I would like to create a function that takes a string and returns a number between 0 and 1. The function should consistently return the same number when given the same string, but other than that the results should have no discernible pattern. The output numbers for any large set of input strings should follow a uniform distribution.
Moreover, I need to generate more than one such function, i.e. when given the string "abc", function A might consistently return 0.593927 while function B consistently returns 0.0162524. I need it to be fast (it's for a numerical simulation), and have reasonably good statistics.
I'm using Python and will settle for answers of the form "here is an easy way to do it using a Python library" or "here is an algorithm that you can implement." If there's no fast way to do it in Python I'll just switch to C instead.
I realise that either of the following two methods will work, but each of them have drawbacks that make me want to look for a more elegant solution.
Store a dictionary
I could just calculate a new random number every time I'm given a new string, and store it in a dictionary to be retrieved if I receive the same string again. However, my application is likely to generate a lot of strings that only appear once, This will eventually result in having to store a very large dictionary in memory. It also makes repeatability more difficult, since even if I use the same seed, I'll generate a different function if I receive the same strings in a different order. For these reasons, it would be much better to consistently compute the random numbers "on the fly".
Use a hash function
I could just call a hash function on the string and then convert the result to a number. The issue of generating multiple functions could be solved by, for example, appending a "seed" string to every input string. However, then I'm stuck with trying to find a hash function with the appropriate speed and statistics. Python's built-in hash is fast but implementation-dependent, and I don't know how good the statistics will be since it's not designed for this type of purpose. On the other hand I could use a secure hash algorithm such as md5, which will have good statistics, but this would be too slow for my application. Hash functions aimed at data storage applications are typically much faster than cryptographically secure ones like md5, but they're designed with the aim of avoiding collisions, rather than producing uniformly distributed output, and these aren't necessarily the same in all cases.
A further note about hash functions
To illustrate the point that avoiding collisions and producing uniform results are different things, consider the following example using Python's built-in hash function:
>>> hash("aaa") % 1000 340 >>> hash("aab") % 1000 343 >>> hash("aac") % 1000 342 >>> hash("aad") % 1000 337 >>> hash("aae") % 1000 336 >>> hash("aaf") % 1000 339 >>> hash("aag") % 1000 338 >>> hash("aah") % 1000 349 >>> hash("aai") % 1000 348 >>> hash("aaj") % 1000 351 >>> hash("aak") % 1000 350
There are no collisions in the above output, but they are also clearly not uniformly distributed, since they are all between 336 and 351, and there is also a definite pattern in the third digit. I realise I could probably get better statistics by doing
(hash("aaa")/HASH_MAX)*1000 (assuming I can work out what
HASH_MAX should be), but this should help to illustrate that the requirements for a good hash function are not the same as the requirements for the function I'm looking for.
Some relevant information about the problem
I don't know exactly what the strings are that this algorithm will need to work on, because the strings will be generated by the simulation, but the following are likely to be the case:
They will have a very restricted character set (perhaps just 4 or 5 different symbols).
There will be a lot of unique or rare strings and a few very common ones, of varying length.
There is no upper bound on the lengths of the strings, but short ones are likely to be much more common than long ones. I wouldn't be surprised if I never see one longer than 100 characters, but I don't know for sure. Many of them will just have one to three characters, so it's important that the algorithm is fast for short strings. (But I guess I could use a lookup table for strings less than a certain length.)
Typically, the strings will have large substrings in common - often two strings will differ only by a single character appended to the beginning or end. It's important that the algorithm doesn't tend to give similar output values when the strings are similar.