value, then according to the Pigeonhole Principle surely this can not be unique as there are more unique arbitrary strings than there are unique 32-digit hex values

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You're correct that it cannot guarantee uniqueness, however there are approximately 3.402823669209387e+38 different values in a 32 digit hex value (16^32). That means that, assuming the math behind the algorithm gives a good distribution, your odds are phenomenally small that there will be a duplicate. You do have to keep in mind that it IS possible to duplicate when you're thinking about how it will be used. MD5 is generally used to determine if something has been changed (I.e. it's a checksum). It would be ridiculously unlikely that something could be modified and result in the same MD5 checksum.

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And the cleverness behind designing a hash function is that all of these outputs are equally likely. If you have two almost identical documents, that differ by only 1bit, they will produce totally different hashes. –  Martin Beckett Mar 15 '10 at 2:11
The other interesting property of cryptographic hashes is that they are designed to be difficult to "reverse" or "target". In other words, given a hash it should be difficult to come up with a message that would produce that hash. –  Michael Burr Apr 28 '11 at 5:20
Interesting. It would mean, there is a phenomenal chance that two different e-mails generate the same md5 hash and Gravatar delivers the wrong user pic. de.gravatar.com/site/implement/hash –  Christian Jun 10 '13 at 14:32

You are absolutely correct. But hashes are not about "unique", they are about "unique enough".

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As Mike (and basically every one else) said, its not perfect, but it does the job, and collision performance really depends on the algo (which is actually pretty good).

What is of real interest is automatic manipulation of files or data to keep the same hash with different data, see this Demo

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Cryptographic one-way hash functions are, by nature of definition, not Injective. In terms of hash functions, "unique" is pretty meaningless. These functions are measured by other attributes, which affects their strength by making it hard to create a pre-image of a given hash. For example, we may care about how many image bits are affected by changing a single bit in the pre-image. We may care about how hard it is to conduct a brute force attack (finding a prie-image for a given hash image). We may care about how hard it is to find a collision: finding two pre-images that have the same hash image, to be used in a birthday attack.

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As others have pointed out, the goal of a hash function like MD5 is to provide a way of easily checking whether two objects are equivalent, without knowing what they originally were (passwords) or comparing them in their entirety (big files).

Say you have an object `O` and its hash hO. You obtain another object `P` and wish to check whether it is equal to `O`. This could be a password, or a file you downloaded (in which case you won't have `O` but rather the hash of it hO that came with `P`, most likely). First, you hash `P` to get hP.

There are now 2 possibilities:

1. hO and hP are different. This must mean that `O` and `P` are different, because using the same hash on 2 values/objects must yield the same value. Hashes are deterministic. There are no false negatives.
2. hO and hP are equal. As you stated, because of the Pigeonhole Principle this could mean that different objects hashed to the same value, and further action may need to be taken.

a. Because the number of possibilities is so high, if you have faith in your hash function it may be enough to say "Well there was a 1 in 2128 chance of collision (ideal case), so we can assume `O` = `P`. This may work for passwords if you restrict the length and complexity of characters, for example. It is why you see hashes of passwords stored in databases rather than the passwords themselves. b. You may decide that just because the hash came out equal doesn't mean the objects are equal, and do a direct comparison of `O` and `P`. You may have a false positive.

So while you may have false positive matches, you won't have false negatives. Depending on your application, and whether you expect the objects to always be equal or always be different, hashing may be a superfluous step.

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(It seems to be Hash Function Sunday.)

Cryptographic hash functions are designed to have very, very, very, low duplication rates. For the obvious reason you state, the rate can never be zero.

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As others have answered, hash functions are by definition not guaranteed to return unique values, since there are a fixed number of hashes for an infinite number of inputs. Their key quality is that their collisions are unpredictable.

In other words, they're not easily reversible -- so while there may be many distinct inputs that will produce the same hash result (a "collision"), finding any two of them is computationally infeasible.

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