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The online documentation says

Hash[expr] 
  gives an integer hash code for the expression expr.
Hash[expr,"type"]
  gives an integer hash code of the specified type for expr.

It also gives "possible hash code types":

  • "Adler32" Adler 32-bit cyclic redundancy check
  • "CRC32" 32-bit cyclic redundancy check
  • "MD2" 128-bit MD2 code
  • "MD5" 128-bit MD5 code
  • "SHA" 160-bit SHA-1 code
  • "SHA256" 256-bit SHA code
  • "SHA384" 384-bit SHA code
  • "SHA512" 512-bit SHA code

Yet none of these correspond to the default returned by Hash[expr].

So my questions are:

  • What method does the default Hash use?
  • Are there any other hash codes built in?
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1 Answer 1

up vote 4 down vote accepted

The default hash algorithm is, more-or-less, a basic 32-bit hash function applied to the underlying expression representation, but the exact code is a proprietary component of the Mathematica kernel. It's subject to (and has) change between Mathematica versions, and lacks a number of desirable cryptographic properties, so I personally recommend you use MD5 or one of the SHA variants for any serious application where security matters. The built-in hash is intended for typical data structure use (e.g. in a hash table).

The named hash algorithms you list from the documentation are the only ones currently available. Are you looking for a different one in particular?

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@Michael Do you know if there a way to "introspect" Mathematica to get this kind of info? And also: Why isn't the "type" param of the Hash function implemented as an "option" (->) ? Mmmm may be I should post a question ... –  belisarius Oct 28 '10 at 22:04
    
@belisarius It is strange how Hash[] does not follow the option convention... –  Simon Oct 28 '10 at 23:10
    
@Michael I'm actually using it to speed up a calculation. I have some very long expressions built out of NonCommutativeMultiply that I need to Collect the coefficients and solve for linear dependence. Hashing the NonCommutativeMultiplys speeds things up by about a factor of 2. So all I need is the uniqueness of the hash. The question was asked only out of curiosity. –  Simon Oct 28 '10 at 23:14
1  
Also, @Simon, keep in mind most hash functions (including Hash[], MD5 and SHA) aren't "perfect" (i.e., injective), and unfortunately, especially not Hash. Evaluate and consider this: Length[DeleteDuplicates[Hash /@ Range[10^6]]] =) –  Michael Pilat Oct 29 '10 at 0:12
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@Simon So derive the algorithm by knowing that :D –  belisarius Oct 30 '10 at 0:33

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