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Hi i'm looking for a an algorithm to convert any finitely large set of finitely long set of string to a specific real number between -1 and 1, in which every string would have a unique real number representation. This question is programming language agnostic.

Where each string could contain numerous words and end lines, and real number by mathematical definition. I could also use arbitrary precision libraries.

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A string can already be considered a real number, represented in base-256 (assuming 8-bit characters). So there's nothing that needs doing. – Oliver Charlesworth Jan 2 '13 at 0:37
@OliCharlesworth If you conveniently assume that the string stops just before the first '\0', which is not very language-agnostic. – Pascal Cuoq Jan 2 '13 at 0:40
@PascalCuoq: Not sure I follow. – Oliver Charlesworth Jan 2 '13 at 0:41
I updated the question to clear my ambiguity – pyCthon Jan 2 '13 at 0:42
@PhilFrost yes, it may not have applicability for infinite length strings, but we couldn't store those anyway. It has definite uses for finitely long strings. For example, see the accessibility keyboard, Dasher, which would not be possible without it. – ceykooo Jan 2 '13 at 0:55
up vote 8 down vote accepted

Assuming you want each string to map to a unique real number, which can also be decoded back into the original string, I would use arithmetic coding.

Basically, what you want to do is divide the set of real numbers between -1 and 1 into a number of parts equal to the number of characters in your alphabet, n. To encode a single character string, just pick the start of one of these regions. To encode the second character of the string, first find the region where the first character lies, and then subdivide that region into n smaller regions, and pick the region where the second character falls. You can then recurse on this solution to to be able to convert arbitrary length strings into unique real numbers.

For example, lets say our alphabet is only the characters a and b and we want to encode the string aba. The first a gives us the region [-1,0), the second character then subdivides this region, and yields [-0.5,0). Repeat with the final a to yield the region [-0.5,-0.75). Any number in this region can only be decoded to the sequence aba (given that we know the length of the original string, or we can just recurse forever when decoding).

(See wikipedia for a more detailed explanation of the encoding and decoding process. Note that you are probably only interested in equal-size regions for this problem.)

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[Turning my comment into an answer.]

You don't need to do anything. A string can already be considered a real number. Each character is a digit after the radix point, in base-256 (for 8-bit chars).

As pointed out, this fails to distinguish strings that have multiple trailing \0 characters. If this is a concern, then you could instead consider this number base-257, and have no character map to a value of 0.

As there is no algorithm, there are no extra memory requirements; your input string is also your output! There are no issues with arbitrary-precision libraries, etc.

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Suppose a string is 20 ASCII bytes, or 160 bits. A double-precision real number has only 64 bits. So there cannot be a unique real number for each possible string.

On the other hand, if you are not limited to 64 bits, just put the decimal (binary) point after the first bit, take the first bit as sign, and take all the bits of the string as fraction.

In fact, if you limit your alphabet to digit characters 0-9, it already exists, in the form of decimal arithmetic, as supported in COBOL and prior languages and old IBM computers. Just put the decimal point in front, multiply by 2, and subtract 1.

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won't this only give me an integer greater than 1? and Yes there are plenty of arbitrary precision libraries out there for me to use , no restriction on that. – pyCthon Jan 2 '13 at 0:47
This assumes that "\0\0" and "\0" are not strings, or that it is not important to distinguish them. – Pascal Cuoq Jan 2 '13 at 0:47
@pyCthon: If the first string, in binary is 0.11111.... it is +1 minus epsilon. If it is 1.0000......1 it is -1 plus epsilon. – Mike Dunlavey Jan 2 '13 at 0:51
@PascalCuoq: You can map characters any way you like onto bits, and then assume any string consists of some number of non-zero bit codes, followed by an infinite string of zero-bits codes. – Mike Dunlavey Jan 2 '13 at 0:55
this is assuming a language with limited reals. There's quite a few with arbitrary precision – Keith Nicholas Jan 2 '13 at 1:07

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