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I need an algorithm that can do a one-to-one mapping (ie. no collision) of a 32-bit signed integer onto another 32-bit signed integer.

My real concern is enough entropy so that the output of the function appears to be random. Basically I am looking for a cipher similar to XOR Cipher but that can generate more arbitrary-looking outputs. Security is not my real concern, although obscurity is.

Edit for clarification purpose:

  1. The algorithm must be symetric, so that I can reverse the operation without a keypair.
  2. The algorithm must be bijective, every 32-bit input number must generate a 32-bit unique number.
  3. The output of the function must be obscure enough, adding only one to the input should result big effect on the output.

Example expected result:

F(100) = 98456
F(101) = -758
F(102) = 10875498
F(103) = 986541
F(104) = 945451245
F(105) = -488554

Just like MD5, changing one thing may change lots of things.

I am looking for a mathmetical function, so manually mapping integers is not a solution for me. For those who are asking, algorithm speed is not very important.

share|improve this question
How fast do you want your algorithm to run ? – Cyril Gandon Jul 1 '10 at 7:45
@Scorpi0 Encoding does not matter, decoding should be faster, generally a speed close to public key cryptography acceptable. – Emre Yazici Jul 1 '10 at 10:34
@eyazici: If the algorithm is symmetric, encoding and decoding are the same. Now you say decoding should be faster. Do you really need a symmetric algorithm? – nikie Jul 1 '10 at 10:50
@Scorpi0: Algorithm must be symetric so that I can reverse the process. I give PKI speed as a measure. – Emre Yazici Jul 1 '10 at 11:40
@eyaici: The process is reversible if the encoding function is bijective. But do the encoding and decoding function have to be the same function? That's how I would understand the term "symetric". If you mean something else by "symetric algorithm", please clarify. – nikie Jul 1 '10 at 13:48

11 Answers 11

up vote 28 down vote accepted

Use any 32-bit block cipher! By definition, a block cipher maps every possible input value in its range to a unique output value, in a reversible fashion, and by design, it's difficult to determine what any given value will map to without the key. Simply pick a key, keep it secret if security or obscurity is important, and use the cipher as your transformation.

For an extension of this idea to non-power-of-2 ranges, see my post on Secure Permutations with Block Ciphers.

Addressing your specific concerns:

  1. The algorithm is indeed symmetric. I'm not sure what you mean by "reverse the operation without a keypair". If you don't want to use a key, hardcode a randomly generated one and consider it part of the algorithm.
  2. Yup - by definition, a block cipher is bijective.
  3. Yup. It wouldn't be a good cipher if that were not the case.
share|improve this answer
Yes the algorithm is symetric, I mean I do not want a solution that uses asymetric (if any), asymetric ciphers use different keys for encoding and decoding that are together named "keypair". I found a 32-bit block cipher (perhaps the only one on the web) with the help of your suggestions and I am poritng it another language now, it seems good enough: – Emre Yazici Jul 1 '10 at 15:26
Ah, understood. As my post indicates, it's possible to shorten existing ciphers; TEA is amenable to being modified for a 32 bit blocklength. I wouldn't rely on such a modification for cryptographic security, but you don't appear to be concerned about that. :) – Nick Johnson Jul 1 '10 at 15:34
Of course, a rainbow table for a 32-bit key is only 16 GB in size and can be generated at first run, so this is probably not going to ever be cryptographically secure on modern hardware. – Jonathan Grynspan Feb 9 '13 at 15:35
Some possible ciphers for this in no particular order: Hasty Pudding cipher, GDES, Simon, Speck, RC5. There are probably many more. – Artjom B. Aug 19 '15 at 23:31

I will try to explain my solution to this on a much simpler example, which then can be easily extended for your large one.

Say i have a 4 bit number. There are 16 distinct values. Look at it as if it was a four dimensional cube: 4 dimensional cube.

Every vertex represents one of those numbers, every bit represents one dimension. So its basicaly XYZW, where each of the dimensions can have only values 0 or 1. Now imagine you use a different order of dimensions. For example XZYW. Each of the vertices now changed its number!

