# Map strings to numbers maintaining the lexicographic ordering

I'm looking for an algorithm or function that is able to map a string to a number in such way that the resulting values correspond the lexicographic ordering of strings. Example:

``````"book" -> 50000
"car"  -> 60000
"card" -> 65000
"a longer string" -> 15000
"another long string" -> 15500
"awesome" -> 16000
``````

As a function it should be something like: f(x) = y, so that for any x1 < x2 => f(x1) < f(x2), where x is an arbitrary string and y is a number.

If the input set of x is finite, then I could always do a sort and assign the proper values, but I'm looking for something generic for an unlimited input set for x.

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I don't understand this. There is an infinite number of possible strings between "a longer string" and "another long string", so how can you guarantee unique values? –  Skilldrick Dec 16 '09 at 14:32
Do you have a maximum string length? –  Skilldrick Dec 16 '09 at 14:33

If you require that `f` map to integers this is impossible.

Suppose that there is such a map `f`. Consider the strings `a`, `aa`, `aaa`, etc. Consider the values `f(a)`, `f(aa)`, `f(aaa)`, etc. As we require that `f(a) < f(aa) < f(aaa) < ... ` we see that `f(a_n)` tends to infinity as `n` tends to infinity; here I am using the obvious notation that `a_n` is the character `a` repeated `n` times. Now consider the string `b`. We require that `f(a_n) < f(b)` for all `n`. But `f(b)` is some finite integer and we just showed that `f(a_n)` goes to infinity. We have a contradiction. No such map is possible.

Maybe you could tell us what you need this for? This is fairly abstract and we might be able to suggest something more suitable. Further, don't necessarily worry about solving "it" generally. YAGNI and all that.

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with a maximum string length it may be possible however –  jk. Dec 16 '09 at 14:52
@jk: yes, but question explicitly states "I'm looking for something generic, for an unlimited input set for x." –  AakashM Dec 16 '09 at 14:56
I supposed this would be the answer, but just wanted to be sure ... :-) The background: Actually I get some input sets of lets say 10000 strings each of maximum length 50, that is always different for each query. (That's why the unlimited input set.) Out of these strings I'd like to identify/group the similar ones and need a numeric value which matches the sort order for each separate input set. Solved the problem meanwhile, so thanks for your answer. –  MicSim Dec 16 '09 at 15:16
if you have a maximum length then the input set is limited (assuming a fixed alphabet) although probably very large. still it sounds like there is a better solution to the underlying problem anyway –  jk. Dec 16 '09 at 15:21
@Jason: I like your answer, as it clearly shows: Proving an approach wrong or impossible lets you safely discard it and frees your mind for other solutions. –  MicSim Dec 16 '09 at 16:53

what you are asking for is a a temporary suspension of the pigeon hole principle (http://en.wikipedia.org/wiki/Pigeonhole%5Fprinciple).

The strings are the pigeons, the numbers are the holes. There are more pigeons than holes, so you can't put each pigeon in its own hole.

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As a corollary to Jason's answer, if you can map your strings to rational numbers, such a mapping is very straightforward. If `code(c)` is the ASCII code of the character `c` and `s[i]` is the`i`th character in the string `s`, just sum like follows:

``````result <- 0
scale  <- 1
for i from 1 to length(s)
scale <- scale / 26
index <- (1 + code(s[i]) - code('a'))
result <- result + index / scale
end for
return result
``````

This maps the empty string to 0, and every other string to a rational number between 0 and 1, maintaining lexicographical order. If you have arbitrary-precision decimal floating-point numbers, you can replace the division by powers of 26 with powers of 100 and still have exactly representable numbers; with arbitrary precision binary floating-point numbers, you can divide by powers of 32.

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Yes, and as you mention, the key here is that you absolutely have to have arbitrary-precision. Similar reasoning as in my answer shows why this must be the case. We have that `f(a_n) < f(b)` for all `n`. If there is a number `e > 0` such that `f(a_(n+1)) - f(a_n) > e` for all `n` then choose `N` so large that `N * e + f(a_1) > f(b)`. Then `f(a_N) = f(a_N) - f(a_(N-1) + f(a_(N-1)) - f(a_(N-2)) + f(a_(N-2)) - ... + f(a_1) > N * e + f(a_1) > f(b)`. So, there is no such `e` and we conclude that the `f(a_n)` must get arbitrarily close to each other and thus we require arbitrary-precision. –  Jason Dec 16 '09 at 15:26