You can do this for any number of dimensions, just permute those dimensions. If security is not your concern this could be a nice fast solution for you. On the other hand, i dont know if the output will be "obscure" enough for your needs and certainly after a large amount of mapping done, the mapping can be reversed (which may be an advantage or disadvantage, depending on your needs.)

share|improve this answer
Is this not equivalent to simply switching around the individual bits of the number to a given pattern? Hypercube is cool, regardless. – Justin L. Jul 1 '10 at 8:12
Yes, it is. The hypercube example was added just for explanation since i thought it would be nice to actually understand what swapping bits "does" in multidimensional space. – PeterK Jul 1 '10 at 8:16
I see. I've never really seen multidimensional been used as an analogy for a 32 bit integer before, but it's interesting indeed. – Justin L. Jul 1 '10 at 18:45
Swapping bits around in an n-bit value only gives n! possibilitues. What you want is a real permutation, which gives (2^n)! possibilities. – Todd Lehman Sep 2 '15 at 6:42

The following paper gives you 4 or 5 mapping examples, giving you functions rather than building mapped sets:

share|improve this answer
+1 Very nice paper. – PeterK Jul 1 '10 at 8:27

Apart from generating random lookup-tables, you can use a combination of functions:

  • XOR
  • symmetric bit permutation (for example shift 16 bits, or flip 0-31 to 31-0, or flip 0-3 to 3-0, 4-7 to 7-4, ...)
  • more?
share|improve this answer
As I wrote in my question, I need arbitrary-looking outputs. I have already mentioned about XOR-way, haven't I? – Emre Yazici Jul 1 '10 at 12:04
Yes of course, but I think combining XOR with bit permutation would look relatively arbitrary. Whatever that means in your case. – Michel de Ruiter Jul 1 '10 at 12:10
Yes, trying bit permutations would solve my problem, but I am looking for a tried one that is proved instead of implenting it myself, that's why I am asking here. – Emre Yazici Jul 1 '10 at 12:32
Ah. In that case, I would look into block ciphers as mentioned by Nick Johnson. A bit harder to follow, but tried and true. – Michel de Ruiter Jul 2 '10 at 12:07

Can you use a random generated lookup-table? As long as the random numbers in the table are unique, you get a bijective mapping. It's not symmetric, though.

One 16 GB lookup-table for all 32 bit values is probably not practical, but you could use two separate 16-bit lookup tables for the high-word and the low word.

PS: I think you can generate a symmetric bijective lookup table, if that's important. The algorithm would start with an empty LUT:

+----+        +----+
|  1 |   ->   |    |
+----+        +----+
|  2 |   ->   |    |
+----+        +----+
|  3 |   ->   |    |
+----+        +----+
|  4 |   ->   |    |
+----+        +----+

Pick the first element, assign it a random mapping. To make the mapping symmetric, assign the inverse, too:

+----+        +----+
|  1 |   ->   |  3 |
+----+        +----+
|  2 |   ->   |    |
+----+        +----+
|  3 |   ->   |  1 |
+----+        +----+
|  4 |   ->   |    |
+----+        +----+

Pick the next number, again assign a random mapping, but pick a number that's not been assigned yet. (i.e. in this case, don't pick 1 or 3). Repeat until the LUT is complete. This should generate a random bijective symmetric mapping.

share|improve this answer
Using a lookup table is a certain solution, however I need a mathematical solution. – Emre Yazici Jul 1 '10 at 12:45
What do you mean by "mathematical solution"? Use a PRNG with a fixed seed (e.g. the key) and you have a mathematical solution. – nikie Jul 1 '10 at 13:50
I mean a more clever solution, mapping 2^32 integers is neither cost effective nor scaleable. Basically I was looking for a 32-bit block cipher (which is rare in case of 32-bit) and I have found it. – Emre Yazici Jul 1 '10 at 15:33
That's why I suggested mapping high-word and low-word separately... – nikie Jul 1 '10 at 18:21

Take a number, multiplies by 9, inverse digits, divide by 9.

123  <> 1107 <> 7011 <> 779
256  <> 2304 <> 4032 <> 448
1028 <> 9252 <> 2529 <> 281

Should be obscure enough !!

Edit : it is not a bijection for 0 ending integer

900 <> 8100 <> 18 <> 2
2   <> 18   <> 81 <> 9

You can always add a specific rule like : Take a number, divide by 10 x times, multiplies by 9, inverse digits, divide by 9, multiples by 10^x.

And so

900 <> 9 <> 81 <> 18 <> 2 <> 200
200 <> 2 <> 18 <> 81 <> 9 <> 900

W00t it works !

Edit 2 : For more obscurness, you can add an arbitrary number, and substract at the end.

900 < +256 > 1156 < *9 > 10404 < invert > 40401 < /9 > 4489 < -256 > 4233
123 < +256 > 379 < *9 > 3411 < invert > 1143 < /9 > 127 < -256 > -129
share|improve this answer
How do you deal with overflows? Multiplying a large 32bit number by 9 can result in a number > 2^32 – nikie Jul 1 '10 at 9:02
+1 for simplicity :) – Tomek Tarczynski Jul 1 '10 at 9:39
yes, little problem on the overflows, 2147483647 <> 3647263599. The algorithm guaranteed a bijection on the set 10^N, not 2^N, that is a tiny detail :p – Cyril Gandon Jul 1 '10 at 9:56
As I write above, I am looking for a cipher that can generate arbitrary-looking outputs, but your solution generates similar outputs for sequential numbers: 123=>779, 124=>679, 125=>579... Obscurity is a must for me, but is not the only concern. I do not use simple XOR cipher or any other symetric cipher for this reason, which can generate much better results (in terms of obscurity) – Emre Yazici Jul 1 '10 at 12:02
I'm thinking, maybe running this algorithm twice, or even more, 10 times, on the inverted number, and the results could be fun. I will try to code something ! – Cyril Gandon Jul 1 '10 at 12:14

Here is my simple idea: You can move around the bits of the number, as PeterK proposed, but you can have a different permutation of bits for each number, and still be able to decipher it.

The cipher goes like this: Treat the input number as an array of bits I[0..31], and the output as O[0..31]. Prepare an array K[0..63] of 64 randomly generated numbers. This will be your key. Take the bit of input number from position determined by the first random number (I[K[0] mod 32]) and place it at the beginning of your result (O[0]). Now to decide which bit to place at O[1], use the previously used bit. If it is 0, use K[1] to generate position in I from which to take, it it is 1, use K[2] (which simply means skip one random number).

Now this will not work well, as you may take the same bit twice. In order to avoid it, renumber the bits after each iteration, omitting the used bits. To generate the position from which to take O[1] use I[K[p] mod 31], where p is 1 or 2, depending on the bit O[0], as there are 31 bits left, numbered from 0 to 30.

To illustrate this, I'll give an example:

We have a 4-bit number, and 8 random numbers: 25, 5, 28, 19, 14, 20, 0, 18.

I: 0111    O: ____

25 mod 4 = 1, so we'll take bit whose position is 1 (counting from 0)

I: 0_11    O: 1___

We've just taken a bit of value 1, so we skip one random number and use 28. There are 3 bits left, so to count position we take 28 mod 3 = 1. We take the first (counting from 0) of the remaining bits:

I: 0__1    O: 11__

Again we skip one number, and take 14. 14 mod 2 = 0, so we take the 0th bit:

I: ___1    O: 110_

Now it doesn't matter, but the previous bit was 0, so we take 20. 20 mod 1 = 0:

I: ____    O: 1101

And this is it.

Deciphering such a number is easy, one just has to do the same things. The position at which to place the first bit of the code is known from the key, the next positions are determined by the previously inserted bits.

This obviously has all the disadvantages of anything which just moves the bits around (for example 0 becomes 0, and MAXINT becomes MAXINT), but is seems harder to find how someone has encrypted the number without knowing the key, which has to be secret.

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If you don't want to use proper cryptographic algorithms (perhaps for performance and complexity reasons) you can instead use a simpler cipher like the Vigenère cipher. This cipher was actually described as le chiffre indéchiffrable (French for 'the unbreakable cipher').

Here is a simple C# implementation that shifts values based on a corresponding key value:

void Main()
  var clearText = Enumerable.Range(0, 10);
  var key = new[] { 10, 20, Int32.MaxValue };
  var cipherText = Encode(clearText, key);
  var clearText2 = Decode(cipherText, key);

IEnumerable<Int32> Encode(IEnumerable<Int32> clearText, IList<Int32> key) {
  return clearText.Select((i, n) => unchecked(i + key[n%key.Count]));

IEnumerable<Int32> Decode(IEnumerable<Int32> cipherText, IList<Int32> key) {
  return cipherText.Select((i, n) => unchecked(i - key[n%key.Count]));

This algorithm does not create a big shift in the output when the input is changed slightly. However, you can use another bijective operation instead of addition to achieve that.

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If your goal is simply to get a seemingly random permutation of numbers of a roughly defined size, then there is another possible way: reduce the set of numbers to a prime number.

Then you can use a mapping of the form

f(i) = (i * a + b) % p

and if p is indeed a prime, this will be a bijection for all a != 0 and all b. It will look fairly random for larger a and b.

For example, in my case for which I stumbled on this question, I used 1073741789 as a prime for the range of numbers smaller than 1 << 30. That makes me lose only 35 numbers, which is fine in my case.

My encoding is then

((n + 173741789) * 507371178) % 1073741789

and the decoding is

(n * 233233408 + 1073741789 - 173741789) % 1073741789

Note that 507371178 * 233233408 % 1073741789 == 1, so those two numbers are inverse the field of numbers modulo 1073741789 (you can figure out inverse numbers in such fields with the extended euclidean algorithm).

I chose a and b fairly arbitrarily, I merely made sure they are roughly half the size of p.

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Draw a large circle on a large sheet of paper. Write all the integers from 0 to MAXINT clockwise from the top of the circle, equally spaced. Write all the integers from 0 to MININT anti-clockwise, equally spaced again. Observe that MININT is next to MAXINT at the bottom of the circle. Now make a duplicate of this figure on both sides of a piece of stiff card. Pin the stiff card to the circle through the centres of both. Pick an angle of rotation, any angle you like. Now you have a 1-1 mapping which meets some of your requirements, but is probably not obscure enough. Unpin the card, flip it around a diameter, any diameter. Repeat these steps (in any order) until you have a bijection you are happy with.

If you have been following closely it shouldn't be difficult to program this in your preferred language.

For Clarification following the comment: If you only rotate the card against the paper then the method is as simple as you complain. However, when you flip the card over the mapping is not equivalent to (x+m) mod MAXINT for any m. For example, if you leave the card unrotated and flip it around the diameter through 0 (which is at the top of the clock face) then 1 is mapped to -1, 2 to -2, and so forth. (x+m) mod MAXINT corresponds to rotations of the card only.

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As far as I understand you mention about a function which can be defined as f(x)=(x+m) mod MAXINT where 0<m<MAXINT . However it has a very simple logic and the outputs are easily predictable. As I mentioned in my question I do not use XOR cipher which can generate much better outputs with a specially selected key. – Emre Yazici Jun 28 '10 at 10:11

Split the number in two (16 most significant bits and 16 least significant bits) and consider the bits in the two 16-bit results as cards in two decks. Mix the decks forcing one into the other.

So if your initial number is b31,b30,...,b1,b0 you end up with b15,b31,b14,b30,...,b1,b17,b0,b16. It's fast and quick to implement, as is the inverse.

If you look at the decimal representation of the results, the series looks pretty obscure.

You can manually map 0 -> maxvalue and maxvalue -> 0 to avoid them mapping onto themselves.

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